• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A sleeve for covering a roll (7) for transporting glass panels in a heating system. The sleeve is a textile fabric comprising yarns, the yarns comprising both glass fibers (16, 17) or ceramic fibers as well as metal fibers (15). The sleeve has an improved lifespan.
    公开号:BE1021069B1
    申请号:E2011/0179
    申请日:2011-03-23
    公开日:2015-04-21
    发明作者:Tom Verhaeghe;Raf Claes;Ridder Frank De
    申请人:Nv Bekaert Sa;
    IPC主号:
    专利说明:

    Title: Hybrid sleeve with glass fibers or ceramic fibers and metal fibers
    Description
    Technical Field The invention relates to a sleeve for covering a roll for transporting glass panels in a heating system.
    The invention further relates to the use of a sleeve as a cover on one or more rolls of a roller conveyor in a glass furnace heating oven.
    Background Art Heating systems for glass panels are known. They are used to heat glass panels to a sufficient temperature, generally to or above the softening temperature, in order to subject the panel to a shaping operation where an initially flat glass panel is curved, to a tempering operation or to a coating operation. Such heating systems include an oven in which a heating zone is defined, and a heating device for heating the heating zone. The glass panels to be heated are supplied through a supply opening in the oven. The glass panels are heated to the desired temperature in the oven. Meanwhile, a roller conveyor provided in the oven and extending through the heating zone conveys the glass panel to the discharge opening of the oven. In the case of forming the flat glass panel into a curved panel, this molding can take place - according to prior art and according to the invention - in the oven before the discharge opening (called bending in the oven) or outside the oven after the discharge opening (bending called outside the oven).
    "Bending in the oven" generally uses a mold with the desired curvature, with vacuum sucking the glass panel into the mold. The mold is placed above the glass. The mold generally has a series of suction holes and the glass is drawn onto the mold by means of a vacuum applied to the rear of the mold. Depending on the oven technology, suction can be supported by lift jets under the glass and the glass can be pressed against the mold by a pressure ring.
    "Bending outside the oven" generally uses a mold, rollers, a pressure ring, a quench ring, and roll pairs placed at ambient temperature. Depending on the complexity of the glass, one or more of the above items may or may not be present in the outside oven technology.
    It is a known problem that heated glass panels are susceptible to damage such as marking and printing. It is therefore important that the rollers of the roller conveyor have a smooth surface to prevent such damage. An additional problem is that, especially in the initial part of heating, heating often takes place unevenly, resulting in undesired bending. This bending can result in line marks.
    According to US 5565013, the rollers of the roller conveyor are provided with a knitted covering sleeve made of 100% metal wires. The coefficient of friction between the glass and the metal is low, which can be favorable for changing the position of the glass in the oven. The knitted structure is flexible and provides a certain softness, favoring a soft contact between the rollers and the glass, which helps to reduce marks. Although the temperature in the heating zone is very high, the glass panel that is still being heated is, however, still relatively cold. This causes an immediate cooling down every time the roller cover comes into contact with the glass panel. The glass is therefore often unevenly heated, which results in bending of the glass panel and which can cause markings on the glass as the glass passes through the oven. The roll itself remains hot and immediately heats the sleeve as the glass panel continues into the oven. This results in rapid temperature fluctuations of the sleeve, which in turn causes rapid oxidation of the sleeve and low lifetime of the sleeve. In addition, the metal sleeves lose their tension after a certain time, so that the sleeves are no longer tight around the rollers and so that they exhibit bending. This can cause torsion of the sleeve around the roll, which can result in corrugation of the sleeve.
    Other known coatings for conveyor belt rolls include silica or alumina fibers. Each of these products has its own disadvantages. Typically, in the first heating zones of an oven, temperatures are more elevated and can reach 710 ° C or more. Aromatic fibers are not resistant to these temperatures. Silicon dioxide fibers also quickly disintegrate at these temperatures. And fiberglass sleeves are difficult to assemble. Aluminum oxide fibers are very expensive.
    In addition, glass fibers and silica fibers have moderate mechanical strength, which often leads to local breaks of some yarns. These fractures start in isolated places, but run the risk of quickly reproducing throughout the sleeve, so that the glass panel ultimately rests on a bare roll.
    Disclosure of the Invention It is an object of the present invention to mitigate the disadvantages of the prior art. It is an additional object of the present invention to provide a conveyor belt roll cover that has an increased service life.
    According to a first aspect of the present invention, a sleeve for covering a roll for conveying glass panels is provided. The sleeve is a textile cloth, the textile cloth is made from yarns, the yarns comprising both glass fibers or ceramic fibers and metal fibers. The textile fabric preferably comprises between 10% by weight and 50% by weight of glass fibers or ceramic fibers, the remaining part being formed by metal fibers, such as steel fibers. Most preferably, the textile fabric comprises between 25 and 40% by weight of glass fibers and / or ceramic fibers, for example between 28% by weight and 36% by weight of glass fibers and / or ceramic fibers. Examples are 31-33% by weight of glass and 67-69% by weight of stainless steel.
