• 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:
    Abstract The invention provides an energy efficient method to manufacture 3D shaped articles, withsmooth crease-free surfaces, from cellulose-based material. The method comprises the steps of: - providing a suspension with a dry content of more than 10%, whichsuspension comprises at least 95w% of cellulose fibers calculated on the totalamount of dry material, whereof at least 50w% of said cellulose fibers have afiber length of less than 1 mm, - spraying said suspension on a 3D-shaped, heated mold having a smoothsurface, in at least a first step, whereby a 3D shaped article of cellulose fiberbased material is formed, - drying said 3D shaped article.
    公开号:SE1650262A1
    申请号:SE1650262
    申请日:2016-02-29
    公开日:2017-08-30
    发明作者:Axrup Lars;Gullander Kristina
    申请人:Stora Enso Oyj;
    IPC主号:
    专利说明:

    Method of manufacturing 3D shaped articlesTechnical Field The present invention relates to a method of manufacturing a 3D shaped article from cellulose fiber based material.Background Three-dimensional (3D) shaped packages including various shapes, such dimples included ininserts for chocolate boxes, holding the chocolate pieces, or deep trays, are usually madefrom plastic materials or from paperboard molded to the desired shape. However,paperboard is not as flexible as plastic and problems with creases oftentimes occur during molding.
    Other examples of 3D shaped packages made from cellulose fiber based materials aremolded pulp packages, such as egg cartons. Egg cartons are usually made from pulp ofrecycled paper. ln the production of molded pulp packages, formation molds descend in avat filled with pulp. A Vacuum sucks the pulp mixture onto the formation molds. Theformation molds contain a stainless steel mesh, which ensures an even vacuum through themold so that the pulp is spread evenly. However, molded pulp packages produced in such a way have a very rough surface which is not suitable for printing. ln recent years, the potential of using highly fibrillated cellulose, such as microfibrillated pulp(MFC) or nanocellulose in paper and paperboard production to enhance strength or provide barrier functionality has been observed by the industry. ln paper or paperboard applicationssuch highly fibrillated cellulose has been used as an additive to be added e.g. in the wet-end, or applied in the coating or surface sizing of the paper or paperboard.
    WO2004055268 describes a method to form molded cellulosic articles by drying andoptionally pressing a fiber suspension comprising cellulose enzyme-treated MFC in castingmolds to obtain the articles. The patent application exemplifies a tray made of e-M FC thatwas prepared in a Finnish Hand Sheet Former and then press dried to the desired shape.Thus, in this method an MFC sheet is pressed into the desired shape, whereby cracks and wrinkles might occur.
    There thus remains a need for a method to manufacture 3D shaped articles with smooth, crease-free surfaces, from cellulose based material.Summary of the invention The object of the present invention is to provide a method to enable manufacturing of 3Dshaped articles that fulfills the above identified needs. Thus, it is an object of the presentinvention to provide an energy efficient method to manufacture 3D shaped articles fromcellulose-based material without the problems with roughness and creases connected with the prior art solutions.
    According to the invention the object above is attained by a method of manufacturing a 3Dshaped article from cellulose fiber based materials according to the attached patent claims.
    The method ofthe invention comprises the steps of: - providing a suspension with a dry content of more than 10%, whichsuspension comprises at least 95w% of cellulose fibers calculated on the totalamount of dry material, whereof at least 50w% of said cellulose fibers have afiber length of less than 1 mm, - spraying said suspension on a 3D-shaped, heated mold having a smoothsurface, in at least a first step, whereby a 3D shaped article of cellulose fiberbased material is formed, - drying said 3D shaped article.
    The method of the invention provides a 3D article with a smooth, crease free surface.Problems with creases and roughness in the surface of the article are efficiently avoided. Thesuspension comprising cellulose fibers can be applied at high concentrations, which renderthe method energy efficient and thus environmental friendly. The dry content of thesuspension to be sprayed on the mold may be at least 15%, preferably between 15 - 30% orbetween 15 - 25%. The method further enables the manufacturer to have control of the application and ofthe thickness ofthe formed article.
