Title of Invention

ARUNDO DONAX PULP, METHOD OF FORMING THE SAME, PAPER PRODUCT AND COMPOSITE PANEL FROM ARUNDO DONAX, AND METHOD OF FORMING THE SAME

Abstract Composite panels and pulp, and paper products of the pulp, are produced from Arundo donax. In the fabrication of the composite panels, Arundo donax is comminuted (20) to a suitable size, combined with a binder (40, 50), and consolidated (80) into panels that meet standards for construction and/or furniture grade panels. The Arundo donax particulates may be combined with wood particulates to produce a mixed furnish that can be used in the preparation of composite panels. Comminuted Arundo donax is treated, in conventional pulping processes, to produce a high tensile strength pulp that can be used in the production of paper. The pulp has a lighter color than wood pulp, and thereby uses less bleaching chemicals to achieve a desired whiteness. The pulp can be combined with wood pulp to produce a variety of products.
Full Text "ARUNDO DONAX PULP, METHOD OF FORMING THE
,SAME, PAPER PRODUCT AND COMPOSITE PANEL FROM
ARUNDO DONAX, AND METHOD OF FORMING THE SAME"
The invention relates to arundo donax pulp, method of forming the same, paper
product and composite panel from arundo donax, and method of forming the same.
Arundo donax is a type of grass.
Background of the Invention
There are several well-known technologies for producing particle board, using
wood chips and other wood processing waste products. Indeed, these wood-based
composite boards have found wide application particularly in building construction and
the manufacture of furniture. More recently, the industry has produced oriented strand
board (OSB) as a useful construction material. Both particle board and OSB fall into the
category of "composites" because both contain a filler (wood fiber) embedded within a
binder matrix. Another well-known wood composite is "MDF" (medium density fiber
board). Other well known composite products are made with wood or other fibers using
inorganic binders, such as cement, to make construction and decorative products.
The popularity of wood-based composites is based in large part on the availability
of relatively low cost wood byproducts (chips, sawdust, etc.) that can be used in the
composites. Indeed, many of the industry standards for the physical performance of these
composites are based on wood-based composites. Since the manufacturing parameters
for wood-based composites are well-known, and can often be customized for certain
applications, there has been little incentive to investigate other fillers.
With the increasing demand for paper prepared from wood pulp, as well as
worldwide demand for wood-based composites (which can substitute for lumber), there is
now a perceived growing need for a substitute raw material for wood. While the supply
of wood for use in these products is "renewable," it requires setting aside land for long
periods of time for tree fanning. Moreover, when demand outstrips supply, because
supply is based on forecasts of decades before when trees were planted, then a shortage
inevitably develops. Since the wood required for these uses results in cutting millions of
acres of forest each year, such shortages lead to serious worldwide concerns about large
scale deforestation and its contribution to global warming.
There is yet a need for a material that can be readily substituted for wood in
wood-based composites, and that can also be used to produce paper pulp for the
fabrication of paper products. Extensive research had been conducted and production
trials have been made in an effort to find a suitable non-wood fiber for composites and
pulp but, until now, this work has met with very little success due to inferior properties,
excessive costs and many commercial production drawbacks.
Summary of the Invention
In one aspect of the invention, Arundo donax particles are provided. The
particles, including chips and flakes, can be advantageously formed into pulp from which
paper and paper products can be made. The particles can also be used in the production
of particle boards.
In another aspect, the invention provides composites that include a binder matrix
filled with Arundo donax particulates. In accordance with the invention, these composite
boards use significantly less binder than wood-based composites, and exceed several of
the physical properties of comparable wood-based composites, as measured by standards
used in the industry.
The composites of the invention are produced by selecting nalgrass (a common
name for Arundo donax), which is widely distributed as a native wild grass in many parts
of the world. The nalgrass is charged to a flaker which contains sharp internal knife
edges to reduce the nalgrass to small shards (e.g., flakes), which can then be charged to a
hammermill for further size reduction. The resulting material is called a "furnish." The
hammermill furnish is sized, preferably into at least two fractions. Each of the two
fractions of nalgrass particulates is separately combined with a proportion of a resin. A
layered structure, having alternate layers of fine and coarse nalgrass-resin mixture is then
produced. The layered structure is subjected to heat and pressure for consolidation into a
composite product. Satisfactory products may be made with a single layer, two layers, or
more. Many commercial operations blend a variety of wood sources, such as hardwoods,
softwoods, and recycled wood waste, in the manufacture of composites. Those skilled in
the field will seek the advantages of nalgrass by blending into their furnish a portion of
nalgrass with their available wood sources.
The invention also provides paper pulp, and paper products made from nalgrass.
The raw pulp produced from the nalgrass is of lighter color than the pulp produced from
woods that are typically used in paper production. Accordingly, a smaller amount of
chemical bleach must be added to bleach the pulp to a desired whiteness. Nalgrass pulp
is also stronger than most common hardwoods, such as aspen. The pulp of the present
invention can also be utilized in other cellulose-based products including building
products and modified cellulosic fibers such as viscose (e.g., rayon).
Brief Description of the Accompanying Drawings
The foregoing aspects and many of the attendant advantages of this invention will
become more readily appreciated as the same become better understood by reference to
the following detailed description, when taken in conjunction with the accompanying
drawings, wherein:
FIGURE 1 is an illustration of representative nalgrass particles of the invention;
FIGURE 2 is a plan view of a representative device for forming nalgrass chips in
accordance with the present invention;
FIGURE 3 is an elevation view of a representative device for forming nalgrass
chips in accordance with the present invention;
FIGURE 4 is a detail section of a blade arrangement for a representative device
for forming nalgrass chips in accordance with the present invention;
FIGURE 5 is a schematic flow diagram showing steps in a representative process
for producing the nalgrass composites of the invention;
FIGURE 6 is a representative nalgrass composite panel prepared in accordance
with the invention;
FIGURE 7 is an illustration comparing production from kenaf, hardwood, and
Arundo donax harvests; and
FIGURE 8 is a schematic flow diagram showing steps in representative processes
for producing nalgrass pulp in accordance with the present invention.
Detailed Description of the Preferred Embodiment
The composites of the invention utilize a raw material that is abundant, but that
has been regarded as a weed, unsuitable for any use other than stabilizing soil on slopes,
windbreaks, and the manufacture of woodwind instruments. The raw material is of the
genus Arundo of the family Gramineae, tribe Festuccae. It includes about six species, of
which Arundo donax L. is the most widely distributed and the best known. Arundo
donax, also known as "nalgrass," is native to the countries surrounding the Mediterranean
Sea. The terms "nalgrass" and "Arundo donax" are used interchangeably herein.
Nalgrass is a tall, erect, perennial grass and at maturity reaches 7-28 feet in
height. In optimum climate, it grows at a rate of six inches per day during most of the
year and can reach maturity in one to one and a half years. In infertile soils, yields are in
the range of 8 tons dry nalgrass material per acre. Test cutting in southern California
resulted in yields of more than 30 tons dry nalgrass material per acre. It is estimated that
the sustainable yield of dry fiber from 50,000 acres of nalgrass is the equivalent of
1,250,000 acres of tree wood fiber. It is one of the largest of the herbaceous grasses.
