TECHNICAL FIELD
[0001] The present invention relates to methods for improving discoloration in pulp, more
specifically to novel methods for improving discoloration in pulp using specific compounds,
and to pulp with improved discoloration prepared by the methods for improving discoloration.
PRIOR ART
[0002] Brightness loss or discoloration in pulp over time is a common issue for any type
of pulp including chemical pulp (hereinafter referred to as CP) such as KP, AP, SP;
semi-chemical pulp (hereinafter referred to as SCP); mechanical pulp (hereinafter
referred to as MP) such as SGP, RGP, PGW, TMP, CTMP, BCTMP; and deinked pulp (hereinafter
referred to as DIP). The extent of discoloration in pulp is mainly influenced by the
residual amount of lignin or modified lignin in the pulp, and discoloration tends
to advance as the residual amount of lignin or modified lignin increases. Thus, discoloration
advances the most rapidly in MP characterized by low degrees of bleaching, followed
by SCP, and then CPs. Discoloration in DIP is greatly influenced by the MP content
or other factors.
[0003] During bleaching of pulp, lignin is oxidized to produce a hydroquinone as modified
lignin. This hydroquinone is readily oxidized via the reaction shown in Scheme 1 to
give a quinone, resulting in coloration. The lignin remaining unoxidized in the pulp
is also excited with UV light and oxidatively degraded via the reaction shown in Scheme
2 to freshly produce a quinone compound, resulting in coloration. Thus, conventional
methods for improving discoloration in pulp normally comprise degrading or removing
causative agents of discoloration such as lignin or modified lignin by adding bleaching
chemicals or alkaline chemicals during the pulp bleaching process.

[0004] According to a conventional method for improving discoloration in CP, causative agents
of discoloration such as lignin or hexenuronic acid are degraded and removed with
chemicals or the like. In this method, however, large amounts of chemicals or the
like must be used to degrade/remove lignin and these treatments cause problems such
as yield losses in bleached pulp or strength losses in pulp fibers. Large amounts
of acids are required to remove hexenuronic acid, which also invites the problem of
strength losses in pulp fibers. If the quinone compound could be degraded in advance,
such benefits as quality stabilization of paper products made from CP and the possibility
of the development of new products would be expected.
[0005] As an example of prior art, a document shows that discoloration is improved better
at higher temperatures with higher hydrogen peroxide concentrations for longer reaction
periods during the hydrogen peroxide-bleaching stage under alkaline conditions (see
non-patent document 1). A bleaching process has been patented, characterized in that
an alkali is added late in the first reaction of successive chlorine dioxide stages
when a pulp derived from a lignocellulose material is bleached through a bleaching
sequence consisting of chlorine and/or chlorine dioxide stage - alkali/oxygen stage
-chlorine dioxide stage -chlorine dioxide stage and that the ratio of chlorine dioxide
at the first to second stages is 40/60 to 70/30 (see patent document 1). A multi-stage
bleaching process has also been patented, comprising the step of treating a pulp derived
from a lignocellulose material with chlorine, alkaline extraction, and then a hypochlorite,
characterized in that 1.0% or more of an alkali is added on the basis of the bone
dry weight of the pulp during the hypochlorite-bleaching stage and the pulp is treated
at a temperature of 60°C or more (see patent document 2). A technique has been disclosed,
which is characterized in that a pulp bleached in a sequence including at least one
chlorine bleaching stage is treated with xylanase and further bleached in a bleaching
sequence including a hypochlorite stage and a chlorine dioxide stage (see patent document
3). A process for preparing a pulp with high brightness has been disclosed, comprising
further bleaching a bleached pulp derived from a lignocellulose material through a
sequence of a hyposulfite bleaching stage under high temperature and high alkali conditions
and a chlorine dioxide bleaching stage, wherein the second chlorine dioxide bleaching
stage is performed at a chlorine dioxide concentration of 1% by weight to 3% by weight
on the basis of the bone dry weight of the pulp in a chlorine dioxide/alkali ratio
of 1/0.05 to 1/0.3 and at a high temperature (see patent document 4).
