Aplicação de nanoceluloses em fibras não branqueadas para obtenção de papéis. / Application of nanocelulose in unbleached fibers for papermaking.

Cruces Cerro, Jorge

18 August 2016

Atualmente, o Brasil é o maior fabricante de celulose branqueada de eucalipto do mundo. Geralmente as fibras virgens de Eucalyptus spp. são utilizadas na fabricação de papéis para imprimir, tissue e especiais. Papéis para embalagens, tipicamente Kraftliners, precisam de uma grande resistência mecânica e são produzidos principalmente a partir de pastas Kraft de coníferas não branqueadas. Por outro lado, nanoceluloses fabricadas a partir de biomassa são consideradas um dos materiais sustentáveis mais interessantes para o século, com excelentes propriedades como baixa densidade, elevadas propriedades mecânicas, alta hidrofilicidade, grande área superficial com reatividade química e elevado valor econômico. Desde 2012 o uso de nanoceluloses na fabricação de papel ganhou impulso. As nanoceluloses têm sido adicionadas em pastas mecânicas e Kraft branqueadas para fabricação do papel, incrementando notavelmente as suas propriedades mecânicas, mas há preocupações sobre a diminuição da drenabilidade, da porosidade e da opacidade do papel. Poucos estudos foram desenvolvidos visando a aplicação de nanoceluloses em fibras não branqueadas, ainda que tenham aplicações em pastas branqueadas e/ou mecânicas. Portanto, o presente trabalho visa desenvolver o uso de nanoceluloses para melhorar as propriedades mecânicas em fibras não branqueadas. Em primeiro lugar, tomaram-se os finos primários do branqueamento de celulose de Pasta Kraft de Eucalipto como a matéria-prima para produzir dois tipos de nanocelulose. A celulose microfibrilada (MFC) é produzida diretamente por homogeneização mecânica utilizando equipamento Masuko. A celulose nanofibrilada (CNF) é produzida por oxidação mediada por TEMPO e homogeneizada por GEA. Em segundo lugar, selecionaram-se com as fibras virgens de Pasta Kraft Marrom de Pinho (PKPM) com número Kappa 36,1 e Pasta Kraft de Eucalipto Não Branqueada (PKEP), obtida na saída de estágio de deslignificação com oxigênio, com número Kappa 9,21, e todas as fibras foram refinadas até atingir o mesmo grau Shopper-Riegler (33±1 SR). Os experimentos com PKPM são conduzidas como uma referência a papéis Kraftliners tradicionais, com ou sem nanocelluloses. Também obteve folhas manuais com pasta branqueada Kraft de eucalipto, adicionando nanoceluloses, para compreender o efeito da lignina presente em PKEP. A receita e os aditivos químicos aplicados aqui são os mesmos que na produção industrial. Os principais resultados são: o uso de CNF (ou MFC) e agentes químicos, separadamente, na pasta PKEP, aumenta as resistências mecânicas dos papéis, no entanto, quando aplicadas CNF (ou MFC) em PKMP sem aditivos químicos, as resistências à tração e a estouro diminuem, e a resistência ao rasgo permanece constante. Como a terceira parte do estudo, delineamento de experimentos teve a configuração composto central com o ponto central em 1% de CNF (ou MFC) e 1% de agentes químicos (polímero+amido+cola), e seus pontos axiais foram 0,3%-1,7% de CNF (ou MFC), e 0,15%-0,85% de agentes químicos. O ponto ótimo de equilíbrio dos índices de rasgo (mN.m2/g) /estouro (kPa.m2/g) /tração (N.m/g) de (10,00/2,25/36,56 para CNF e 12,88/4,25/57,62 para MFC), obteve-se com a adição de 1,03% de CNF e 0,65% de amido, ou com a adição de menos de 0,01% de MFC e de 1% de amido. Finalmente, foram aplicadas CNF ou MFC por impregnação direta no centro da direção-z, considerando que o papel tem forças que interagem em 3D. Os resultados mostram que a PKEP atinge a qualidade do Kraftliner de pinus obtendo um índice de tração de 52,58 N.m/g utilizando 1% de CNF, ou 47,40 N.m/g utilizando 1% de MFC. Também, o custo de utilização do CNF ou MFC na fabricação do papel é avaliado, resultando em estimativas de 0,9494 US$/kg ou 0,3036 US$/kg, com a adição de 1% de CNF ou 1% de MFC, respectivamente, em pasta PKEP. Este trabalho mostra que a aplicação de nanocelulose em Kraftliner tradicional com fibras de pinus com todos os agentes químicos não tem vantagens reais. No entanto, o uso de