Unlike bamboo, kenaf, and other grasses, the stalks are hollow, with walls 2 to 7 mm.
thick and divided by partitions at the nodes. The nodes vary in length from
approximately 12 to 30 cm. The outer tissue of the stem is of a siliceous nature, very
hard and brittle with a smooth, glossy surface that turns pale golden yellow when fully
mature.
The vascular bundles of nalgrass are distributed freely throughout the cross-
sectional area of its fundamental parenchyma. Those toward the periphery of the stem
are smaller and more numerous than those toward the interior. These bundles are
collateral and are surrounded by one or more rows of thick-walled, strongly lignified
fibers. Toward the periphery of the stem, as the size of the bundles decreases, the
number of rows of fibers associated with the bundles are small and comparatively close
together, the fibers are sufficiently abundant to form a continuous ring of structural tissue
within which are scattered the vascular elements. This structural ring is separated from a
wax-covered single cell epidermal layer by a narrow band of parenchyma cells that in
mature stems are comparatively small, thick-walled, and lignified. The vascular bundles,
including the associated fibers interior to the structural fibrous ring, occupy
approximately 24% of the stem. The vascular tissue and associated fibers that compose
the structural ring make up approximately 33% of the total cross-sectional area. Thus,
parenchymatous tissue occupies but 43% of the cross-sectional area of the stem.
Both leaves and stems of nalgrass, particularly the former, contain numerous
highly silicified cells. These cells, associated with the vascular bundles, are also located in
the epidermal tissue. Their presence explains the elevated silica count that has been
indicated by chemical analyses
The equipment necessary for manufacturing the composites of the invention are
commercially available, and may have to be modified to optimize production.
Nevertheless, commercially available equipment can readily be used in the process.
In one aspect the present invention provides an Arundo donax particle. The
particle is either a chip or a flake and can be used either in the formation of pulp, paper
products derived from the pulp, or incorporated into composite panels.
The chip is formed from an Arundo donax stem by cutting the stem across its
length to provide a ring having a substantially circular cross section in a length from
about 1/8 inch to about 3 inches. Breaking the ring's circular cross section provides the
chip. Typically, when the ring is broken two to five chips are formed. Referring to
FIGURE 1, Arundo donax's stem 1 provides ring 2 from which chips 3 are formed. A
representative device and method for forming Arundo donax's chips is described in
Example 1. Preferably, the ring has a length from about ½ to about 1½ inches and is
formed by cutting the stem either by a saw cut, a knife blade or a veneer cut.
In addition to chips, suitable Arundo donax particles include flakes. The flakes
are formed from flaking an Arundo donax stem in any one of a number of conventional
flakers. Preferably, the flake (i.e., shard, sliver) has a length from about two inches to
about four inches and preferably from about 2½ to about 3½ inches. Flake thickness can
vary greatly from about 1/32 of an inch to about 1/8 of an inch. Referring to FIGURE 1,
flaking stem 1 provides flake 4. Suitable flakes can be prepared from conventional
equipment including ring, drum, and disc flakers and chippers. Preferably, flakes are
formed using a drum flaker.
As discussed below, Arundo donax particles (e.g., flakes and chips) can be
advantageously used in the production of composite panels, pulp, and paper products.
Chips can be advantageously used in the formation of pulp including continuous or batch
pulping processes. Arundo donax flakes can also be pulped, preferably by batch digestion
processes. In kraft pulping the flakes and/or chips are directly digested. In CTMP
(alkaline peroxide) pulping, the flakes and/or chips can be reduced in size prior to
digestion. For composite panel (e.g., particle board) formation, the flakes and/or chips
are typically reduced in size by hammermilling to provide a furnish which is then mixed
with a binder such as a resinous binder and then consolidated into a panel.
A representative method for forming a composite panel is illustrated in FIGURE
5. Referring to FIGURE 5, in a first step clean nalgrass is charged to a flaker or
chipper 10 which contains internal sharp edges for cutting the nalgrass to a reduced size.
Typically, a size distribution of nalgrass is obtained from the flaker. Preferably, nalgrass
particulates having a length of about one inch, and up to about four inches, are produced
by the flaker, if the resultant furnish is to be used to manufacture composites. If the
particulates are to be used to manufacture paper pulp, then it is preferred that they be
smaller, typically in the range one-half inch to about 1½ inches in length.
The nalgrass particulates are then charged to a hammermill 20 for further
comminution. It should be understood that other apparatus commonly used for
comminution of cellulosic materials may also be used, and that the invention is not limited
to the use of flakers, chippers, and hammermills. The hammermill further reduces the size
of the nalgrass particulates and produces a size distribution of the furnish.
The particulates from the hammermill are then preferably charged to a series of
mesh sieves 30 for sizing. Preferably, the sieves are arranged to produce at least three
cuts or size distributions of nalgrass particulates. Thus, it is preferred to use a first sieve
of 48 mesh size to remove undersized nalgrass "dust." Thereafter, the oversized
particulates are charged to a second sieve of mesh size 14. This sieve produces an
undersize and an oversize. Material that does not pass through a 4 mesh (over one-
quarter inch) is removed and reworked.
The undersized material is finer and is used to make the "face" layers 100 of the
composites shown in FIGURE 6. The oversize material, which is relatively coarser, is
used for the core layer 120 or layers of the composite. Typically, a composite comprises
three layers: a central core covered on each side by a face layer. However, additional
layers can also be added, depending upon customer requirements, physical property
requirements, and other factors.
The undersize or "face nalgrass particulates" are mixed with a resin 40 to form a
"face material mixture" of resin-coated particulates. Separately, the core material is also
mixed with the resin to form a "core material mixture."
While any of the organic resins and inorganic binders conventionally used in the
manufacture of wood products may also be used to make nalgrass composites, the
preferred resin is methyl diisocyanate ("MDI"). It has been found that MDI resin results
in the production of composites having superior properties. Without being bound, it is
theorized that the nalgrass-MDI resin combination may produce these enhanced physical
properties due to a combination of any of the listed physical properties of nalgrass in
combination with moieties of the MDI resin molecule: high melting point waxes present
in the nalgrass, elevated silica content of the nalgrass, high-alpha cellulose content of the
nalgrass, and low lignin content of the nalgrass.
Regardless of theory, it has also been found that the manufacture of nalgrass
composites requires a lower proportion of resin additive, than would be required with a
wood-based composite of a similar physical dimensions and strength. Indeed, nalgrass
composites of the invention may be prepared with as little as 1.5 weight percent MDI.
Typically, the resin proportion may range from about 1.5 to about 5 weight percent MDI
depending upon the composite physical properties required. More than 5 weight percent
MDI may also be used but there appears to be of little commercial advantage to produce
such composites. Generally, the higher the proportion of resin added, the stronger the
composite. Preferably, the nalgrass-resin mixture contains from about 1.5 to about
3.5 weight percent MDI, and most preferably from about 2.5 to about 3.0 weight percent
MDI. Clearly, when a resin other than MDI is used, a different resin proportion may be
found optimal, depending upon the physical properties required of the composite.
