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4,450,043 Page
Appleton Papers Inc. Patent
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United States Patent |
4,450,043 |
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Schulz |
May 22,
1984 |
Method for recovering pulp from
pressure-sensitive carbonless copying paper waste
Abstract
A process for recovering pulp from pressure-sensitive carbonless
copying paper waste is disclosed. This process includes defibrating the
waste without substantial rupture of the microcapsules, treating the
defibrated waste with an enzyme for starch saccharification
and separating the fibers from the released microcapsules by means of a
sidehill screen equipped with a washing shower.
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Inventors: |
Schulz; William J. (Cloquet, MN) |
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Assignee: |
Appleton Papers Inc. (Appleton, WI) |
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Appl. No.: |
357400 |
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Filed: |
March 12, 1982 |
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Current U.S. Class: |
162/5;
435/278 |
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Intern'l Class: |
D21C
005/02 |
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Field of Search: |
162/5
435/264,277,278,275 |
References Cited
[Referenced By]
U.S.
Patent Documents
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3652383 |
Mar., 1972 |
deVos |
162/5.
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4356058 |
Oct., 1982 |
Fischer et al. |
162/5.
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Foreign Patent Documents |
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2836156 |
Mar., 1980 |
DE |
435/264.
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50-29042 |
Sep., 1975 |
JP |
162/5.
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Primary Examiner: Smith; William F.
Attorney, Agent or Firm: McKinney; E. Frank, Phillips, Jr.; Paul S.
Claims
What is claimed is:
1. A process for the recovery of fibers from pressure-sensitive carbonless
copying paper waste having color former containing microcapsules,
comprising the steps of:
(a) defibrating the waste in aqueous media in two steps without
substantial rupture of the microcapsules wherein one defibrating step is
performed under acidic conditions and the other step is performed under
basic conditions;
(b) treating the defibrated waste with an enzyme for starch
saccharification; and,
(c) separating the fibers from the non-fibrous components in a sidehill
screen equipped with a washing shower.
2. A process according to claim 1, which further comprises a step in which
bleach is applied.
3. A process according to claim 2, wherein the bleaching step is performed
after the defibration step.
4. A process according to claim 1, wherein the media is adjusted to a pH
of 6.0-7.5 prior to the addition of the enzyme.
5. A process according to claim 1, wherein the microcapsules are produced
by polymerization methods utilizing monomers or initial condensates of
synthetic resins.
6. A process according to claim 5, wherein the microcapsules are produced
by a polymerization reaction between urea and formaldehyde.
7. A process according to claim 1, wherein one defibrating step is
performed at a pH less than about 5 and the other step is performed at a
pH of about 8 or greater.
Description
This invention relates to a method of recovering fibers from waste
pressure-sensitive carbonless copying paper. The method is especially
useful for recovering fiber from waste pressure-sensitive carbonless
copying paper wherein the walls of the microcapsules employed in the paper
were produced by polymerization methods utilizing monomers or initial
condensates of synthetic resins.
This invention comprises the steps of defibrating the waste without
substantial rupture of the microcapsules, treating the defibrated waste
with an enzyme for starch saccharification to break the
adhesive bonds between the microcapsules and the fibers and separating the
fibers from the released microcapsules by means of a sidehill screen
equipped with a washing shower.
Well known in the art are pressure-sensitive mark-forming units and
systems comprising color former components, generally present as a solute
in a liquid solvent which is the core or nucleus material in pressure-rupturable
microcapsules coated on a supporting sheet material and color developer
components distributed in particulate form on a supporting sheet material,
both components being arranged in proximate relation to each other, so
that, upon the application of marking pressure to the microcapsules, the
microcapsules rupture and release the solution of color former, with the
consequent contact of the color developer components producing a mark or
color in those regions where pressure is applied. Such pressure-sensitive
copying papers are described in, for example, U.S. Pat. Nos. 2,712,507;
2,730,456; 2,730,457; 3,455,721; 3,672,935; 4,001,140; 4,087,376;
4,089,802 and 4,100,103.
Conventional waste paper can be defibrated comparatively easily with
various defibrating machines and optionally further threated to yield a
regenerated pulp which can be utilized alone or in admixture with other
furnishes to produce comparatively high quality paper.
When waste paper comprising pressure-sensitive carbonless copying paper is
defibrated, microcapsules can be ruptured during the defibration because
of the grinding action exerted on them. The color former released by such
rupture reacts with the color developer to produce color. The color,
so-produced, results in stained pulp which cannot be subsequently used as
a raw material for high quality paper. Because of this disadvantage, edge
trimmings and damaged paper resulting from the production of
pressure-sensitive carbonless copying paper, together referred to in the
industry as broke or waste, have met with a limited acceptance and
consequent low price in the recycled paper market.