CNF e MFC tecnicamente e economicamente tem vantagens superiores em pasta Kraft de eucalipto não branqueada (e deslignificada com oxigênio), obtendo-se propriedades superiores às de fibras longas. / Nowadays, Brazil is the largest manufacturer of Bleached Eucalyptus Kraft Pulp in the world. Mostly the Eucalyptus spp. virgin fibres are used in papermaking to manufacture printing, tissue and specialty papers. Packaging papers, typically Kraftliners, have high demands for mechanical strength and are made mostly from Unbleached Softwood Kraft Pulp. Other side, nanocelluloses from biomass are considered one of the most interesting sustainable materials for the Century, with excel properties such as low density, high mechanical properties, high hydrophilicity, large surface area with chemical reactivity and high economic value. Since 2012 the use of nanocellulose in papermaking experienced a great momentum. Nanocelluloses are added in bleached or mechanical pulp in papermaking to increase significantly the mechanical properties, but there are concerns about the decreasing of the drainability, the porosity and the opacity of the paper. A very few studies were developed on the application of nanocelluloses in an unbleached Kraft pulp, even there are its applications on bleached pulps and mechanical pulps. Therefore, the present work aims to develop the application of nanocelluloses to increase the mechanical properties of the unbleached fibers, specifically for Kraftliners, and show the way to replace the softwood fibers with the low-cost hardwood fibers. Firstly, the primary fines from bleaching area of Eucalyptus Kraft pulp, obtained from an industrial residue, was the raw material for nanocellulose production of two nanocelluloses. The microfibrillated celluloses (MFC) are produced with direct mechanical homogenization using Masuko. The nanofibrillated cellulose (NCF) is produced with oxidation mediated by TEMPO and homogenization using GEA. Secondly, as virgin fibers were selected the Unbleached Pine Kraft Pulp (USKP) with Kappa number 36.1 and the Unbleached Eucalyptus Kraft Pulp (UEKP) just after the oxygen delignification stage with the Kappa number 9.21. All the fibres (USKP and UEKP) was refining at the same Shopper-Riegler (33±1 SR). USKP experiments are conducted as reference to traditional Kraftliners, with or without nanocelluloses. Also the virgin bleached Eucalyptus Kraft pulp with nanocelluloses addition for the handsheet paper helps to understand the role of lignin in UEKP. The recipe and chemicals applied here are the same of the industrial production. The main results are: the use CNF (or MFC) and chemical agents, separately, in UEKP, promote the mechanical resistances, however when applied CNF (or MFC) in UPKP without chemicals, the tensile and burst properties decreased and tear remains constant. As the third group of the study, the design of the experiments was conducted in the star configuration with centre point as 1% CNF (or MFC) and 1.00% chemical agents (polymers+starch+chemical agents) and, the axial points were 0.3%-1.7% NCF (or MFC) and 0.15%-0.85 of chemical agents. The optimum point from the balanced tear (mN.m2/g) /burst (kPa.m2/g) /tensile (N.m/g) index point of view with 10.00/2.25/36.56 for (1.03% CNF and 0.65% starch) and 12.88/4.25/57.62 for (<0.001% MFC and 1% starch). Finally, it is applied here the direct impregnation of the center of z-direction with 1% of CNF and MFC, considering that the paper has 3D interacting forces. The results show that the UEKP reaches the pinus Kraftliner quality with 52.58 N.m/g (Tensile Index) using 1% CNF or 47.40 N.m/g using 1% MFC. Also, the cost of use CNF or MFC in papermaking is evaluated, resulting in the estimates of 0.9494 US$/kg or 0.3036 US$/kg, the addition of 1% CNF or 1% MFC in UEKP. This work shows that the application of nanocellulose in traditional Kraftliner with pinus fibres with all chemical agents has no real advantages. However, the use of CNF and MFC technically and economically has superior advantages in Eucalyptus unbleached (and oxygen delignified) Kraft pulp, resulting in such properties superior to those of long fibres.