After the nalgrass-resin mixtures have been prepared, they are conveyed to "mat
forming" 60. In this process, the face material mixture is first laid down in a layer. This
is followed by a layer of core material mixture, which is covered by a final layer of face
mixture, to form a three-layer sandwich. More or less layers can also be used depending
upon the desired properties of the resultant composite.
The layered mat is prepressed 70 under ambient conditions to reduce its volume,
by allowing limited movement of particulates to fill in interstitial and void spaces. The
prepressed layered structure is then pressed, in a conventional press used for the
production of wood-based composites, and subjected to sufficient heat and pressure to
consolidate the panel 80. When MDI resin is used, the press is typically operated at a
temperature in the range of 160-170°C (320-340°F), and under pressure of between 500-
600 psi (maximum) during the closing cycle and about 100 psi during the curing cycle.
During pressing, some of the mixture may spread outward, resulting in a relatively
uneven edge to the consolidated composite. The panel edges are trimmed, and the board
is cut to size to produce a composite board of standard size. The formation of
representative nalgrass particle boards and their properties as well as wheatstraw-based
particle boards and southern pine-based particle boards is described in Example 2.
As noted above, the nalgrass furnish may be mixed with proportions of wood
furnish to prepare composites in accordance with the invention. Preferably, the nalgrass
forms the major proportion of the furnish due to its lower cost. The formation of
representative nalgrass/southern pine particle boards and their properties are described in
Example 3. The mechanical and physical properties of the nalgrass/southern pine blend
particle boards are compared to particle boards formed from (1) nalgrass and
(2) southern pine in that example.
The Arundo donax composite panel includes a binder matrix and Arundo donax
particles (e.g., chips, flakes, and chips and flakes having reduced size) distributed
throughout the binder matrix. Referring to Tables 1 and 2, the composite panels of the
present invention meet at least the M-3 standard for composite panels.
The panels include from about 1% to about 10% by weight of a resin binder based
on the total weight of the panel. However, to achieve the advantageous properties
associated with wood panels, the presence of Arundo donax in the composite panels of
the present invention permits a much lower amount of binder. Accordingly, the panels
preferably include from about 1.5% to about 3.0% by weight of resin binder based on the
total weight of the panel. Conventional binders known in the formation of composite
panels can be used to provide the panels of the invention. Preferred binders include
methyl diisocyanate, urea-formaldehyde, and phenolic binders.
The panels of the present invention can further include other fibers including
wood fibers. Preferably, the panels of the invention that include a blend of fibers have
from about 10% to about 90% by weight Arundo donax particles based on the total
weight of the panel.
Generally, the bending strength and moisture resistance of the panels of the
invention are increased proportionally relative to the amount of Arundo donax present in
the panel compared to conventional wood-based panels. Generally, the bending strength
of the panel is about 55% greater than a similar constituted wood-based panel, and about
5% greater than a similarly constituted wheatstraw-based panel. The moisture resistance
of the panel is about 2.6 times greater than a similarly constituted wood-based panel and
about 15% greater than a similarly constituted wheatstraw-based panel.
A representative method for manufacturing an Arundo donax composite panel
includes the steps of (1) comminuting Arundo donax into particles of a size distribution
suitable for use as a furnish in a composite panel; (2) mixing those particles with a binder
(e.g., resin) to provide a binder-particle mixture; and (3) consolidating the binder-particle
mixture into a composite panel. In the process, the Arundo donax particles are bonded
into a contiguous material with the resin. As noted above, the particle-binder mixture can
further include other materials such as, for example, wood particles and fibers.
As described above, Arundo donax can be advantageously incorporated into
particle board. Similar advantages can be obtained through the incorporation of Arundo
donax in oriented strand board (OSB) and medium density fiberboard (MDF). Arundo
donax can be incorporated as the sole particular component or as a component in a
particle blend.
In another aspect of the invention, nalgrass is utilized as a raw material for the
preparation of pulp and paper products produced from this pulp. Arundo donax pulp
comprises fibers obtained from the treatment of Arundo donax particles (e.g., chips and
flakes). Depending upon the pulp, in addition to treatment, the particles can also be
subject to comminution. Comminution can be performed by a number of devices
including, for example, a hammermill or a rotary disc refiner.
As discussed below, the pulp can be formed from a number of different treatments
including, for example, kraft pulping, soda pulping, alkaline peroxide mechanical pulping
(CTMP), sulfite, and other pulping processes known in theart. The pulping process can
also include bleaching. In a preferred process, the bleaching step includes Elemental
Chlorine-Free bleaching.
The Arundo donax pulp of the present invention has a freeness in a range from
about 150-750 CSF and has a brightness of at least about 55% ISO, and preferably at
t about 75% ISO.
The pulp forming methods of the invention provide a pulp yield of about 50%.
The yield is comparable to that of hardwood yields and significantly greater than that
obtained from kenaf. The yields obtained from Arundo donax, hardwood, and kenaf are
illustrated in FIGURE 7. Referring to FIGURE 7, the initial yields of usable kenaf,
hardwood, and Arundo donax are about 50 pounds/100 pounds, about 88 pounds/100
pounds, and about 99 pounds/100 pounds, respectively. For kenaf, separation of the pith
greatly reduces the usable amount of fiber. For hardwood, debarking provides a
relatively high amount of fiber for further processing. Arundo donax initial processing
removes only the leaves from the stem, which are unusable, leaving the majority of the
Arundo donax (i.e., about 99%) usable for further processing. Following initial
processing, the kenaf, hardwood and Arundo fibers are then digested with a typical yield
being about 50%. As illustrated in FIGURE 7, the power (steam requirement, BTU/ton)
and chemical requirements (lbs/ton) for pulping Arundo donax is significantly less than
for pulping of either kenaf or hardwood fibers. The power requirement for Arundo
donax pulping is approximately 88% that of kenaf and about 73% of hardwood digestion.
Furthermore, Arundo donax pulping requires about 83% of the amount of the chemicals
needed to convert the raw fibers to usable pulp. The overall pulp yields for kenaf,
hardwood, and Arundo donax are about 28%, 44%, and 50%, respectively. Thus, the
use of Arundo donax in the formation of pulp and subsequent paper products, offers
significant economic advantages through lower energy and chemical requirements
compared to hardwood and other non-wood materials. As illustrated in the examples, the
characteristics of Arundo donax pulp, paper products, and particle boards is generally
comparable or superior to wood-based and nonwood-based counterparts.
The pulp has a better tear and tensile, strength than aspen pulp. This is an
important property affecting paper production efficiency. Also, the nalgrass furnish uses
less chemical and energy to produce pulp.
The bulk density of nalgrass chips is somewhat higher than that of typical wood
chins. Accordingly, digester loading would be proportionately higher for nalgrass chips
than for wood chips. This is an important consideration for those paper and pulp
manufacturers that are limited in capacity due to digester through-put limitations.
In contrast to wood chips, which require a moisture content of about 50 percent
for efficient pulping, nalgrass particles having significantly lower moisture content, less
than about 10 percent, can be directly and readily digested.