    The drying ofthe 3D shaped article is preferably accomplished by contactless drying, e.g. byuse of hot air (generated e.g. by use of electricity, oil, bottled gas, burners or natural gas), Infrared heating (IR) or microwaves. Dewatering, e.g. by use of vacuum, is avoided whereby problems with roughening of the surface of the article is diminished. Thus, the drying isaccomplished using drying methods excluding dewatering methods wherein water is removed from the surface of the formed article through the mold. ln one embodiment of the invention, the suspension may comprise at least 98w%, at least99w%, or even 100w% cellulose fibers, calculated on the dry weight. The cellulose fibers maybe nanofibrillated polysaccharide, such as microfibrillated cellulose (MFC). The suspension ispreferably an aqueous suspension, but other solvents, such as alcohols or ketones, may alsobe used. ln addition to the cellulose fibers, the suspension may optionally comprise small amounts of additives such as binders, pigments and/or dyes.
    At least 50w% of the cellulose fibers in the suspension are constituted of fibers having a fiberlength of less than 1mm. However, this proportion of short fibers (having a fiber length ofless than 1mm) in the suspension may advantageously be higher than 50w%, e.g. at least70w%, at least 80w% or even up to 100w% (calculated on the total dry weight of thesuspension). The higher amount of short fibers, the greater affinity of the fibers to the mold surface and the smoother surface ofthe formed article is achieved. ln one preferred embodiment, the suspension comprising short fibers is sprayed onto amale-formed mold, whereby shrinkage of the article is avoided during drying. The outersurface of said male-formed mold, which surface is to be sprayed with the fiber solution, is smooth, having no apertures.
    The suspension may be sprayed on the mold in at least a first and a second step, preferablywith in-between drying. This facilitates an even application and enhances the smoothness ofthe article even further. Moreover, the spraying of the suspension in several steps accordingto this embodiment render the use of suspensions with high concentrations of fiberspossible which further improves the energy efficiency. The suspension may be sprayed onthe mold in further steps, e.g. in three, four, 10 or even 30 steps, with in-between drying.The in-between drying may be accomplished by use ofthe same drying technologies as thefinal drying ofthe article, using contactless drying such as hot air, IR or microwaves.Preferably, the article formed in each spraying step is dried to a dry content of at least 50%,preferably to between 50-70%, prior to the subsequent spraying step. ln each spraying step, a 3D-shaped fiber layer is formed on the mold with a grammage of e.g. 2-50 gsm, preferably around 5 -10 gsm. The grammage ofthe finally formed article may be e.g. around 300 gsm depending on the end-product targeted.
    Further features, objects and advantages with the present invention are defined in the following detailed description of the invention.Detailed Description The present invention relates to a method to manufacture a 3D shaped article from cellulosebased material. The method enables 3D shaped articles to be produced from cellulose basedmaterial in an energy efficient and environmentally friendly way without the drawbacksconnected to the prior art. The 3D articles produced by the invention are preferably 3Dshaped packages or parts of packages e.g. trays, details for liquid packages, cosmeticpackages, inserts for boxes comprising dimples such as inserts for chocolate, mobile phones or other products.
    By the term ”dry content” throughout the application it is meant content of dry matter in aslurry or solution. That is, for example 10% dry content means that the weight of the drymatter is 10%, based on the total weight of the solution or slurry. Analogously, by ”dry weight” is meant the weight of dry matter.
    By ”smooth surface” is meant a continuous surface without any holes, depressions or protrusions.By ”fiber length" is meant the weighted average fiber lengthBy ”fiber width” is meant the weighted average fiber width The ”nanofibrillated polysaccharide" may be any type of highly fibrillated fibers, such asmicrofibrillated cellulose (MFC), nanofibrillated cellulose, nanocrystalline cellulose, andcellulose fibrils or a mixture thereof. The definition of nanofibrillated polysaccharide includesbacterial cellulose or nanocellulose spun with either traditional spinning techniques or withelectrostatic spinning. The fibers can also be formed by other means using e.g. ionic liquidsor membrane techniques (precipitation or coagulation of dissolved cellulose) and thus either a form of regenerated cellulose or liberated fibrils obtained by selective dissolving liquids.