Celulose

CNF

Eucalipto

Eucalyptus short fibers

Fabricação do papel

Kraftliner

Kraftliner

Mechanical properties of paper

MFC

MFC

Nanocellulose

NCF

Papel (Propriedades mecânicas)

Papermaking

Aplicação de nanoceluloses em fibras não branqueadas para obtenção de papéis. / Application of nanocelulose in unbleached fibers for papermaking.

Jorge Cruces Cerro

18 August 2016

Atualmente, o Brasil é o maior fabricante de celulose branqueada de eucalipto do mundo. Geralmente as fibras virgens de Eucalyptus spp. são utilizadas na fabricação de papéis para imprimir, tissue e especiais. Papéis para embalagens, tipicamente Kraftliners, precisam de uma grande resistência mecânica e são produzidos principalmente a partir de pastas Kraft de coníferas não branqueadas. Por outro lado, nanoceluloses fabricadas a partir de biomassa são consideradas um dos materiais sustentáveis mais interessantes para o século, com excelentes propriedades como baixa densidade, elevadas propriedades mecânicas, alta hidrofilicidade, grande área superficial com reatividade química e elevado valor econômico. Desde 2012 o uso de nanoceluloses na fabricação de papel ganhou impulso. As nanoceluloses têm sido adicionadas em pastas mecânicas e Kraft branqueadas para fabricação do papel, incrementando notavelmente as suas propriedades mecânicas, mas há preocupações sobre a diminuição da drenabilidade, da porosidade e da opacidade do papel. Poucos estudos foram desenvolvidos visando a aplicação de nanoceluloses em fibras não branqueadas, ainda que tenham aplicações em pastas branqueadas e/ou mecânicas. Portanto, o presente trabalho visa desenvolver o uso de nanoceluloses para melhorar as propriedades mecânicas em fibras não branqueadas. Em primeiro lugar, tomaram-se os finos primários do branqueamento de celulose de Pasta Kraft de Eucalipto como a matéria-prima para produzir dois tipos de nanocelulose. A celulose microfibrilada (MFC) é produzida diretamente por homogeneização mecânica utilizando equipamento Masuko. A celulose nanofibrilada (CNF) é produzida por oxidação mediada por TEMPO e homogeneizada por GEA. Em segundo lugar, selecionaram-se com as fibras virgens de Pasta Kraft Marrom de Pinho (PKPM) com número Kappa 36,1 e Pasta Kraft de Eucalipto Não Branqueada (PKEP), obtida na saída de estágio de deslignificação com oxigênio, com número Kappa 9,21, e todas as fibras foram refinadas até atingir o mesmo grau Shopper-Riegler (33±1 SR). Os experimentos com PKPM são conduzidas como uma referência a papéis Kraftliners tradicionais, com ou sem nanocelluloses. Também obteve folhas manuais com pasta branqueada Kraft de eucalipto, adicionando nanoceluloses, para compreender o efeito da lignina presente em PKEP. A receita e os aditivos químicos aplicados aqui são os mesmos que na produção industrial. Os principais resultados são: o uso de CNF (ou MFC) e agentes químicos, separadamente, na pasta PKEP, aumenta as resistências mecânicas dos papéis, no entanto, quando aplicadas CNF (ou MFC) em PKMP sem aditivos químicos, as resistências à tração e a estouro diminuem, e a resistência ao rasgo permanece constante. Como a terceira parte do estudo, delineamento de experimentos teve a configuração composto central com o ponto central em 1% de CNF (ou MFC) e 1% de agentes químicos (polímero+amido+cola), e seus pontos axiais foram 0,3%-1,7% de CNF (ou MFC), e 0,15%-0,85% de agentes químicos. O ponto ótimo de equilíbrio dos índices de rasgo (mN.m2/g) /estouro (kPa.m2/g) /tração (N.m/g) de (10,00/2,25/36,56 para CNF e 12,88/4,25/57,62 para MFC), obteve-se com a adição de 1,03% de CNF e 0,65% de amido, ou com a adição de menos de 0,01% de MFC e de 1% de amido. Finalmente, foram aplicadas CNF ou MFC por impregnação direta no centro da direção-z, considerando que o papel tem forças que interagem em 3D. Os resultados mostram que a PKEP atinge a qualidade do Kraftliner de pinus obtendo um índice de tração de 52,58 N.m/g utilizando 1% de CNF, ou 47,40 N.m/g utilizando 1% de MFC. Também, o custo de utilização do CNF ou MFC na fabricação do papel é avaliado, resultando em estimativas de 0,9494 US$/kg ou 0,3036 US$/kg, com a adição de 1% de CNF ou 1% de MFC, respectivamente, em pasta PKEP. Este trabalho mostra que a aplicação de nanocelulose em Kraftliner tradicional