The nalgrass chips or particulates are readily susceptible to digestion, and cook
very readily as compared to wood under kraft conditions for wood. The yield of
unbleached pulp is of the order of 48.5%, which at the upper end of the range for
bleachable kraft pulps, with the possible exception of aspen (which produces yields in the
range 55 to 58%). Importantly, the pulp of nalgrass has a lighter color than typically
obtained from hardwood. Accordingly, a lower amount of bleaching chemicals is added
to produce the same resultant treated brightness. The brown stock produced from
nalgrass is very easily bleached with a DEDED sequence to 89.9% ISO brightness at a
93.9% yield. The brown stock can also be readily bleached by the Elemental Chlorine
Free (ECF) method, a three-stage method, as described in Example 4 and FIGURE 8. In
a representative ECF process, pulp brightness of about 85% ISO was obtained.
The weighted average fiber length of nalgrass pulp is about 0.97 millimeter, and
the coarseness is of the order of 0.13 milligram per meter. Both of these values are
somewhat higher than obtained from aspen pulp.
Nalgrass pulp may be used to prepare paper, such as wood-free uncoated papers,
and may also be blended with wood pulps to produce other products. Nalgrass wood
pulp is also suitable for the production of corrugating medium. Nalgrass furnish may be
blended with wood furnish to produce a mixed pulp product suitable for many uses.
In another aspect of the present invention, methods for forming Arundo donax
pulp are provided. In these methods, Arundo donax particles such as chips and flakes are
pulped.
In one method, Arundo donax pulp is formed by selecting a furnish that includes
Arundo donax particles and subjecting the furnish to a pulping process to produce a
brown stock of pulp having a yield of about 48% by weight based on the furnish.
Generally, the pulping time for the method, which achieves a 48% yield and a kappa
value of about 15, is about 25% less than required for pulping hardwood to achieve the
same yield and kappa value.
In another embodiment, the present invention provides a method for forming an
Arundo donax pulp that includes the steps of: (1) selecting a furnish that includes
Arundo donax particles; (2) subjecting the furnish to a pulping process to produce a
brown stock of pulp having a yield of about 48% by weight based on the furnish; and
(3) bleaching the brown stock to a brightness of from about 55% to about 90% ISO. In
the method, bleaching the brown stock to a brightness of about 90% ISO requires about
25% less bleach than required for bleaching hardwood to about the same brightness.
In another embodiment of the method of the invention, Arundo donax pulp is
formed by: (1) subjecting Arundo donax particles to a bleaching chemical to provide a
bleached furnish; and (2) mechanically refining the bleach pulp furnish to provide a pulp
stock having a brightness of from about 55% to 90% ISO. The bleaching chemicals can
be any one of a variety of bleaching chemicals known to those in the pulping art.
Preferred bleaching chemicals include a mixture of hydrogen peroxide, sodium hydroxide,
and sodium silicate (alkaline peroxide pulping). Alternatively, the bleaching chemical can
include chlorine dioxide.
A flow chart illustrating two representative pulping processes is shown in
FIGURE 8. Referring to FIGURE 8, kraft pulping and bleaching and chemimechanical
pulping (alkaline peroxide) processes are illustrated. Briefly, in these processes nalgrass
stems are processed to form nalgrass particles (e.g., chips and/or flakes). For kraft
pulping and bleaching, the nalgrass particles are digested in a cooking liquor. The
digested material is then washed and the waste liquor recycled into the cooking liquor for
continuous processing. The result of digestion is a pulp product that is then bleached.
As illustrated in FIGURE 8, bleaching can include the steps of a first chlorine dioxide
bleaching step followed by an extraction step which is then followed by a second chlorine
dioxide bleaching step. Following bleaching, the pulp is then washed and either directed
to a paper machine for paper formation or pressed and dried for shipping to market. The
pressed and dried pulp is referred to as market pulp.
For chemimechanical pulping, the nalgrass particles are impregnated with
chemical (an alkaline peroxide mixture of hydrogen peroxide, sodium hydroxide, and
sodium silicate). Following chemical impregnation, the resulting treated pulp is
mechanically refined and then washed. After washing the pulp can either be directed to a
paper machine or dried and baled and shipped to market.
In another aspect of the present invention, Arundo donax paper products are
provided. The paper products include Arundo donax pulp. The incorporation of Arundo
donax pulp into the paper products provides advantageous brightness as well as strength
(i.e., burst, tear, and tensile). The utilizing of Arundo donax in the production of paper,
its pulping behavior and pulping properties are described in Example 4. In Example 4,
data from kraft pulping, soda pulping, and alkaline peroxide mechanical pulping is
presented. The results for Arundo donax are compared to those obtained for wheatstraw
and wood.
The Arundo donax paper products are generally formed by a method that includes
the steps of: (1) forming an Arundo donax furnish that includes fibers and an aqueous
dispersion medium (e.g., water); (2) depositing the furnish onto a foraminous support
(e.g., a forming wire); (3) dewatering the deposited furnish to provide a fibrous web; and
(4) drying the web to provide a paper product.
The Arundo donax paper products of the present invention can further include
other materials and can include a pulp blend, such as a blend of Arundo donax and
softwood and/or hardwood pulp. Accordingly, in the method described above, the
Arundo donax furnish can further include wood fibers.
The advantageous properties of Arundo donax can be obtained by incorporating
from about 5% to about 85% by weight Arundo donax pulp in the paper product.
Generally, the paper product of the present invention has a brightness of at least about
82% ISO, a burst index of at least about 3.0, a tear index of at least about 8.5, and a
tensile index of at least about 50. Depending upon the characteristics of the pulp, the
paper products of the present invention include high brightness printing and writing grade
paper, news print and publication printing grade, and unbleached liner and corrugation
boards.
The following examples are provided for the purposes of illustration and not
limitation.
Examples
Example 1
Equipment. Processes, and Methods for Nalgrass Size Reduction
In this example, cutting or macerating nalgrass, more specifically cutting nalgrass
into particles that are suitable for processing into digested pulp or for efficient processing
into composite panels and/or engineered wood products, is described.
Fairly sophisticated processing equipment has been developed over many years,
by the forest and wood products industries, for size reduction of logs, sawmill shavings,
waste lumber, etc. The equipment and handling methods have been designed to produce
particles of specific geometry for use in modern digesters for the manufacture of pulp and
in milling equipment for wood composites, namely, particleboard, oriented strand board
(OSB), and medium density fiberboard (MDF). During the development work, several
types and models of wood chippers and flakers were tested. The resulting particles were
satisfactory for laboratory and pilot scale work but it quickly became evident that such
particle geometry was less satisfactory for commercial application.
Generally, the conventional equipment, ring, drum, and disc flakers and chippers,
and various tub and agricultural and "roadside/yard" grinders, produced many long flakes,
shards, and slivers. The action of these machines tend to pull the hollow nalgrass stems
into the blades and shred the long fibers as if peeling layers. Long shards and slivers tend
to blind screens and conveyors generally used in pulp digesters and handling equipment
used in composite panel plants.