[0006] It has become known from recent findings that not only conventional lignin and modified
lignin but also hexenuronic acid are responsible for discoloration in ECF or TCF bleached
pulp. This hexenuronic acid is produced by demethylation from methylglucuronic acid
in hemicellulose during a cooking step. This hexenuronic acid is said to be responsible
for discoloration in pulp. An acid treatment at a relatively high temperature was
proposed to remove the hexenuronic acid. According to this method, the hexenuronic
acid and modified lignin are removed by acid hydrolysis by treating unbleached pulp
at high temperatures under acid conditions. For example, a technique has been disclosed
wherein a suspension of a cellulose pulp prepared by the sulfate process or alkaline
process is heated and treated at about 85 to 150°C and a pH of about 2 to 5 to remove
at least about 50% of hexenuronic acid in the cellulose pulp, thereby decreasing the
Kappa number of the pulp by 2 to 9 units (see patent document 5).
[0007] MP have a pulp yield reaching even 90 to 95% because they are prepared by grinding
wood chips into fibers. Thus, it would be desirable to expand the use of MP for the
purpose of effective utilization of forest resources. However, MP are mainly used
for mechanical paper and newsprint papers due to the problem of significant discoloration,
and are only partially used for applications requiring high brightness and long shelf
life such as printing paper and recording paper at present.
The mechanism of discoloration in MP is the same as that of the lignin-induced discoloration
in the pulp described above, but discoloration in MP is more severe than in CP and
SCP because of the higher residual amount of lignin and modified lignin than in CP
and SCP. A major cause of the strong coloration in MP is that lignin is oxidized during
hydrogen peroxide-bleaching to produce a hydroquinone, which is readily oxidized into
a quinone. Discoloration becomes more severe in MP having higher brightness because
more hydroquinone is produced at higher degrees of bleaching. The lignin remaining
unoxidized in MP is also excited with UV light and oxidatively degraded to newly produce
a quinone compound, resulting in coloration. Thus, the main factor of the severe discoloration
in MP is the quinone compound, and if this quinone compound could be degraded in advance,
the severe discoloration in MP would be greatly reduced and many benefits would be
expected such as (1) quality stabilization of current paper products containing MP,
(2) enrichment in MP in current paper products with limited content of MP due to the
discoloration in MP, (3) the possibility of the development of new products containing
MP, etc.
[0008] To solve the problem of the discoloration in MP, many proposals have been made over
a long period of time, and a method using, for example, a water-soluble UV absorbent
and a photostabilizer in combination has been recently shown (see non-patent document
2). A method in which the aromatic ring contained in the lignin in MP is reduced was
also shown (see non-patent document 3). However, UV absorbents or the like have a
disadvantage in that their effect does not continue for a long period because they
are deteriorated by UV light. On the other hand, when a rhodium catalyst was used
for reducing the lignin aromatic ring, it took such a long period as 5 days to partially
hydrogenate the aromatic ring in the hydrogenation reaction of the aromatic ring of
the lignin isolated from wood at room temperature in an aqueous alcohol solution,
and this catalyst seems very difficult to directly react with the lignin present in
pulp fibers because it is used as an emulsion. Thus, all of these conventional methods
have disadvantages such as insufficient anti-fading effect, long processing time,
lack of economy or practicability, etc. at present.
[0009] One of the applicants of the present invention, the National Institute of Advanced
Industrial Science and Technology, has already filed three applications for pulp bleaching
methods involving irradiation with UV and/or visible light. Specifically, a technique
is disclosed involving irradiation with UV and/or visible light in bleaching pulp
using a reducing agent (see patent document 6). Another technique is disclosed involving
irradiation with UV and/or visible light in the presence of an organic peroxide represented
by ROOR' as an oxidizing agent (see patent document 7). Still another technique is
disclosed combining the use of hydrogen peroxide and UV and/or visible light (see
patent document 8). The present invention provides methods for improving discoloration
in pulp by applying the techniques of these prior inventions to bleached pulp.