com fibras de pinus com todos os agentes químicos não tem vantagens reais. No entanto, o uso de CNF e MFC tecnicamente e economicamente tem vantagens superiores em pasta Kraft de eucalipto não branqueada (e deslignificada com oxigênio), obtendo-se propriedades superiores às de fibras longas. / Nowadays, Brazil is the largest manufacturer of Bleached Eucalyptus Kraft Pulp in the world. Mostly the Eucalyptus spp. virgin fibres are used in papermaking to manufacture printing, tissue and specialty papers. Packaging papers, typically Kraftliners, have high demands for mechanical strength and are made mostly from Unbleached Softwood Kraft Pulp. Other side, nanocelluloses from biomass are considered one of the most interesting sustainable materials for the Century, with excel properties such as low density, high mechanical properties, high hydrophilicity, large surface area with chemical reactivity and high economic value. Since 2012 the use of nanocellulose in papermaking experienced a great momentum. Nanocelluloses are added in bleached or mechanical pulp in papermaking to increase significantly the mechanical properties, but there are concerns about the decreasing of the drainability, the porosity and the opacity of the paper. A very few studies were developed on the application of nanocelluloses in an unbleached Kraft pulp, even there are its applications on bleached pulps and mechanical pulps. Therefore, the present work aims to develop the application of nanocelluloses to increase the mechanical properties of the unbleached fibers, specifically for Kraftliners, and show the way to replace the softwood fibers with the low-cost hardwood fibers. Firstly, the primary fines from bleaching area of Eucalyptus Kraft pulp, obtained from an industrial residue, was the raw material for nanocellulose production of two nanocelluloses. The microfibrillated celluloses (MFC) are produced with direct mechanical homogenization using Masuko. The nanofibrillated cellulose (NCF) is produced with oxidation mediated by TEMPO and homogenization using GEA. Secondly, as virgin fibers were selected the Unbleached Pine Kraft Pulp (USKP) with Kappa number 36.1 and the Unbleached Eucalyptus Kraft Pulp (UEKP) just after the oxygen delignification stage with the Kappa number 9.21. All the fibres (USKP and UEKP) was refining at the same Shopper-Riegler (33±1 SR). USKP experiments are conducted as reference to traditional Kraftliners, with or without nanocelluloses. Also the virgin bleached Eucalyptus Kraft pulp with nanocelluloses addition for the handsheet paper helps to understand the role of lignin in UEKP. The recipe and chemicals applied here are the same of the industrial production. The main results are: the use CNF (or MFC) and chemical agents, separately, in UEKP, promote the mechanical resistances, however when applied CNF (or MFC) in UPKP without chemicals, the tensile and burst properties decreased and tear remains constant. As the third group of the study, the design of the experiments was conducted in the star configuration with centre point as 1% CNF (or MFC) and 1.00% chemical agents (polymers+starch+chemical agents) and, the axial points were 0.3%-1.7% NCF (or MFC) and 0.15%-0.85 of chemical agents. The optimum point from the balanced tear (mN.m2/g) /burst (kPa.m2/g) /tensile (N.m/g) index point of view with 10.00/2.25/36.56 for (1.03% CNF and 0.65% starch) and 12.88/4.25/57.62 for (<0.001% MFC and 1% starch). Finally, it is applied here the direct impregnation of the center of z-direction with 1% of CNF and MFC, considering that the paper has 3D interacting forces. The results show that the UEKP reaches the pinus Kraftliner quality with 52.58 N.m/g (Tensile Index) using 1% CNF or 47.40 N.m/g using 1% MFC. Also, the cost of use CNF or MFC in papermaking is evaluated, resulting in the estimates of 0.9494 US$/kg or 0.3036 US$/kg, the addition of 1% CNF or 1% MFC in UEKP. This work shows that the application of nanocellulose in traditional Kraftliner with pinus fibres with all chemical agents has no real advantages. However, the use of CNF and MFC technically and economically has superior advantages in Eucalyptus unbleached (and oxygen delignified) Kraft pulp, resulting in such properties superior to those of long fibres.