Enough material was screened and recovered during the trials to conduct the
scientific work, but it was clear that more work was needed to efficiently reduce nalgrass
size for commercial processes. Further investigation has shown that conventional
equipment used for wood may not produce satisfactory particle geometry for modern
continuous pulp digesters nor for many composite panel processing plants. The desired
particle geometry is a chip of ¾ to 1 inch long by ¼ to ¾ inch wide by approximately
3/16 inch thick. (Note: these dimensions apply broadly to most commercial operating
mills but could vary somewhat for certain operations.) Further, certain pulping
equipment and processes, used principally outside the United States, can utilize a wider
range of particle geometry.
One representative device and method for preparing desired particle geometry for
nalgrass is shown in FIGURES 2-4. This same concept may be applied to upgrading
agricultural straws and prunings, roadside and yard clean-up, etc.
The usable stem portion of nalgrass grows from 15 to 20 feet to maturity in 12 to
18 months depending on weather and soil conditions. The stems are harvested by cutting
with a blade just above the ground line and the top section, containing leaves and small
stems, is removed by a blade cutter in the field. The resulting stems, which are essentially
hollow, range from about ½ inch to ¼ inches diameter with wail thickness ranging from
just over 1/16 inch to roughly ¼ inch. The concept is based on sawing the stems into
"rings" of ¾ to 1 inch length then, "chopping" the rings into three to five pieces. Simple
calculations show that the resulting pieces would meet the optimum size specifications for
commercial pulping and composite panel processes.
FIGURE 2 is a plane view and FIGURE 3 an elevation of a saw blade bed 5½ feet
wide with saw blades mounted on a shaft and spaced 1 inch apart. This width was
selected for illustration purposes because automatic saws used in composite panel and
wood products plants range from 4 to 8 feet in width to cut panels into sections for
various products. However, it would be possible to have a much more narrow or wide
saw bed depending on economic factors of construction cost and capacity requirements.
FIGURE 4 is a detail section of the blade and finger arrangement. This illustration shows
a circular saw configuration however, a band saw principle can be employed.
Blade spacing of 1 inch is also used for illustration since spacing of ¾ to
1½ inches more or less is possible depending on the desired application. Nalgrass stems
are pre-cut to approximately 4 to 5 feet lengths and aligned and fed into the hopper which
is mounted above the apron that feeds the saw blade arrangement. Fingers mounted on a
chain, belt; or other carrier mechanism are driven through a slot in the belt that feeds into
the saw blades. These fingers pull the nalgrass stems that feed by gravity or by a positive
teed mechanism, (the stems are not completely straight and a positive feed to clear the
hopper discharge into the fingers can be used) from the hopper onto the apion into and
through the saw blades resulting in rings of nalgrass discharging to a chute that then
flows into the chopping mechanism. The width of the fingers for a 1 inch saw blade can
be ½ to ¾ inch in order to supply the positive force to gently pull the stems through the
blades.
The "chopper" may be one of several possible designs. The representative design
shown is of a type with blades mounted on a shaft that can rotate at a single or variable
speed. As rings fail into the housing around the blades, they are chopped by the action of
the blade impinging on or near the wall. An alternate design uses hammers instead of
blades or even a drum with blades and an annular space whereby chunks are pulled from
the nalgrass rings. The optimal design produces the fewest small slivers or shards.
After the chopper, a screen removes the oversize (intact or nearly intact rings) for
return to the chopper and the undersize slivers and shards are removed by screening. The
main stream is conveyed to a holding bin to be loaded into trucks or railcars.
Variations of this basic process are possible. The saw blades may be oscillating if
a more positive cutting action is needed. The saw blades may have many or very few or
no teeth. Another design, as noted earlier, may use a band saw principle rather than a
circular one. The bands would have an up and down motion as the stems are pulled
through. Nonetheless, the method involving cutting rings to optimum length then
reducing the rings to desired particles is the same in all versions.
A key to many of the design features is the capacity of the system. For general
efficiency and adequate customer service to large processing plants, a system in the field
would need to produce a minimum of 10 tons/hour up to 30 or more tons/hour and
operate effectively 16 hours/day and 6 or 7 days per week, 50 to 52 weeks per year.
Tons in this reference are short tons, 2000 lbs., and as "green" tons. In the industry,
tonnage frequently means "bone dry tons". Based on the bulk density of the stems, some
rough estimated calculations and sketches show that each if each finger "pulled" a small
bundle about 10 inches in diameter, roughly 6 to 7 pounds, the fingers would need to
pass the blades (about 30 inches in diameter) at a rate of just over one per second to
process 10 to 12 tons per hour. Relating that speed to similar types of processes
conceptually seems that a speed of 2 to 3 seconds would be needed to accomplish the
sawing of a bundle that size. Band saw blades of 30 to 40 inch length could possibly saw
bundles up to 15 inches in diameter and that design could process 10 to 12 tons per hour.
Larger bundles being pulled through may begin to crush the stems before they can be cut
into the desired ring shape.
Example 2
The Formation of Representative Nalgrass Particle Boards
The protocol for manufacturing particle board of nalgrass, and of comparison
materials, is described in this example.
Preparing the Furnish (Particles). Arundo donax stalks were chipped into pieces
of approximately 2 to 3 in. long x 1/4 to 3/8 in. wide x 0.03 in. thick in a Pallmann Drum
Flaker, dried to 8% moisture, and then processed in a Prater Blue Streak hammermill
with a 1/8 in. screen. Material from the mill was screened resulting in 32% through the
screen to be used for face material and 68% on the screen to be used for core material.
For wood (southern pine) composite preparation, commercially obtained face and
core material was used. The commercial face material was coarser than that used for
nalgrass and wheatstraw so a portion of the wood face material was screened, using the
same mesh screen as used for nalgrass.
For wheatstraw, the straw was processed through the Prater Blue Streak
hammermill with a 1/8 in. screen. Material from the mill was screened in the same
manner as nalgrass with 24% through the screen to be used for face material and 76% on
the screen to be used for core material.
All prepared test materials were processed as follows. Each test had three
replications at low (2%), medium (4%), and high (6%) resin content; and low and high
density. A total of 18 test panels was used for each material. See Table 1.
Resin/Binder addition. Core material and face material portions were weighed
out and individually put into a laboratory blender designed to duplicate production
conditions. For each portion, the methyl diisocyanate resin, generally referred to as MDI,
was weighed to achieve the target percentage and put into a reservoir that feeds into
nozzled spray apparatus. The nozzles were positioned in the blending chamber and
sprayed for 60 to 180 seconds while the blender was operating. The blender was stopped
and the resin-coated material removed. In all tests, resin content of the face and core
materials was the same.
Mat Forming. Two small portions of face material and one of core material were
weighed out for each mat to be pressed into a 3-layer test panel. A Teflon® sheet, to
ease test panel release after pressing, was placed on a steel sheet, and a rectangular
wooden frame placed on the Teflon® sheet. The frame measured 16 in. x 20 in., (the
target size of the finished test panel) and was 6 in. high. Face material was distributed
uniformly inside the frame to form the lower face, then the core material was distributed
uniformly over the face layer. Finally, the remaining portion of face material was
distributed uniformly as a top layer. The mat formed by the layers was tamped down, the
frame removed, and a Teflon® release sheet placed on top of the mat.