    The microfibrillated cellulose (MFC) is also known as nanocellulose, nanofibrillated celluloseor cellulose nanofibrils (CNF). lt is a material typically made from wood cellulose fibers, bothfrom hardwood or softwood fibers. lt can also be made from microbial sources, agriculturalfibers such as wheat straw pulp, bamboo or other non-wood fiber sources. ln microfibrillated cellulose the individual microfibrils have detached from each other. Amicrofibrillated cellulose fibril is normally very thin (N20 nm) and the length is often between100 nm to 10 pm. MFC can be made with different means such as mechanically or chemicallyor enzymatically or by using bacteria or by combining e.g. chemical and mechanical treatment steps." The 3D articles formed by the method of the invention are composed by one (or several)layer(s) with a pre-determined thickness, which thickness is substantially the same in alldirections of the layer's extension. Said layer has a first and a second side. The 3D shape ofthe article is formed such that a depression in the first side of the layer (or layers) corresponds to a protrusion in the corresponding second side ofthe layer.
    As described herein, it has surprisingly been found that it is possible to form a fiber-based,3D article, by spraying a fiber suspension on a smooth form and thereby achieve a 3D articlewith a smooth and substantially crease-free surface. lt has been assumed in the art thatsome kind of dewatering through the mold, e.g. by use of vacuum, is needed to attach afiber suspension to the mold. However, the use of a suspension comprising a considerablyhigh amount of short fibers enhances the affinity of the fibers to the mold. The spraying ofsaid suspension onto the mold increases the production efficiency and gives rise to an even and smooth application of the fibers onto the mold.
    The fiber suspension to be sprayed on the mold is preferably an aqueous suspension (orslurry). The suspension is prepared by dispersion fibers in an aqueous media. The suspensioncomprises at least 95w% of cellulose fibers, calculated on the total amount of dry materialin the suspension, whereof at least 50w% of said cellulose fibers have a fiber length of lessthan 1 mm. The remaining part ofthe cellulose fibers may be longer fibers of hardwoodand/or softwood. The cellulose fibers (both the shorter and the longer fraction) may besoftwood and/or hardwood e.g. from pine, spruce, birches, eucalyptus, oaks, beeches or poplars and combination of any of these. ln addition to the fibers, the suspension may comprise additives, such as binders, pigments and/or dies, which additive can be added to the aqueous media before or after the addition of the fibers.
    The mold is preferably a male-formed mold having a convex form, which could includesmooth or sharp curves. The skilled person realizes that the mentioned convex form couldbe any kind of form, e.g. rectangular, crescent-shaped, triangular, astral, uniform or irregularetc. The outer surface of the mold, which is to be sprayed with the fiber suspension, issmooth and non-permeable, preferably having a surface roughness of below 2 pm Ra, orpreferably below 1 pm Ra. One example of a mold is shown in fig. 1. The mold shown in fig. 1 has a substantially flat base surface 1, and a curved, convex protrusion 2.