Celulose

CNF

Eucalipto

Fabricação do papel

Kraftliner

MFC

Papel (Propriedades mecânicas)

Eucalyptus short fibers

Kraftliner

Mechanical properties of paper

MFC

Nanocellulose

NCF

Papermaking

The Use of Lignin Derivatives to Improve Selected Paper Properties

Antonsson, Stefan

January 2007

<p>Ved består huvudsakligen av tre typer av polymerer, cellulosa, hemicellulosa och lignin. Lignin bildas i naturen genom enzymatiskt initierad oxidativ koppling av tre olika typer av fenylpropan-enheter. Dessa bygger genom olika kol-kol- och kol-syre-bindningar upp en amorf tredimensionell polymer. När kemisk massa tillverkas bryts lignin ner och löses ut i kokluten. Luten innehåller de förbrukade kokkemikalierna och bränns generellt i en sodapanna för att regenerera kemikalierna och producera ånga. Sodapannan är emellertid dyr. Därför har den blivit produktionsbegränsande på många massabruk. Att avlägsna en del av ligninet från avluten vore därför önskvärt och att finna ekonomiskt intressanta produkter baserade på lignin från svartlut är därför ett viktigt forskningsområde .</p><p>Ett lämpligt område för ligninprodukter vore som tillsatts i oblekt massa. Oblekt massa används till stor del för tillverkning av kraftliner, topp- och bottenskikten på wellpapp. När lådor av wellpapp lagras i containrar som färdas över haven, förändras den relativa luftfuktigheten. Detta gör att lådorna kollapsar lättare än om de skulle ha lagrats vid konstant luftfuktighet, även en hög sådan. Detta är på grund av det så kallade mekanosorptiva- eller accelererade krypfenomenet. Genom tillsatts av våtstyrkemedel till kraftliner eller behandla den med hydrofoba ämnen, finns indikatoner på att mekanosorptiva effekten skulle kunna minska.</p><p>För att försöka minska den effekten har ett lågmolekylärt kraftlignin, som utvunnits med hjälp av tvärsflödesfiltrering av svartlut och svavelsyrafällning, använts. Genom derivatisering av detta lignin med linolja erhölls ett hydrofobt ligninderivat som uppvisar strukturella likheter med biopolymeren suberin. När detta suberinlika ligninderivat tillsätts till massa verkar det mekanosorptiva krypet minska. När lågmolekylärt lignin används tillsammans med ligninradikalinitiatorerna lackas eller mangan(III) i kraftlinermassa erhålls dessutom en våtstyrka på ca 5% av torrstyrkan. Efter aminering av detta lignin gav en tillsatts till kraftlinermassan en våtstyrka på upp till 10% av torrstyrkan. Det finns indikationer på att det mekanosorptiva krypet samtidigt minskar när dessa behandlingar görs som ger upphov till ökad våtstyrka.</p> / <p>Wood consists mainly of three types of polymers; cellulose, hemi cellulose and lignin. Lignin is formed in nature through enzymatic initiated oxidative coupling of three different kinds of phenyl propane units. These form by various carbon-carbon and carbon-oxygen bonds, an amorphous three-dimensional polymer. As chemical pulp is produced, lignin is degraded and dissolved into pulping liquors. These liquors contain the spent cooking chemicals and are generally burnt in a recovery boiler to regenerate cooking chemicals and produce steam. However, the recovery boiler is expensive. Hence, it has become the bottleneck for production in many pulp mills. Removal of some lignin from the spent cooking liquor would, for that reason, be desired and valuable products based on lignin from cooking liquors are searched for.</p><p>One suitable area for lignin products would be as additive in unbleached pulp. A major product from unbleached pulp is kraftliner, the top and bottom layers of corrugated board. When boxes of corrugated board are stored in containers travelling overseas the relative humidity is varying. This makes the boxes collapse more easily than if they were stored at constant humidity, even a high one. This is due to the so called mechano-sorptive or accelerated creep phenomenon. By addition of wet strength additive to kraftliner or treating it with hydrophobic compounds there are indications on that the mechano-sorptive effect would decrease.</p><p>Trying to decrease this effect, low molecular weight kraft lignin has been used. It was obtained by cross-flow filtration of black liquor and precipitation by sulphuric acid. By derivatisation of this lignin by linseed oil, a hydrophobic lignin derivative was obtained, similar in structure to units in the biopolymer suberin. As this suberin-like lignin-derivative was added to pulp the mechano-sorptive creep seemed to be lowered. Furthermore, when the low molecular weight lignin was used together with the lignin radical initiators laccase or manganese(III) in kraftliner pulp, a wet strength of about 5% of dry strength was obtained. An amination treatment of this lignin and addition to kraftliner pulp resulted in a wet strength of up to 10% of dry strength. There are indications of that the mechano-sorptive creep also decreases as these treatments, resulting in increased wet strength, are made.</p>