Panel Forming. The mat was placed on the lower platen of a Siempelkamp pilot
model press. The platen dimensions of the press were 23 in. x 31 in. and it was driven by
a 200 ton servohydraulic system. A three-stage press schedule was preset on a computer
to compress to 0.75 in. in 60 seconds, to remain at that thickness for an additional
400 seconds, and then to vent for 20 seconds for a total press time of 480 seconds
Platen temperature was 330°F. At the end of the press time, the top platen withdrew to
its starting distance and the panel was removed and allowed to cool at ambient
conditions.
Composite panels were manufactured from nalgrass, wheatstraw, and southern
pine. From each panel two specimens were cut and tested in static bending of modulus of
rupture, and modulus of elasticity; four for internal bond strength; and one for screw
withdrawal. One specimen from six of the 18 panels of each furnish was used to measure
water absorption and thickness swell.
Mechanical tests were conducted on ambient-conditioned specimens using a
screw-driven universal test machine according to ASTM D1037, with a few exceptions
noted below.
Static bending specimens were roughly 2 in. x 19 in. x 3/4 in. instead of
3 in. x 20 in. x 3/4 in. as specified for specimens with thickness greater than 1/4 in. The
test speed was 0.36 inVmin. and the span was 18 in.
Internal bond strength specimens were 2 in. x 2 in. x 3/4 in. and tested at a speed
of 0.06 in/min. Centerline and surface breaks were recorded for each internal bond test.
Screw withdrawal specimens were 3 in. x 6 in. x 3/4 in. instead of 3 in. x 6 in.
x 1 in. as specified for face screw withdrawal and 2 1/2 in. x 4 1/2 in. x 3/4 in. for edge
screw withdrawal. The test speed was 0.06 in./min. Two edge and two face screw pull
tests were conducted on the same specimen.
Water absorption and thickness swell were measured on 6 in. x 6 in. specimens
after they soaked in distilled water for 2 and 24 hours. Thickness was measured at four
locations and averaged for each specimen. Water absorption and thickness swell were
determined as a percentage of the unsoaked weight and averaged thickness for each
specimen.
All mechanical and physical properties were averaged over the three specimens
for each type of panel. The mean values in the graphs in Table 1 (below) represent the
averages for the respective panel type.
All tests were conducted according to "Standard Methods of Evaluating the
Properties of Wood-Base Fiber and Particle Panel Materials," ASTM D1037. All panels
were first cut into 14 inch x 19 inch sections. Specimens were cut from these for testing.
Static Bending—Modulus of Rupture (MOR) and Modulus of Elasticity (MOE).
Two specimens of 2 in. x 19 in. were cut from each panel providing a total of six
specimens for each combination of density and resin level. Specimens were placed on a
United Model No. SFM-10 screw-driven test machine set for a span of 18 in. A
computer assisted program set the test speed at 0.36 in./min. and recorded the elasticity
and rupture curves. The six results for each combination were averaged and recorded in
Table 1.
Tensile Strength Perpendicular to Surface—Internal Bond (IB). Four
2 in. x 2 in. specimens were cut from each test panel. Metal loading blocks were
cemented to both faces of the specimen and allowed to cure completely. The blocks
were engaged on a Model SFM-10, and tested at a speed of 0.06 in./min. Internal bond
breaks were automatically recorded. Test results were averaged for the specimens for
each density and resin combination, and recorded in Table 1.
Direct Screw Withdrawal; Perpendicular and Edge One specimen of each test
panel was prepared with two face and two edge pulls per specimen. Face withdrawal
specimens were 3 in. x 6 in. x 3/4 in. for face pulls and 2 1/2 in. x 4 1/2 in. x 3/4 in. for
edge pulls (ASTMD1037 recommends 3 in. x 6 in. x 1 in.). Standard pilot holes were
drilled and standard screws inserted. Specimens were anchored to a platen, screw heads
gripped with a loading fixture, then withdrawn by separating the platens at the standard
rate of 0.6 in./min. Force required to withdraw the screws was recorded. Test results for
specimens with the same combination of density and resin level were averaged, and
recorded in Table 1.
Water Absorption and Thickness Swelling. One specimen of 6 in x 6 in. of each
combination was immersed in distilled water at ambient temperature for 2 and 24 hours.
Thickness was measured at four locations on the specimen using a thickness gauge, and
averaged. Weights at each period were recorded. Water absorption and thickness swell
were calculated as percent gains over the unsoaked weights, and recorded in Table 1.
The results show that at a 2 weight percent resin level and low density trial, the
nalgrass composite exceeds the maximum for the highest industry grade standard for
medium density particleboard (ANSI; M-3) whereas neither the wood composite nor the
wheatstraw composite meets even the minimum grade standard (ANSI; M-l). See
Tables 1 and 2. The 2 weight percent nalgrass composite shows significantly less water
absorption and thickness swell than the wood-based composites. Moreover, the internal
bond strength of nalgrass is significantly higher than that of the wheatstraw composite
which fails to meet minimum standards. These superior physical properties are also
apparent at the 4 and 6 weight percent resin levels.
With regard to the screw pull test, the nalgrass composites perform at least as
well as the wood-based composites, and exceeds significantly the performance of
wheatstraw composites. The modulus of elasticity (MOE) of nalgrass exceeds that of
wheatstraw and wood-based composites, for almost every level of resin addition, except
at the 6 weight percent level. At this level of resin addition, wheatstraw composite
appears to have a slightly higher modulus of elasticity.
With regard to modulus of rupture (MOR), nalgrass composite again exhibits
superior performance as compared to wood-based composite. The wood composite fails
to make the minimum (M-l) industry grade standard. When compared to wheatstraw
composite, nalgrass composite is superior when the resin level is low, such as 2 weight
percent. As the resin level increases, wheatstraw composite MOR exceeds that of the
nalgrass composites. This demonstrates one of the advantages of nalgrass composite,
namely, that good physical properties are achievable at low resin levels.
Example 3
The Formation of Representative Nalgrass/Southern Pine Particleboards
In this example, the formation of particle boards containing nalgrass/southern pine
blends is described. The mechanical and physical properties of the particle boards
compared to particle boards formed from (1) nalgrass and (2) southern pine.
Tests were conducted to compare the mechanical and physical properties of
nalgrass, southern pine, and nalgrass/southern pine particleboard. For each furnish type,
panels were manufactured with target densities of 42 lb/ft3 and 47 lb/ft3 and resin levels
of 2% and 4%. All specimens were tested in static bending, internal bond strength, face
and edge screwholding, water sorption, and thickness swell. Mechanical properties were
compared with product specifications for medium density particleboard (ANSI
A208.1-1993). See Table 2.