    Textile cloths comprising both glass and metal fibers are known per se. Such a known textile cloth is used for bending the glass panel in the mold. Experience with these textile fabrics has shown that they have a shorter lifespan than a textile fabric comprising 100% metal fibers. This shorter service life is expected due to the lower impact resistance of glass fibers, in particular of the E-glass fibers.
    In contrast to this known experience, it has surprisingly been found that the service life of the textile cloth sleeve according to the invention is considerably longer than the service life of a conventional textile cloth cover of 100% metal fibers (stainless steel fibers). In fact, in a particular case, conventional coatings of 100% metal had a lifetime of only about 2/3 weeks, while the coating according to the invention had a lifetime of more than 2 months.
    The glass or ceramic material or a combination of both in the sleeve (textile cloth cover) dampens the cyclic temperature changes that the roll cover experiences with each passage of a glass panel. Considering that friction between metal and the glass panel is low, the metal provides low friction between the cover of the roller and the glass panel. Furthermore, the metal fibers provide strength to the cover and prevent cutting into the cover through the glass panel. The glass fibers do not come out of the cover. Furthermore, coverings of pure metal lose their tension over time, as a result of which the cover is no longer tight around the rollers, which causes bending, which in turn causes torsion of the cover around the roll. The resulting waves in the metal cover cause defects in the glass panel and that rolls must be replaced. In the sleeve cover according to the invention, the glass compensates for the resulting deflection of the cover and holds the cover tight around the roll.
    The sleeve of the present invention preferably has one or more yarns. Each yarn has one or more bundles, each of the one or more bundles includes both - glass fibers and / or ceramic fibers; and - metal or steel fibers.
    In a preferred embodiment of the invention, the sleeve has a textile fabric with one or more yarns. Each yarn has three bundles: one bundle comprises metal or steel fibers, the other two bundles comprising glass fibers and / or ceramic fibers. In this preferred embodiment, the two bundles may or may not be twisted with the glass fibers.
    The bundle with the metal and steel fibers may or may not be twisted with the bundles with the glass fibers.
    The textile cloth used for the sleeve according to the invention can be a non-woven fabric or mixtures of glass / ceramic fibers and metal fibers, a textile cloth obtained by netting of mixtures of glass / ceramic fibers and metal fibers, a woven textile cloth of yarn, a woven fabric of yarn, or preferably a knitted textile cloth of yarn. The textile fabric can be a tubular fabric fabric. It can be a circular textile cloth.
    A knitted structure with glass fibers provides softness, resulting in reduction of damage to the glass panel. According to additional implementations of this embodiment: the knitted structure is a weft-knitted structure; and / or • the knitted structure is a chain-knitted structure; and / or • the knitted structure is a circular knitted structure; and / or; • the knitted structure is a knitted single bed structure; and / or • the knitted structure is a weft-knitted double-bed structure and / or • the knitted structure is a 1/1 knitted structure (where 1/11 means right, 1 back).
    In another preferred embodiment of the invention, the sleeve is a knit (knitted textile fabric) comprising yarn, the yarn comprising at least three fiber bundles. The yarn comprises at least one fiber bundle comprising metal fibers. Each of the fiber bundles is defined by an equivalent bundle diameter. The equivalent bundle diameters of each of the fiber bundles in the yarns are equal to each other or differ by no more than 40%. The metal fiber bundles or single yarns are defined by an equivalent bundle diameter. The equivalent bundle diameter is to be understood as the diameter of an imaginary bundle with a circular radial cross-section, which cross-section has an area identical to the equivalent fiber diameter multiplied by the amount of fibers in the bundle or single yarn. The term "equivalent fiber diameter" of a particular fiber is to be understood as the diameter of an imaginary fiber with a circular radial cross-section, which cross-section has an area identical to the average of the cross-sectional areas of the particular fiber.
    In a preferred embodiment, the equivalent bundle diameter of the different bundles or single yarns in the yarn differs at most 30%, more preferably at most 20% and even more preferably at most 10%. The fiber bundles, of which at least one contains metal fibers, can be thoroughly mixed and twisted into a three or more twisted yarn or the yarn can be a three or more twisted yarn, some of the bundles or single yarns or all or some yarns of one type of fiber. By twisting yarns is meant that two or more bundles or yarns are given a torsion about the direction of the axes of the bundles or yarns, resulting in a twisted yarn. Alternatively, the yarn can be constructed prior to the knitting process by bundling at least 3 fiber bundles or single yarns, or the bundles or single yarns can be supplied separately during knitting to obtain a yarn with more than three yarn bundles. In another alternative embodiment, the yarn can be made by joining together the series of twisted yarns.