    The mold is heated and may be of e.g. aluminum, stainless steel, steel or cast iron .The moldmay be heated to a temperature of around 100 - 200 C°, by use of e.g. contact heating ,direct heating, induction heating, by circulating heating liquid in channels in the mold orother heating methods well known to the skilled person. The mold may be pre-heated orcontinuously heated. Optimally, the mold is held at a temperature of between 100 - 200 °C,preferably between 100 - 130 °C, during the spraying operation. ln accordance with onepreferred embodiment ofthe invention, the fiber suspension is sprayed on the mold inseveral steps, with in-between drying by use of e.g. hot air, infrared radiation (IR) ormicrowaves. The spraying may be done by use of any spraying technology known to theskilled person, e.g. by use of air-less or air-assisted spraying technology. The fiber suspensionis applied on the mold in an amount forming subsequent layers of fiber material, each layerhaving a grammage of around 5 - 10 gsm. After the final layer has been applied, the article isdried to a dry content of around 95w%. The article formed thereby may be pulled off themold. Alternatively, the article is dried to a dry content of around 50 - 95 w%, pulled off themold and further dried to a dry content of at least 95w%. The thereby formed article showsexcellent smoothness on both the surface which has been in contact with the mold and theopposite surface, due to the combination ofthe smooth mold, the application method and the short fiber length ofthe cellulose fibers.
    The invention is further described by way of an example below.
    Example 1: An aqueous suspension comprising cellulose fibers from softwood kraft pulp is preparedwhich fibers have been refined and cut to a fiber length of less than 0,8 mm. The suspensionis formed by slurring the refined fibers in water forming an aqueous suspension with a drycontent of around 12%. Said suspension is sprayed on a mold similar to the one shown in fig.1, which mold is pre-heated to a temperature of around 100 °C. The suspension is sprayedon the mold in an amount to form a first fiber layer with a grammage of around 20 gsm.Thereafter, the formed fiber layer is dried on the mold using hot air to a dry content ofaround 50 %. A second fiber layer is thereafter sprayed onto the dried first fiber layer, saidsecond fiber layer having a grammage of around 20 gsm. Said first and second fiber layersare thereafter dried on the mold. Subsequent third, fourth, fifth... up to 30 layers aresprayed onto said first layers, with intermediate hot-air drying, forming an article having thesame 3D shape as the mold. The article is pulled off the mold and a 3D shaped article showing smooth, crease-free surfaces is obtained. ln view of the above detailed description of the present invention, other modifications andvariations will become apparent to those skilled in the art. However, it should be apparentthat such other modifications and variations may be effected without departing from the spirit and scope of the invention defined in the appended claims.
    权利要求:
    Claims (9)
    [1] 1. A method of manufacturing a 3D shaped article from cellulose fiber based materialcomprising the steps of: - providing a suspension with a dry content of more than 10%, whichsuspension comprises at least 95w% of cellulose fibers calculated on the totalamount of dry material, whereof at least 50w% of said cellulose fibers have afiber length of less than 1 mm, - spraying, in at least a first spraying step, said suspension on a 3D-shaped,heated mold, which mold has a smooth surface, whereby a 3D shaped articleof cellulose fiber based material is formed, - drying said 3D shaped article.
    [2] 2. A method according to claim 1, wherein the drying of the 3D shaped article is performed by use of hot air, IR or microwaves.
    [3] 3. The method of claim 1, wherein the cellulose fibers having a fiber length of less than 1 mm are nanofibrillated polysaccharide.
    [4] 4. The method of any one of the above claims, wherein the suspension has a drycontent of at least 15 %, preferably between 15 - 30%, most preferably between 15 -25%.
    [5] 5. A method according to anyone of claims 1-4, wherein the 3D-shaped, heated mold is male-formed
    [6] 6. A method according of anyone ofthe above claims, wherein the suspension is sprayed on the mold in at least a first and a second step.
    [7] 7. A method according to claim 6, comprising a step of drying the formed article in- between said first and second steps.
    [8] 8. A method according to claim 7, wherein the article formed after the first sprayingstep is dried to a dry content of at least 50%, preferably to between 50-70%, prior to the second spraying step.
    [9] 9. A method according to claim 6 - 8, wherein the suspension is sprayed on the mold in at least three steps with in-between drying between the steps.
    类似技术:
    公开号 | 公开日 | 专利标题
    JP6849669B2|2021-03-24|Dense film surface sizing
    US11155698B2|2021-10-26|Method for the production of a film comprising microfibrillated cellulose and a film comprising microfibrillated cellulose
    JP6816040B2|2021-01-20|A method for producing a film or a film product containing an amphipathic polymer.