Table 2. Grade Specifications of Medium Density Particleboard
(National Partideboard Association ANSI A208.1-1993)
Grade MOR (psi) MOE (ksi) IB (psi) FSP (lb) ESP (lb)
M-1 1595 250 58 NS NS
M-S 1813 276 58 202 180
M-2 2103 326 65 225 202
M-3 2393 399 80 247 225
An electrically heated, computer automated hot-press was used to manufacture all
panels. The press was equipped with nominal 23 x 31 inch platens, which were driven by
a 200 ton servo-hydraulic system. The press was controlled using platen position with a
three-stage press schedule that included: (1) press closing for 60 seconds; (2) panel
pressing for 400 seconds; and (3) venting for 20 seconds. The platen temperature was
330°F. All panels were formed to dimensions of 16x20x¾ inch, but trimmed to
14 x 19 x ¾ inch.
Panels were manufactured from nalgrass, southern pine, and nalgrass/southern
pine at target densities of 42 lb/ft3 and 47 lb/ft3 and diphenylmethane diisocyanate (MDI)
resin levels of 2% and 4%. Twelve panels of each furnish were manufactured at the
different combinations of density and resin loading (i.e., three panel replicates per
combination). From each panel two specimens were cut and tested in static bending for
modulus of rupture and elasticity, four for internal bond strength, and one for water
sorption/thickness swell. One specimen from four of the twelve panels of each furnish
was used to measure face and edge screw holding capacity. Each specimen had a
different density and resin level.
Mechanical tests were conducted on ambient-conditioned specimens using a
screw driven universal test machine in general accordance to ASTMD 1037. Static
bending specimens were nominally 2 x 19 x ¾ inch (ASTM specifies dimensions of
3 x 20 x ¾ inch for specimens with thickness greater than ¼ inch). The test speed was
0.36 in/min and the span was 18 inches. Internal bond strength specimens were 2 x 2 x ¾
inch and the test speed was 0.06 in/min. Screwholding specimens were 3 x 6 x ¾ inch for
face screwholding (ASTM specifies dimensions of 3 x 6 x 1 inch) and 2½ x 4½x¾ for
edge screwholding. The test speed was 0.06 in/min. The two edge and two face
screwholding tests were conducted on the same specimen. Water sorption and thickness
swell were measured on 6 x 6 inch specimens after they soaked in distilled water for
24 hours. Thickness was measured at five locations, and averaged for each specimen.
A three-way analysis of variance (ANOVA) was performed on all mechanical and
physical properties using density, resin level, and furnish as the three factors.
In general, for each density and resin level combination, the modulus of rupture
(MOR) and modulus of elasticity (MOE) significantly increased as the proportion of
nalgrass particles within them increased (Table 3). In contrast, the internal bond
strength (IB) of panels consisting predominantly of nalgrass particles were significantly
lower than similar panels made predominantly of southern pine particles. For face (FSP)
and edge (ESP) screwholding, there were few significant differences between any of the
panels. For the most part, all panels exceeded the highest grade specifications as
stipulated by ANSI A208.1-1993 (Table 2).
Table 3. Average Mechanical Properties of Various Nalgrass.
Southern Pine and Nalprass/Southern Pine Particleboards
Furnish Nalgrass: Southern pine Target Density (lb/ft3) Resin Loading (psi) MOR (psi) MOE (ksi) IB (psi) FSP (lb) ESP (lb) Highest Grade Acceptance
100:0 42 2 2709 (183) 500 (19) 123 (17) 303 (48) 243 (29) M-3
80:20 42 2 2467 (194) 493 (33) 148 (22) 303 (160) 253 (6) M-3
60:40 42 2 2343 (229) 464 (280) 158 (17) 317 (18) 314 (97) M-2
40:60 42 2 2210 (152) 416 (230) 147 (16) 327 (1) 274 (32) M-3
20:80 42 2 2362 (283) 429 (262) 167 (14) 314 (12) 278 (21) M-3
0:100 42 2 1769 (119) 321 (10) 184 (18) 313 (46) 271 (33) M-S
100:0 42 4 3252 (238) 529 (17) 182 (14) 420 (65) 355 (36) M-3
80:20 42 4 3414 (2440) 527 (19) 201 (34) 357 (5) 301 (30) M-3
60:40 42 4 3263 (258) 521 (24) 223 (20) 386 (61) 375 (19) M-3
40:60 42 4 3176 (228) 526 (18) 230 (35) 384 (8) 341 (60) M-3
20:80 42 4 2807 (577) 458 (63) 238 (28) 443 (6) 357 (18) M-3
0:100 42 4 2272 363 249 343 288 M-2
Furnish Nalgrass: Southern pine Target Density (lb/ft3) Resin Loading (psi) MOR (psi) MOE (ksi) IB (psi) FSP (lb) ESP (lb) Highest Grade Acceptance
(410) (54) (50) (50) (53)
100:0 47 2 3297 (286) 586 (22) 153 (19) 391 (37) 347 (22) M-3
80:20 47 2 3069 (327) 583 (17) 173 (20) 338 (18) 341 (6) M-3
60:40 47 2 3111 (309) 581 (8) 170 (34) 409 (16) 369 (20) M-3
40:60 47 2 2736 (185) 499 (12) 163 (41) 380 (16) 324 (1) M-3
20:80 47 2 2993 (204) 516 (23) 199 (30) 439 (14) 404 (18) M-3
0:100 47 2 2230 (180) 390 (26) 197 (31) 392 (44) 327 (52) M-2
100:0 47 4 3297 (265) 618 (15) 220 (19) 439 (64) 401 (40) M-3
80:20 47 4 4301 (487) 666 (570) 253 (26) 442 (8) 410 (40) M-3
60:40 47 4 3852 (298) 597 (24) 275 (22) 512 (64) 461 (2) M-3
40:60 47 4 3883 (452) 632 (24) 273 (34) 517 (18) 499 (15) M-3
20:80 47 4 3933 (219) 580 (15) 272 (28) 498 (4) 429 (40) M-3
0:100 47 4 3202 (289) 473 (22) 305 (27) 496 (38) 390 (42) M-3
For all furnishes, mechanical properties generally increased as density level
increased from 42 lb/ft3 to 47 lb/ft3 and as resin level increased from 2% to 4%.
The three-way ANOVA indicated that resin level, density, and furnish statistically
influenced all mechanical properties. The effect of panel density in relation to material IB
strength was dependent on resin loading, while the effect of resin loading in relation to
material MOE was dependent on furnish type.
After soaking in distilled water for 24 hours the water sorption and thickness
swell of the panels containing a higher proportion of nalgrass particles were in general
lower than panels incorporating a higher proportion of southern pine particles (Table 4).
Table 4. Average Physical Properties of Various Nalgrass.