Various techniques have been employed to attempt to overcome these
disadvantages resulting from carbonless copying paper waste. U.S. Pat. No.
3,933,578 discloses a method of recovering fibers from pressure-sensitive
copying paper waste which comprises, in the defibration process, using an
alkaline solution containing a surface active agent. This process results
in rupture of the microcapsules, but color formation between the released
color formers and the color developer is inhibited by the surface active
agent employed. This process finds particular utility for
pressure-sensitive copying paper waste wherein the walls of the
microcapsules employed in the paper were produced by a coacervation
process, such as, for example, a process using gelatin with gum arabic or
carboxymethyl cellulose, or other materials. Such coacervation processes
are described in U.S. Pat. Nos. 2,800,457; 3,041,289 and 3,533,958.
Japanese Patent Disclosure No. 51-23302 describes a method for recovering
pulp from waste paper comprising pressure-sensitive carbonless copying
paper wherein the waste paper is defibrated in the presence of a base and
the resulting pulp is separated, washed at least once and flotation
treated to remove the colored and non-colored undesirable components.
German Patent Disclosure No. 2,642,319 discloses a process for the
regeneration of waste paper comprising microencapsulated components
through the use of a bleaching agent, followed by foam flotation.
U.S. Pat. No. 4,264,412 describes a process for recovering fibers from
pressure-sensitive carbonless copying paper waste wherein the waste is
defibrated in aqueous media, the wastage is treated with acid to destroy
the microcapsules and the resulting mixture is treated with a bleaching
agent.
U.S. Pat. No. 3,910,813 discloses a process for reclaiming both the color
former solution and the paper fibers of pressure-sensitive carbonless
copying paper waste. In this process, the waste paper is shredded,
extracted with a solvent capable of penetrating the microcapsule walls
forming a color-forming-solution/solvent solution, the solution is
separated from the fibers and the solvent is separated from the color
former solution by distillation.
The above-disclosed processes for regeneration of fibers from waste
pressure-sensitive carbonless copying paper result in rupture of the
microcapsules contained therein. The resulting color, formed by contact of
the released color former and the color developer, is either inhibited
through the use of surface active agents or removed by flotation, or the
action of a bleaching agent.
When these prior art pulp recovery processes are applied to
pressure-sensitive carbonless copying paper wherein the walls of the
microcapsules employed in the paper were produced by polymerization
methods utilizing monomers or initial condensates of synthetic resins,
such as those disclosed in U.S. Pat. Nos. 4,001,140; 4,087,376; 4,089,802
and 4,100,103, a large number of the microcapsules go through these
processes intact. The pulp reclaimed from such processes continues to have
unruptured microcapsules adhered thereto. Paper produced subsequently from
such regenerated pulp suffers from the disadvantage of being
pressure-sensitive due to the presence of the intact microcapsules adhered
to the reclaimed fibers comprising the paper furnish. Normal writing or
other pressures rupture these residual microcapsules, releasing the color
former solution contained therein which can react with components of the
paper furnish to produce undesirable color. Thus, even though these prior
art processes can be utilized to regenerate carbonless copy paper waste
which can, in turn, be used to produce a fine paper which appears to be
satisfactory, subsequent application of pressure to such paper, and
subsequent undesirable production of color, reveals the unsatisfactory
nature of such prior art reclaiming processes.
It is an object of the present invention to provide a fiber recovery
process for pressure-sensitive carbonless copying paper waste which relies
upon removal of unruptured microcapsules from the defibrated waste.
It is a further object of the present invention to provide a process for
recovery of fibers which, when re-used in the manufacture of paper, are
not subject to accidental coloration.
It is yet another object of the present invention to provide a fiber
recovery process which has particular utility with pressure-sensitive
carbonless copying paper waste wherein the walls of the microcapsules
employed in the paper were produced by polymerization methods utilizing
monomers or initial condensates of synthetic resins.
The present invention provides a process for the recovery of fibers from
waste pressure-sensitive carbonless copying paper, which comprises
defibrating the waste in aqueous media, adjusting the pH of the mixture to
near neutral, e.g. 6.0-7.5, adding a saccharifying enzyme and washing the
defibrated waste in a sidehill screen equipped with a washing shower to
separate the fibers from the other components of the waste.
The defibration is preferably carried out at temperatures higher than room
temperature, e.g. up to about 150.degree. F., and under pH conditions
which optimize the degradation of the wet strength resins, if any,
existing in the base stock of the copying paper waste. Some of these
resins are degraded only under acidic conditions and others are degraded
only under basic conditions. In order to best accomodate the possibility
that both types of wet strength resins are present, it is best to
defibrate for a period of time under one set of conditions, such as, for
example, acidic conditions in the presence of an acid pulping aid followed
by adjusting the defibrating medium to basic conditions and continuing to
defibrate for a period of time.