kraft lignin

black liquor

cross-flow filtration

lignin derivative

kraftliner

oxidative coupling

laccase

manganese

linseed oil

mechano-sorptive creep

kraftlignin

svartlut

tvärsflödesfiltrering

ligninderivat

kraftliner

oxidativ koppling

lackas

mangan

linolja

mekanosorptivt kryp

Cellulose and paper engineering

Cellulosa- och pappersteknik

The Use of Lignin Derivatives to Improve Selected Paper Properties

Antonsson, Stefan

January 2007

Ved består huvudsakligen av tre typer av polymerer, cellulosa, hemicellulosa och lignin. Lignin bildas i naturen genom enzymatiskt initierad oxidativ koppling av tre olika typer av fenylpropan-enheter. Dessa bygger genom olika kol-kol- och kol-syre-bindningar upp en amorf tredimensionell polymer. När kemisk massa tillverkas bryts lignin ner och löses ut i kokluten. Luten innehåller de förbrukade kokkemikalierna och bränns generellt i en sodapanna för att regenerera kemikalierna och producera ånga. Sodapannan är emellertid dyr. Därför har den blivit produktionsbegränsande på många massabruk. Att avlägsna en del av ligninet från avluten vore därför önskvärt och att finna ekonomiskt intressanta produkter baserade på lignin från svartlut är därför ett viktigt forskningsområde . Ett lämpligt område för ligninprodukter vore som tillsatts i oblekt massa. Oblekt massa används till stor del för tillverkning av kraftliner, topp- och bottenskikten på wellpapp. När lådor av wellpapp lagras i containrar som färdas över haven, förändras den relativa luftfuktigheten. Detta gör att lådorna kollapsar lättare än om de skulle ha lagrats vid konstant luftfuktighet, även en hög sådan. Detta är på grund av det så kallade mekanosorptiva- eller accelererade krypfenomenet. Genom tillsatts av våtstyrkemedel till kraftliner eller behandla den med hydrofoba ämnen, finns indikatoner på att mekanosorptiva effekten skulle kunna minska. För att försöka minska den effekten har ett lågmolekylärt kraftlignin, som utvunnits med hjälp av tvärsflödesfiltrering av svartlut och svavelsyrafällning, använts. Genom derivatisering av detta lignin med linolja erhölls ett hydrofobt ligninderivat som uppvisar strukturella likheter med biopolymeren suberin. När detta suberinlika ligninderivat tillsätts till massa verkar det mekanosorptiva krypet minska. När lågmolekylärt lignin används tillsammans med ligninradikalinitiatorerna lackas eller mangan(III) i kraftlinermassa erhålls dessutom en våtstyrka på ca 5% av torrstyrkan. Efter aminering av detta lignin gav en tillsatts till kraftlinermassan en våtstyrka på upp till 10% av torrstyrkan. Det finns indikationer på att det mekanosorptiva krypet samtidigt minskar när dessa behandlingar görs som ger upphov till ökad våtstyrka. / Wood consists mainly of three types of polymers; cellulose, hemi cellulose and lignin. Lignin is formed in nature through enzymatic initiated oxidative coupling of three different kinds of phenyl propane units. These form by various carbon-carbon and carbon-oxygen bonds, an amorphous three-dimensional polymer. As chemical pulp is produced, lignin is degraded and dissolved into pulping liquors. These liquors contain the spent cooking chemicals and are generally burnt in a recovery boiler to regenerate cooking chemicals and produce steam. However, the recovery boiler is expensive. Hence, it has become the bottleneck for production in many pulp mills. Removal of some lignin from the spent cooking liquor would, for that reason, be desired and valuable products based on lignin from cooking liquors are searched for. One suitable area for lignin products would be as additive in unbleached pulp. A major product from unbleached pulp is kraftliner, the top and bottom layers of corrugated board. When boxes of corrugated board are stored in containers travelling overseas the relative humidity is varying. This makes the boxes collapse more easily than if they were stored at constant humidity, even a high one. This is due to the so called mechano-sorptive or accelerated creep phenomenon. By addition of wet strength additive to kraftliner or treating it with hydrophobic compounds there are indications on that the mechano-sorptive effect would decrease. Trying to decrease this effect, low molecular weight kraft lignin has been used. It was obtained by cross-flow filtration of black liquor and precipitation by sulphuric acid. By derivatisation of this lignin by linseed oil, a hydrophobic lignin derivative was obtained, similar in structure to units in the biopolymer suberin. As this suberin-like lignin-derivative was added to pulp the mechano-sorptive creep seemed to be lowered. Furthermore, when the low molecular weight lignin was used together with the lignin radical initiators laccase or manganese(III) in kraftliner pulp, a wet strength of about 5% of dry strength was obtained. An amination treatment of this lignin and addition to kraftliner pulp resulted in a wet strength of up to 10% of dry strength. There are indications of that the mechano-sorptive creep also decreases as these treatments, resulting in increased wet strength, are made. / QC 20101103