    CN109715883B|2022-02-11|Method for producing a film comprising microfibrillated cellulose, film and paper or board product
    SE1650262A1|2017-08-30|Method of manufacturing 3d shaped articles comprising nanofibrillated polysaccharide from cellulose
    JP2020520418A|2020-07-09|Method of making films having low oxygen transmission values
    US20200023627A1|2020-01-23|A method for the production of a coated paper, paperboard or film and a coated paper, paperboard or film
    JP6995771B2|2022-01-17|Method for Producing Film Containing Microfibrillated Cellulose
    CA3041972A1|2018-05-03|Process for providing coating layer comprising microfibrillated cellulose
    WO2015173474A1|2015-11-19|Method of producing boards
    WO2018011667A1|2018-01-18|Process for creating a foam utilizing an antimicrobial starch within a process for manufacturing a paper or board product
    JP2022506770A|2022-01-17|Methods for Dehydrating Webs Containing Microfibrillated Cellulose, and Films Made from Dehydrated Webs
    SE541755C2|2019-12-10|Process for production of film comprising microfibrillated cellulose
    JP2021520988A|2021-08-26|How to make coated paper, paperboard or film, and coated paper, paperboard or film
    CN111771025A|2020-10-13|Method for producing a film comprising microfibrillated cellulose
    CN108350663B|2021-06-15|Printing paper without ink
    WO2021038511A1|2021-03-04|Method of producing an imprintable cellulose fiber product and a fiber product
    JP2004162210A|2004-06-10|Connectable product made by papermaking
    WO2021130669A1|2021-07-01|Patterned liquid repellent nanocellulosic film
    JP2000120000A|2000-04-25|Low density article using waste paper as raw material
    同族专利:
    公开号 | 公开日
    EP3423629A1|2019-01-09|
    WO2017149408A1|2017-09-08|
    EP3423629B1|2020-12-02|
    PL3423629T3|2021-05-17|
    SE539563C2|2017-10-10|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    SE526681C2|2002-12-18|2005-10-25|Korsnaes Ab Publ|Fiber suspension of enzyme treated sulphate pulp as raw material for packaging|
    WO2009014483A1|2007-07-20|2009-01-29|Rottneros Ab|Disposable trays of fibre material coated with a removable film layer|
    SE538085C2|2012-11-09|2016-03-01|Stora Enso Oyj|Drying and mixing process for microfibrillated cellulose|
    FI125024B|2012-11-22|2015-04-30|Teknologian Tutkimuskeskus Vtt|Moldable fibrous product and process for its preparation|
    FR3003581B1|2013-03-20|2015-03-20|Ahlstroem Oy|FIBROUS MEDIUM BASED ON FIBERS AND NANOFIBRILS OF POLYSACCHARIDE|CN207468990U|2017-10-24|2018-06-08|深圳沃普智选科技有限公司|The molded equipment of plant|
    SE1950981A1|2019-08-29|2021-03-01|Stora Enso Oyj|Method of producing a cellulose fiber structure and a fiber structure|
    WO2021071870A1|2019-10-07|2021-04-15|Domtar Paper Company, Llc|Molded pulp products incorporating surface enhanced pulp fibers and methods of making the same|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    SE1650262A|SE539563C2|2016-02-29|2016-02-29|Method of manufacturing 3d shaped articles comprising nanofibrillated polysaccharide from cellulose|SE1650262A| SE539563C2|2016-02-29|2016-02-29|Method of manufacturing 3d shaped articles comprising nanofibrillated polysaccharide from cellulose|
    PCT/IB2017/050989| WO2017149408A1|2016-02-29|2017-02-22|Method of manufacturing 3d shaped articles|
    EP17709193.1A| EP3423629B1|2016-02-29|2017-02-22|Method of manufacturing 3d shaped articles|
    PL17709193T| PL3423629T3|2016-02-29|2017-02-22|Method of manufacturing 3d shaped articles|
    [返回顶部]