If the waste paper being processed is a colored grade, bleach should be
added after the defibration process in order to obtain white recycled
fibers for unrestricted subsequent use.
Following defibration and bleaching, if any, the next step is the
adjustment of the pH to near neutral, e.g. 6.0-7.5, and the addition of an
amylolytic enzyme for saccharification of the starches present. While the
exact mechanism of this step is not known, it is believed that the enzyme
effectively breaks the starch bond adhering the
microcapsules to the fibers. This step, surprisingly, was found to be
required in order to release sufficient microcapsules from the fibers
during the process. Without this step sufficient microcapsules remain
associated with the recovered fibers to render paper, produced
subsequently from such regenerated pulp, of limited value for reasons
previously cited.
Following the addition of the saccharifying enzyme, the fibers are
separated from the microcapsules and other non-fibrous constituents in a
sidehill screen equipped with a washing shower in a multistage arrangement
such as, for example, those disclosed in U.S. Pat. Nos. 3,451,555 and
3,452,876. The product of this separation step is the regenerated fiber
which is suitable for use in papermaking processes.
The following Examples are given merely as illustrative of the present
invention and are not to be considered as limiting. Unless otherwise
noted, the percentages therein and throughout the application are by
weight.
EXAMPLES OF THE INVENTION
The general procedure followed for the recovery process is as follows.
Pressure-sensitive carbonless copying paper waste is defibrated in water
to which has been added an acid repulping aid in a low shear pulper at a
consistency of five to nine percent. Sulfuric acid is added to further
lower the pH to 3.5-4.5 if necessary. A wetting agent is optionally
employed in the aqueous media. Steam is added to the mixture until the
temperature reaches 145.degree.-150.degree. F. After about one hour of
agitation, the pH of the stock is raised to 8-9 with an aqueous sodium
hydroxide solution and the agitation is continued until defibration is
complete. Bleach is added to decolor the basestock dyes, if any, the stock
is diluted, the pH of the stock is adjusted to 6.0-7.5 with sulfuric acid
and the enzyme for starch saccharification is added. The
stock is then fed to a sidehill screen equipped with a washing shower to
separate the fibers from the undesirable non-fibrous constitutents.
Using substantially the procedure described above, several experiments
were performed in which fibers were recovered from pressure-sensitive
carbonless copying paper waste. The measure of success of the recovery
process was the determination of the percent removal of the microcapsules
from the waste. These examples are listed in Table 1.
TABLE 1
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Example 1
Example 2
Example 3
Example 4
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Type Pulp Aid
Pulp Aid
Pulp Aid
Pulp Aid
Pulping Aid 101 101 101 101
Amount
1% 1% 1% 1%
pH during acid 4.5 4.5 4.2 4.0
defibration
Temperature 150.degree. F.
150.degree. F.
150.degree. F.
150.degree. F.
pH during basic
8.5 8.5 8.5 8.0
defibration
Type -- Solvox KS
Solvox KS
Solvox KS
Bleach
Amount
-- 1% 1% 1%
pH after defibration
7.0 7.5 7.0 7.0
Type Vanzyme FE
Vanzyme FE
Vanzyme FE
Vanzyme FE
Enzyme
Amount
50 gm/ton
50 gm/ton
50 gm/ton
50 gm/ton
Type of Capsule
3,041,289
3,041,289
4,001,140
4,001,140
(Pat. Ref.)
% Capsule Removal
90% 90% 94% 89%
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Pulp Aid 101 is an acidic water soluble ester material supplied by Laurel
Products Corp., 2600 East Tioga St., Philadelphia, PA.
Solvox KS is calcium hypochlorite supplied by Solvox Mfg. Co., 11725 W.
Fairview Avenue, Milwaukee, Wis.
Vanzyme FE is an enzyme for starch saccharification supplied
by R. T. Vanderbilt Co., Inc., New York, N.Y.
EXAMPLE 5
This example of a fiber recovery process, performed on pressure-sensitive
carbonless copying paper waste comprising capsules made according to U.S.
Pat. No. 3,041,289, was performed in the same equipment as examples 1-4
except that no chemicals were added except Vanzyme FE at the rate of 50 gm
per ton. The percent capsule removal in this case was 83%.
Examples 1-5 show a degree of removal of microcapsules which enables the
subsequent manufacture of a completely satisfactory paper furnish from the
recovered fibers.
The invention being thus described, it will be obvious that the same may
be varied in many ways. Such variations are not to be regarded as a
departure from the spirit and scope of the invention and all such
modifications are intended to be included within the scope of the
following claims.
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