    In a more preferred embodiment, the yarn used in the knit is made up of 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 bundles or single yarns. Even more preferably, the yarn is made up of just 3.4, 5, 6 or 7 bundles or single yarns.
    In yet another embodiment, the yarn used in the knit is made up of 3 or 7 fiber bundles or single yarns. The use of 3 or 7 bundles or single yarns in a yarn provides a yarn that is more or less similar to a perfectly round circle, which surprisingly proved to provide better performing knitted textile fabrics, which, in use, reduce the marks on the curved glass surface.
    In yet another preferred embodiment, the yarn comprises three or more bundles or single yarns, wherein all fibers in a bundle or single yarn are made of one fiber type. Even more preferably, the yarn comprises at least one metal fiber bundle or single yarn and at least one glass fiber bundle or single yarn. The use of yarns in knits comprising at least one bundle of metal fibers and at least one bundle of glass fibers gives a better result in optical distortion than yarns made entirely from metal fiber bundles.
    In a preferred embodiment, the sleeve is a tubular textile fabric made on a weft knitting machine with a double flat bed. In another preferred embodiment, the tubular or circular textile fabric is made on a circular knitting machine.
    An advantage of a circular or tubular knitted structure is that it is a seamless sleeve that can be fitted around a roll simply by inserting the roll into the sleeve. The presence of a seam results in a reduction of the risk of the glass panel being damaged when it passes over the rollers.
    The metal is preferably a steel type and the steel type is preferably stainless steel as it has good coating properties used in glass furnaces. Experiments have proven that they give good results for the aforementioned ratios of fibers of stainless steel and glass fibers.
    The stainless steel is a stainless steel alloy, such as a 316 alloy, such as 316L, or 347 alloy, an Inconnel® or a Fecralloy®. An Inconnel® first a nickel-chromium-iron government. Fecralloy® is a stainless steel comprising iron, chromium, aluminum and yttrium.
    The glass is preferably an E-glass, but can also be an S-glass or quartz.
    The sleeve according to the invention can be used to cover the following: one or more rolls made of ceramic material; and / or • one or more rolls with a diameter of at least 4.5 cm, such as 4.5-7 centimeters; and / or • one or more rollers arranged at a regular distance of 7-15 cm, such as 9-11 cm; and / or • one or more rollers that are rigid and have a straight longitudinal axis; and / or • one or more rolls in a heating oven.
    In the art, non-straight rollers are sometimes used for the bending operation of the glass. The sleeve according to the invention is not adapted for the bending operation.
    The length of the oven can be more than 10 m, such as about 20 m; and whether the heating device can be adapted to heat the heating zone to a temperature of at least 500 ° C, such as 500-900 ° C, preferably to a temperature of 550-750 ° C.
    Brief description of the figures in the drawing The present invention will be further explained with reference to the drawing. In this drawing the following is shown: Figure 1 shows a schematic view of a system for treating glass panels, comprising a heating system; Figure 2 shows a schematic perspective view of a roll of the heating system of Figure 1; and Figure 3a, Figure 3b and Figure 3c all show a cross section of a yarn used in a sleeve according to the invention.
    Method of Carrying Out the Invention Figure 1 shows a system for treating glass panels. This system comprises a heating system 1 with on the left a supply station 20 for supplying glass panels 3a, which are to be heated by the heating system. On the right-hand side of the heating system 1, a treatment station 30 is provided for treating glass panels 3c coming from the heating device 1. The feeding station 20 comprises a roller conveyor with rollers 8 and the treatment station comprises a roller conveyor with rollers 9. The treatment in the treatment station could be any type of treatment, such as bending, tempering, coating, cooling, etc., which are usual for glass panels.
    The heating system 1 according to the invention basically comprises a furnace 2, which defines a heating zone 4 in said furnace; a heating device 5 for heating the heating zone in the oven 2; and a roller conveyor 6. The roller conveyor 6 comprises rollers 7 and extends through the heating zone 4. The oven 2 has a supply opening 10 for supplying glass panels 3a, which must be heated in the oven 2. The oven 2 further has a discharge opening 11 for discharging panels 3b, heated in the oven, from the oven to a next station, in this example a treatment station 30.
    The roller conveyor belt 6 extends between the supply opening 10 and the discharge opening 11. The roller conveyor 6 thus lies in the oven 2. As will be clear, the conveyor with rollers 8 from the supply station, the conveyor 6 from the heating system 1 and the conveyor with rollers 9 from the treatment station could be one conveyor assembly. The roller conveyor 6 is then the part of the conveyor belt assembly in the oven.
    As shown schematically in Figure 2, the rollers 7 of the roll conveyor 6 are provided with a textile cloth 14 that covers the roll body 12. The roller body 12 is supported on a shaft 13. The roller body 12 in this example is made of ceramic material because of its good properties for use in a glass panel oven.