kraft lignin

black liquor

cross-flow filtration

lignin derivative

kraftliner

oxidative coupling

laccase

manganese

linseed oil

mechano-sorptive creep

kraftlignin

svartlut

tvärsflödesfiltrering

ligninderivat

kraftliner

oxidativ koppling

lackas

mangan

linolja

mekanosorptivt kryp

Paper, Pulp and Fiber Technology

Pappers-, massa- och fiberteknik

Strategies for improving kraftliner pulp properties

Antonsson, Stefan

January 2008

A large part of the world paper manufacturing consists of production of corrugated board components, kraftliner and fluting, that are used in many different types of corrugated boxes. Because these boxes are stored and transported, they are often subjected to changes in relative humidity. These changes together with mechanical loads will increase the deformation of the boxes compared to the case where the same loads are applied in a static environment. This enlarged creep due to the changes in relative humidity is called mechano-sorptive or accelerated creep. Mechano-sorptive creep forces producers to use high safety factors when designing boxes, and therefore, this is one of the key properties of kraftliner boards.   Different strategies to decrease mechano-sorptive creep, and to simultaneously gain more knowledge about the causes for this phenomenon in paper, are the aim of this work. Derivatised and underivatised black liquor lignins, a by-product produced in pulp mills in large quantities, have been used together with biomimetic methods, to modify the properties of kraftliner pulp. Furthermore, the properties of kraftliner pulp have been compared to other pulps in order to evaluate the influence of fibre morphological factors, such as fibre width and shape factor, on the mechano-sorptive creep. In addition the influence of the chemical composition of the kraftliner pulp has been evaluated both by means of treating a kraftliner pulp with chlorite and xylanase and by producing pulps with different chemical composition.   By using lignin and biomimetic methods, to create radical coupling reactions, it has been shown that it is possible to increase the wet strength of kraftliner pulp sheets. This method of treating the pulp showed, however, no significant effects on the mechano-sorptive creep. The addition of an apolar suberin-like lignin derivative, which has been shown to be possible to produce from natural resources, did show a positive effect on mechano-sorptive creep properties, but at the expense of stiffness properties in constant climate. Different pulps were compared with a kraftliner pulp and it was observed that the ratio between tensile stiffness and hygroexpansion can be used to estimate the mechano-sorptive creep properties. The hardwood kraft pulps investigated had lower hygroexpansion, probably due to more slender and straighter fibres, and higher tensile stiffness, probably due to lower lignin content. As the lignin content was varied by different methods in kraft pulps, it was observed that increased lignin content gives an increased hygroexpansion and decreased tensile stiffness as well as an increased mechano-sorptive creep. There were also indications of increased mechano-sorptive creep due to higher xylan content. / En stor del av världens papperstillverkning utgörs av produktion av wellpappkomponenter, kraftliner och fluting, som används i en uppsjö av olika wellpapplådor. När dessa lådor lagras och transporteras utsätts de ofta för förändringar i relativa luftfuktigheten. Dessa förändringar tillsammans med mekanisk belastning ökar lådornas deformation jämfört med om samma belastning skulle ha applicerats vid ett statiskt klimat. Denna förhöjda krypning på grund av förändringarna i relativ luftfuktighet kallas mekanosorptiv- eller accelererad krypning. Mekanosorptiv krypning tvingar producenterna att ha höga säkerhetsmarginaler vid dimensioneringar av lådor och är därför en av nyckelegenskaperna för kraftliner.   Olika strategier för att minska denna effekt, och på samma gång erövra mer kunskap om orsakerna till detta fenomen, har varit syftet med arbetet. Derivatiserade och oderivatiserade svartlutslignin, en biprodukt möjlig att få ut i stora kvantiteter från massabruk, har används tillsammans med biomimetriska metoder, för att modifiera kraftlinermassas egenskaper. Dessutom har kraftlinermassans egenskaper jämförts med andra massors egenskaper för att utvärdera inverkan av fibermorfologiska faktorer, såsom fiberbredd och fibreform på det mekanosorptiva krypet. Också inverkan av den kemiska sammansättningen av kraftliner massan har undersökts både genom behandling med klorit och xylanas och genom att producera massor med olika kemiska sammansättningar.   Genom att använda lignin och biomimetriska metoder för att skapa radikal-kopplingsreaktioner har det visats på möjligheten att öka våtstyrkan i massa-ark. Det här sättet att behandla massa visade dessvärre inga signifikanta effekter på det mekanosorptiva krypet. Tillsatts av ett apolärt suberin-liknande ligninderivat, som visats möjligt att producera ur naturliga råmaterial, visade en positiv effekt på det mekanosorptiva krypegenskaperna även om det var på bekostnad av styvheten vid konstant klimat. Olika massor jämfördes med en kraftlinermassa och det observerades att relationen mellan dragstyvhet och hygroexpansion kan användas för att uppskatta de mekanosorptiva krypegenskaperna. Lövvedssulfatmassorna som undersöktes hade lägre hygroexpansion, antagligen beroende på smalare och rakare fibrer, och högre dragstyvhet, troligen beroende på en lägre ligninhalt. När ligninhalten varierades i sulfatmassor med olika metoder observerades att ökad ligninhalt ger en ökad hygroexpansion och minskad dragstyvhet liksom en ökad mekanosorptiv krypning. Dessutom fanns indikationer på en ökad mekanosorptiv krypning till följd av högre xylaninnehåll. / QC 20100629