[0010] Non-patent and patent documents cited herein as prior art are as follows:
The Bleaching of Pulp, P382, P384, TAPPI PRESS (1979), N. Hartler, TAPPI 43 (11)
903 (1960) (non-patent document 1); Japanese Patent No. 1983064 (patent document 1);
Japanese Patent No. 2115315 (patent document 2); JPA HEI 6-101185 (patent document
3); JPA HEI 9-105091 (patent document 4); JPA HEI 10-508346 (patent document 5); Yuan,
Z., et al., J. Pulp Paper Sci., 28 (5), 159 (2002) (non-patent document 2); Hu, T.
Q., et al., J. Pulp Paper Sci., 25 (9), 312 (1999) (non-patent document 3); JPA 2002-88671
(patent document 6); JPA 2002-88672 (patent document 7); JPA 2002-88673 (patent document
8).
DISCLOSURE OF THE INVENTION
[0011] The present invention aims to provide a method for improving discoloration in pulp,
characterized by:
(1) a versatile technique adaptable to any type of pulp;
(2) a time-saving process;
(3) a great and permanent anti-fading effect;
(4) environmental friendliness without unpleasant odor or toxicity;
and other properties, as well as a pulp with greatly improved discoloration obtained
by said method for improving discoloration.
[0012] Discoloration in pulp can be greatly improved by adding one or more additives selected
from the group consisting of reducing agents, peroxides and hydrogen-donating organic
compounds to one of bleached CP, SCP, MP and DIP or a mixture of two or more of them
and irradiating it with UV and/or visible light.
BRIEF EXPLANATION OF THE DRAWINGS
[0013]
FIG. 1 is a graph showing the anti-fading effect based on the brightness depending
on the laser irradiation time.
FIG. 2 is a graph showing the anti-fading effect based on the brightness depending
on the laser wavelength.
FIG. 3 is a graph showing the anti-fading effect based on the L*a*b* color difference
depending on the laser irradiation time.
FIG. 4 is a graph showing the anti-fading effect based on the L*a*b* color difference
depending on the laser wavelength.
PREFERRED EMBODIMENTS OF THE INVENTION
[0014] Pulp suitable for improving discoloration according to the present invention includes
common bleached CP, SCP, MP and DIP derived from wood. Any one of these pulp or a
mixture of two or more of the pulp may be used. The term "bleached" here means that
a CP, for example, has gone through a normal multi-stage bleaching or short sequence
bleaching process.
[0015] Specific compounds that can be used in the present invention include known reducing
agents, peroxides and hydrogen-donating organic compounds used as bleaching/decoloring
agents. Pulp is treated in the presence of at least one compound among these groups.
[0016] Such reducing agents include, for example, sulfite or bisulfite ion, hydrosulfites,
boron hydride compounds, etc. The boron hydride compounds are normally represented
by general formula (1) or (2) below.
M (BR
4-nH
n)
m (1)
wherein n = an integer of 1 to 4, m = an integer of 1 to 3, M = a metal ion, organic
ion or inorganic ion, R = a hydrocarbon group or substituted hydrocarbon group or
BR
3-nH
n (2)
wherein n = an integer of 1 to 3, R = a hydrocarbon group or substituted hydrocarbon
group.
[0017] In general formula (1) above, the metal ion is intended to include monovalent metal
ions such as alkali metals, divalent metal ions such as alkali earth metals, and trivalent
metal ions; and the organic ion may be any stable one, especially a quaternary ammonium
ion. Substituents for R include aliphatic hydrocarbon groups preferably containing
1 to 20, more preferably 1 to 10 carbon atoms, aromatic hydrocarbon groups preferably
containing 6 to 20, more preferably 6 to 14 carbon atoms, substituted hydrocarbon
groups preferably containing 7 to 40, more preferably 7 to 24 carbon atoms, etc. When
two or more substituents for R exist, R may be the same or different. Especially preferred
boron hydride compounds for use in the present invention are sodium borohydride and
tetrabutylammonium borohydride.