    Figure 3a shows a cross-section of a first embodiment of a yarn 18, which is used in a sleeve according to the invention.
    The yarn 18 comprises two bundles 16 and 17 of glass fibers. The bundles 16 and 17 are rotated around each other. This twisted assembly 16, 17 is again rotated around a bundle 15 of stainless steel fibers.
    Figure 3b shows a cross-section of a second embodiment of a yarn 18, which is used in a sleeve according to the invention.
    The yarn 18 again comprises two bundles 16 and 17 of glass fibers. The bundles 16 and 17 are rotated around each other. This twisted assembly 16, 17 runs parallel to a bundle 15 of stainless steel fibers.
    Figure 3c shows a cross-section of a third embodiment of a yarn 18, which is used in a sleeve according to the invention.
    The yarn 18 again comprises two bundles 16 and 17 of glass fibers. The bundles 16 and 17 are not rotated around each other and run parallel to each other. This assembly 16, 17 then runs parallel to a bundle 15 of stainless steel fibers.
    Example As an example of a textile cloth for covering a roll of a roller conveyor in a glass panel heating device, the following characterization of the textile cloth can be given: • The textile cloth is a 1/1 single bed, circular knitted structure; • The yarn (s) used in the knitted textile cloth consists of a stainless steel filament and two glass filaments that are twisted together; Each yarn comprises approximately 32% by weight of glass and approximately 68% by weight of stainless steel; • The stainless steel is a 316 alloy; The diameter of the stainless steel filament is 12 µm; • the diameter of both glass filaments is 7 µm; • the glass filaments form an E-glass fiber; • the thickness of the sleeve is 0.93 mm; • the weight of the textile fabric is approximately 600 g / m2.
    List of reference numbers: 1 heating system 2 oven 3a glass panel 3b glass panel 3c glass panel 4 heating zone 5 heating zone 6 conveyor belt 7 roll 8 roll 10 supply opening 11 discharge opening 12 roll body 13 shaft 14 textile cloth 15 bundle of steel fibers 16 first bundle of glass fibers 17 second bundle of glass fibers 18 yarn 20 supply systems 30 treatment station
    权利要求:
    Claims (15)
    [1]
    Conclusions
    A sleeve for covering a roll for transporting glass panels, wherein said sleeve is a textile cloth, said textile cloth comprises yarns, said yarns comprise both glass fibers or ceramic fibers and metal fibers.
    [2]
    The sleeve of claim 1, wherein said textile fabric is a tubular fabric fabric.
    [3]
    A sleeve according to claim 1 or 2, wherein said textile fabric comprises between 10% by weight and 50% by weight of glass fibers or ceramic fibers, the remaining part being formed by metal fibers.
    [4]
    The sleeve of claims 1-3, wherein said textile fabric is a knit.
    [5]
    The sleeve of claim 4, wherein said textile fabric is a tubular knit.
    [6]
    The sleeve of claim 4 or 5, wherein said textile fabric is a weft knit.
    [7]
    The sleeve of claims 1-6, wherein said textile fabric has one or more yarns, each yarn has one or more bundles, each of said one or more bundles comprises both glass fibers or ceramic fibers and metal fibers.
    [8]
    The sleeve of claims 1-6, wherein said textile fabric has one or more yarns, each yarn has three bundles, one bundle of metal fibers, the other two bundles of glass fibers or ceramic fibers.
    [9]
    The sleeve of claim 8, wherein the two bundles are twisted together with the glass fibers or the ceramic fibers.
    [10]
    The sleeve of claim 8 or claim 9, wherein the bundle with the metal fibers is twisted together with the bundles with the glass fibers or the ceramic fibers.
    [11]
    The sleeve of claims 4-6, wherein at least one of said yarns of said knitted fabric comprises at least 3 fiber bundles, said at least one yarn comprises at least one fiber bundle comprising metal fibers, said fiber bundles are each defined by an equivalent bundle diameter, characterized in that said equivalent bundle diameter of each of said fiber bundles in said yarn is identical or differs at most 40% from each other.
    [12]
    The sleeve of claim 7, wherein said equivalent bundle diameters of each of said fiber bundles in said yarn differ by a maximum of 10%.
    [13]
    Use of a sleeve as claimed in any one of the preceding claims as a cover for a conveyor belt roll in a glass panel heating system.
    [14]
    Use according to claim 13 in a heating oven.
    [15]
    The use according to claim 13 or 14 as a cover for a straight conveyor roll.
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    法律状态:
    2019-12-05| MM| Lapsed because of non-payment of the annual fee|Effective date: 20190331 |
    优先权:
    申请号 | 申请日 | 专利标题
    EP10157985|2010-03-26|
    EP101579852|2010-03-26|
    EP10168821|2010-07-08|
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