lignin

xylan

kraftliner pulp

mechano-sorptive creep

hygroexpansion

stiffness

fibre shape

fibre width

lignin

xylan

kraftlinermassa

mekanosorptivt kryp

hygroexpansion

styvhet

fiberform

fiberbredd

Cellulose and paper engineering

Cellulosa- och pappersteknik

Kampen om Piteå handelshamn 1950 - 1973 : från lokal stadshamn till nationell handelshamn

Johansson, Rolf

January 2011

Survey's purpose is to illustrate why and how the process happened when Piteå relocated its commercial port away from Skuthamn to the new construction on Haraholmen 1950-1973. How decision-makers worked to achieve their goals, how the work changed and what incentives motivated them to act. The results showed that the decision was taken not to retain the existing commercial port in large part due to Skuthamns physics attributes, which made it impossible to ship large deep vessels from there. The reason that the decision about the port took such a long time was due to a local political conflict which was based on interest in the ownership of Haraholmen. The reason for the location of the trading port became Haraholmen had political backgrounds. The study's methodology is qualitative and describes the events chronologically. / Undersökningens syfte är att belysa varför och hur processen gick till när Piteå flyttade sin kommersiella hamn bort från Skuthamn och byggde upp den nya internationella handelshamnen på Haraholmen 1950-1973. Hur beslutsfattarna arbetade för att nå sina mål, hur förändrades deras arbetsmetoder med tiden och vilka incitament som motiverade dem att agera. Resultaten visade att beslutet som fattades att inte behålla den befintliga kommersiella hamnen Skuthamn som Piteås handelshamn till stor del berodde på att Skuthamns fysiska attribut omöjliggjorde transporter dit med stora djupgående fartyg. Anledningen till att beslutet om hamnen tog så lång tid berodde på en lokalpolitisk konflikt som grundade sig i vilken aktör som innehade äganderätten av markområdet på Haraholmen. Anledningen till lokaliseringen av handelshamnen på Haraholmen hade sin bakgrund i statens transportpolitik. Metoden som använts är kvalitativ och beskriver händelserna kronologiskt.

hamn

handelshamn

Piteå

Haraholmen

Klemenäs

Holmsund

Umeå

Luleå

stadshamn

hamnar

norrland

norrbotten

älv

älvar

lokalisering

hastighetsprincipen

närhetsprincipen

Hamndirektionen

SCA

ASSI

Cementa

Hamnstyrelsen

Piteå kommun

hamnutredning

riksfarled

SJ

kraftliner

Lövholmen

centralhamn