[0018] As for peroxides, both organic peroxides and inorganic peroxides can be used. Organic
peroxides that can be used are compounds represented by general formula (3) below:
ROOR' (3)
wherein R and R' may be the same or different and represent a hydrocarbon group, alkylcarbonyl
group, arylcarbonyl group, alkoxycarbonyl group, aryloxycarbonyl group, formyl group
or hydrogen.
[0019] Hydrocarbon groups include aromatic hydrocarbon groups such as phenyl, naphthyl,
biphenyl and anthryl groups; aliphatic hydrocarbon groups; and substituted forms thereof;
alkylcarbonyl groups include acetyl, ethylcarbonyl and propionylcarbonyl groups and
substituted forms thereof; arylcarbonyl groups include benzoyl, naphthylcarbonyl and
biphenylcarbonyl groups and substituted forms thereof; alkoxycarbonyl groups include
methoxycarbonyl and ethoxycarbonyl groups and substituted forms thereof; and aryloxycarbonyl
groups include phenoxycarbonyl, naphthoxycarbonyl and biphenyloxycarbonyl groups and
substituted forms thereof. R and R' may be the same or different. Specific examples
of these organic peroxides include, for example, peracids such as perbenzoic acid
and derivatives thereof, peracetic acid and performic acid; esters of these peracids;
and percarbonic acid and esters thereof. Inorganic peroxides include hydrogen peroxide,
sodium peroxide, etc.
[0020] Hydrogen-donating organic compounds are preferably primary alcohols represented by
general formula (4) below, and specifically include ethyl alcohol, benzyl alcohol,
furfuryl alcohol, etc.
RCH
2OH (4)
wherein R represents an alkyl, aryl, etc.
[0021] In the present invention, the reducing agents, peroxides and hydrogen-donating organic
compounds may be used alone in the absence of a solvent, but should desirably be used
as a dispersion or solution in a solvent transparent to UV and/or visible light. Such
solvents include water, alcohols, linear or cyclic alkanes, ethers, etc. alone or
mixtures thereof, preferably water.
[0022] The amount of any of the reducing agents, peroxides and hydrogen-donating organic
compounds used is not specifically limited so far as it is at or below the saturated
concentration of the compound in the solvent, but preferably 0.01 to 40% (weight/volume),
more preferably 0.1 to 20% in the solvent. The amount of any of the reducing agents,
peroxides and hydrogen-donating organic compounds used is 0.05 to 50% solids by weight,
more preferably 0.1 to 25% solids by weight on the basis of pulp solids.
[0023] The UV and/or visible light is not specifically limited, but is desirably used at
a wavelength of about 180 to 800 nm, preferably 200 to 500 nm. This is because lignin,
para-quinone and ortho-quinone have maximum absorption wavelengths of 280 nm, 360
nm and 390 to 410 nm, respectively. Suitable light sources include common light sources
such as low-pressure mercury lamps, high-pressure mercury lamps and xenon lamps; and
various excimer lamps and various lasers; but it is desirable to use laser light sources
in view of high-speed processing. The laser light sources are not specifically limited
and the laser light may be pulsed or continuous, but it is preferable to use excimer
lasers (ArF excimer laser, KrF excimer laser, XeCl excimer laser, XeF excimer laser,
etc.), argon ion laser, krypton ion laser, the second and third harmonics of YAG lasers,
etc.
[0024] The irradiation intensity is not specifically limited, but is suitably 0.1 mJ/cm
2/pulse to 1.0 kJ/cm
2/pulse for pulsed radiation and 0.1 mW to 10 kW/ cm
2 for continuous radiation. The irradiation temperature is not specifically limited
either, but is preferably -80 to 100°C, more preferably 0 to 80°C. The irradiation
time is appropriately determined taking into account the masses of potential coloring
materials contained in raw pulps, the types and concentrations of additives or solvents,
and the type and intensity of the irradiating UV and/or visible light, but normally
1 to 60 minutes will suffice.
[0025] The present invention is not specifically limited to any embodiment provided that
(1) a bleached pulp is brought into contact with (2) at least one compound selected
from reducing agents, peroxides and hydrogen-donating organic compounds and irradiated
with (3) UV and/or visible light. According to a preferred embodiment, for example,
(1) a raw pulp is dispersed in a solvent containing (2) at least one compound selected
from reducing agents, peroxides and hydrogen-donating organic compounds and transparent
to UV and/or visible light and then irradiated with (3) UV and/or visible light. Specifically
when the solvent is water, the aqueous suspension of pulp having gone through bleaching
and issuing from the bleaching step is combined and mixed with at least one compound
selected from reducing agents, peroxides and hydrogen-donating organic compounds and
then irradiated with UV and/or visible light. Alternatively, (1) a raw pulp is formed
into a sheet or thin layer, which is then impregnated with a solvent containing (2)
at least one compound selected from reducing agents, peroxides and hydrogen-donating
organic compounds, and then irradiated with (3) UV and/or visible light. Specifically
when the solvent is water, the aqueous suspension of pulp having gone through bleaching
and issuing from the bleaching step is dewatered through an apparatus such as a pulp
sheet machine into a pulp sheet, which is then impregnated with at least one compound
selected from reducing agents, peroxides and hydrogen-donating organic compounds and
irradiated with UV and/or visible light.
[0026] Although the anti-fading mechanism according to the present invention is not known
in detail, we assume as follows. That is, potential coloring materials contained in
pulp, such as lignin in MP, are oxidatively degraded by irradiation with UV and/or
visible light during bleaching to produce a hydroquinone according to the present
invention. Unmodified lignin remaining unoxidized during bleaching produces various
quinones. The present invention takes advantage of the phenomenon in which these quinones
are electronically excited from the ground state into the excited state by UV and/or
visible light, and as a result, converted into a state having more active substances,
thereby enhancing the reaction with the coexisting at least one compound selected
from reducing agents, peroxides and hydrogen-donating organic compounds to promote
the degradation reaction of the coloring materials or the hydrogenation reaction of
double bonds, or conversely the phenomenon in which at least one compound selected
from reducing agents, peroxides and hydrogen-donating organic compounds is converted
into a more active substance by irradiation with UV and/or visible light, thereby
improving the reactivity with the coloring materials to enhance the degradation reaction
of the coloring materials or the hydrogenation reaction of double bonds.
[0027] In contrast to the method previously proposed as a method for controlling discoloration
by incorporating an additive such as a thiol compound into a paper made from an MP,
which was associated with unpleasant odor and high toxicity and did not lead to a
radical improvement because such a method merely promoted the reaction of quinones
into hydroquinones and discoloration recurred by UV light once the additive had been
consumed, the method for improving discoloration according to the present invention
not only completely resolves all these problems by adopting a unique means, i.e. irradiation
with UV and/or visible light in the presence of at least one compound selected from
reducing agents, peroxides and hydrogen-donating organic compounds, but also has a
remarkable advantage in environmental friendliness.
EXAMPLES
[0028] The following examples further illustrate the present invention in detail without,
however, limiting the invention thereto.
[Example 1]
[0029] A hand-made paper containing a bleached MP and a bleached CP made from coniferous
wood in a ratio of 1:1 (200 cm
2, basis weight 60 g/m
2) was divided into four portions to prepare samples for laser processing. These samples
were immersed in a 6% aqueous sodium borohydride (w/v) solution and then mounted on
a glass plate. At this point, the impregnation level of sodium boron hydride was 18%
solids by weight on the basis of the weight of pulp solids. The samples were irradiated
with KrF excimer laser at 40 mJ/cm
2/pulse, 5 Hz for 10 minutes. After completion of laser irradiation, the sample was
washed with water and dried in a cylinder dryer. A fading test was performed using
a xenon lamp weather meter. The samples were irradiated with UV light generated from
the xenon lamp for 0.5, 1.0, and 2.0 hours, after which ISO brightness [JIS 8148]
and L*a*b* color difference (delta E*ab) [JIS Z 8701] were determined. The fading
test was performed at a black panel temperature of 63°C, humidity 50%, and an irradiation
intensity of 70 W.
[Example 2]
[0030] The same procedure as in Example 1 was performed except that the irradiation time
of KrF excimer laser was changed to 20 minutes.
[Example 3]
[0031] The same procedure as in Example 1 was performed except that the irradiation time
of KrF excimer laser was changed to 40 minutes.
[Example 4]
[0032] The same procedure as in Example 2 was performed except that XeCl excimer laser was
used in place of KrF excimer laser.
[Comparative example 1]
[0033] The samples for laser processing in Example 1 were immersed in water and then dried
in a cylinder dryer and subjected to the fading test.
[Comparative example 2]
[0034] The same procedure as in Example 2 was performed except that the samples were allowed
to stand for 20 minutes on the glass plate without laser irradiation.
[0035] The results were shown in Figures 1 to 4.
[Example 1]
[0036] A hand-made paper containing a bleached MP and a bleached CP made from coniferous
wood in a ratio of 1:1 (200 cm
2, basis weight 60 g/m
2) was divided into four portions to prepare samples for laser processing. These samples
were immersed in a 6% aqueous sodium borohydride (w/v) solution and then mounted on
a glass plate. At this point, the impregnation level of sodium boron hydride was 18%
solids by weight on the basis of the weight of pulp solids. The samples were irradiated
with KrF excimer laser at 40 mJ/cm
2/pulse, 5 Hz for 10 minutes. After completion of laser irradiation, the sample was
washed with water and dried in a cylinder dryer. A fading test was performed using
a xenon lamp weather meter. The samples were irradiated with UV light generated from
the xenon lamp for 0.5, 1.0, and 2.0 hours, after which ISO brightness [JIS 8148]
and L*a*b* color difference (delta E*ab) [JIS Z 8701] were determined. The fading
test was performed at a black panel temperature of 63°C, humidity 50%, and an irradiation
intensity of 70 W.
[Example 2]
[0037] The same procedure as in Example 1 was performed except that the irradiation time
of KrF excimer laser was changed to 20 minutes.
[Example 3]
[0038] The same procedure as in Example 1 was performed except that the irradiation time
of KrF excimer laser was changed to 40 minutes.
[Example 4]
[0039] The same procedure as in Example 2 was performed except that XeCl excimer laser was
used in place of KrF excimer laser.
[Comparative example 1]
[0040] The samples for laser processing in Example 1 were immersed in water and then dried
in a cylinder dryer and subjected to the fading test.
[Comparative example 2]
[0041] The same procedure as in Example 2 was performed except that the samples were allowed
to stand for 20 minutes on the glass plate without laser irradiation.
[0042] The results were shown in Figures 1 to 4.
[0043] It was shown that when an MP was irradiated with KrF excimer laser, the discoloration
tendency decreased as the irradiation time increased (Figures 1, 3). Especially, the
samples irradiated with the laser for 40 minutes showed very little discoloration
and a significant brightness difference of 16 points compared with blanks after the
fading test for 2 hours. As a result of the comparison between the anti-fading effects
of KrF excimer laser and XeCl excimer laser, very little difference was observed between
them (Figures 2, 4).
ADVANTAGES OF THE INVENTION
[0044] Any type of pulp can be treated rapidly to produce a great and permanent anti-fading
effect as well as other advantages such as environmental friendliness by providing
a novel method for improving discoloration in pulp comprising irradiating a pulp with
UV and/or visible light in the presence of at least one compound selected from the
group consisting of reducing agents, peroxides and hydrogen-donating organic compounds.
Moreover, pulp with greatly improved discoloration obtained by the present method
for improving discoloration can be used as raw materials to produce further benefits
such as quality stabilization of paper products, development of new products, expanded
applications of MP, etc.