Southern Pine and Nalgrass/Southern Pine Particleboard
Furnish Nalgrass:Southern Pine Target Density (lb/ft3) Resin Loading (psi) WA 24 Hour (%) TS 24 Hour (%)
100:0 42 2 37.1 13.3
80:20 42 2 61.5 (5.4) 23.6 (0.9)
60:40 42 2 79.7 (2.9) 27.3 (0.3)
40:60 42 2 89.7(1.0) 28.8 (1.6)
20:80 42 2 79.3 (5.4) 29.7 (0.6)
0:100 42 2 97.3 29.2
100:0 42 4 28.2 8.2
80:20 42 4 27.8 (1.6) 10.2 (0.6)
60:40 42 4 50.2 (3.5) 16.4 (0.2)
40:60 42 4 63.3 (7.8) 18.3 (0.4)
20:80 42 4 69.8.(4.9) 19.6 (0.5)
0:100 42 4 76.7 20.1
100:0 47 2 27.9 12.3
80:20 47 2 39.0 (2.3) 18.7(1.6)
60:40 47 2 64.0 (7.9) 27.2 (2.2)
40:60 47 2 80.7(1.5) 32.4 (2.3)
20:80 47 2 79.3 (5.4) 30.5 (0.2)
0:100 47 2 79.6 35.3
100:0 47 4 22.6 7.8
80:20 47 4 19.3 (0.8) 8.7(0.1)
60:40 47 4 32.5 (5.0) 12.4(1.3)
40.60 47 4 50.4(14.1) 17.9(2.1)
20:80 47 4 63.7 (4.6) 21.2(0.1)
0:100 47 4 70.0 23.0
Values in parentheses indicate associated standard deviations.
Water sorption and thickness swell after 24 hours generally decreased as density
level increased from 42 lb/ft3 to 47 lb/ft3 and as resin level increased from 2% to 4%.
The three-way ANOVA indicated that the effect of panel density in relation to thickness
swell was dependent on furnish type, while the effect of resin loading in relation to both
thickness swell and water sorption was dependent on furnish type.
Generally, the use of nalgrass particles would be best to obtain panels of superior
strength and stifiness. The addition of southern pine particles to a furnish, by an amount
as low as 20%, although slightly affecting panel strength and stiffness, significantly
increases internal bond strength.
As panel density and resin loading increased mechanical properties increased. In a
commercial market, however, panels of the lower density and lower resin loading would
be economically preferable while still attaining wide grade acceptance.
Panels made predominantly from nalgrass particles exhibited preferable water
sorption and thickness swell characteristics to panels made predominantly from southern
pine particles. Water sorption and thickness swell, after 24 hours water submersion,
were generally reduced by an increase in panel density and resin loading.
Example 4
Utilization of Arundo Donax in Paper Production:
Kraft and Alkaline Peroxide Mechanical Pulping
In this example, the utilization of Arundo donax (nalgrass) in the production of
paper is described. The pulping behavior and pulp properties of nalgrass is also
described. Data from kraft pulping, soda pulping, and alkaline peroxide mechanical
pulping of nalgrass is presented.
The tests were to be performed on laboratory and small pilot plant scale. The
Pulp and Paper Science Department of the University of Washington was selected for
kraft and soda pulping tests and the Department of Wood and Paper Science at North
Carolina State University for the alkaline peroxide mechanical pulping tests. All testing
of handsheet paper samples was made by the Pulp and Paper Science Department of the
University of Washington.
Kraft pulping was found to proceed rapidly and resulted in relatively high yields
of easily bleached pulp. Average fiber length was high compared to other nonwood
materials and, in fact, slightly higher than that from aspen hardwood. Strength properties
were better than aspen hardwood kraft in tear and tensile.
Raw Material. Material for the present study was cut fresh from growths in
Orange County, California and shipped without drying to the University of Washington.
The nalgrass stem has a dense ring of tissue surrounding a hollow core. Stem
diameters are typically ¾ to 1¾ inches in diameter. It can be cut or milled into lengths
similar to wood chips and once crushed to break the circular cross section has bulk
density similar to that of wood chips (Table 5).
Table 5. Bulk Density
Nalgrass Wheatstraw N.W. Softwood
Uncompacted, green
BD lb/ft3 10.8 2-6 12-14
Compacted, green
BD lb/ft3 12.5 3-7 12-15
In earlier tests, nalgrass chips were used. Material for the present trials was cut
into precise lengths using a band saw then crushed. For the kraft pulping trials tests were
made at four different cut lengths, 1/2, 3/4, 7/8 and 1 1/4 inches.
The character of chipped material is important to processing into conventional
pulping equipment. The bulk density of the chipped material is important in terms of
packing into digesters and sizing of conveyors and other process equipment. The high
bulk density of chipped nalgrass will allow it to be processed in conventional, existing
chip handling and pulping equipment. Cooking liquor to raw material ratios can be low,
similar to those used for wood chips resulting in high waste liquor concentrations.
The other important chip characteristics is the ability of the cooking chemicals to
penetrate into the center of the chip during pulping. Earlier tests were done with
hammermill prepared chips and were screened to remove fines and oversized material. It
was noted that there were some long pieces (2 inch) that might hinder material flow if
they were not removed early in the processing sequence. The material gave pulp with
low uncooked rejects, indicating that the penetration of cooking liquor was quite
uniform.
A sample of dried material was also included. This was cut to 7/8 inch length and
was included to evaluate whether liquor penetration was hindered by drying as is the case
with wood chips.
Kraft Pulping and Beaching
Kraft Pulping. Kraft cooking of the nalgrass material was made at the University
of Washington using a pilot digester system. Cooks were made with each of the chip
samples under conditions aimed at producing delignification to the 20 kappa level suitable
for bleaching. Pulping conditions are given in Table 6.
Table 6. Pulping Conditions for Chips Size and Type Evaluation
Chip Size (inch) 1/2 3/4 7/8 1-1/4 Veneer Cut Dry
H-Factor 850 850 850 850 850 850
Temp (C) 170 170 170 170 170 170
Liquor/Reed 4.5 4.5 4.5 4.5 4.5 4.5
EA(%) 15 15 15 15 15 15
Sulfidity (%) 24.4 24.4 24.4 24.4 24.4 24.4
Kappa No 17.4 14.0 17.6 18.2 14.6 14.9
Rejects (%) 1.1 0.9 3.6 3.2 0.2 3.3
All samples cooked with similar results. The cooking time is short as indicated by
the low H Factor (a chemical reaction value combining temperature and reaction time).
Cooking times would be up to half those of softwoods. The high bulk density of the
nalgrass chips also allowed use of a low liquid to chip ratio similar to that used for wood
chips. This indicates that nalgrass pulping could be made in the same equipment as wood
chips and with the same heat economy. Typical low density straw and other nonwood
plant material require high liquor to wood ratios although cooking is rapid as found with
this nalgrass material.
The four various lengths of chips show only small, probably insignificant,
differences in pulping response. Although the ¾ inch chip had slightly lower kappa, 14.0
vs. 17.6-18.2 for the longer chips, the ½ inch chip gave 17.4 kappa. The uncooked
rejects were lower in the short cut chips, 0.9-1.1%, compared to the longer chips, 3.2-
3.6%, but these levels are low, indicating that uniform penetration of cooking liquors into
the material occurred and also showing that the nodes cooked well. The nodes of
grasses, of which nalgrass is a member, are sometimes resistant to pulping.
The veneer cut chips cooked similarly to the saw cut chips, giving low kappa,
14.6, and low rejects, 0.2%. This type of chip preparation would be satisfactory for
commercial operations.
The dried material showed pulping response similar to the fresh material,
kappa 14.9, rejects 3.3%, indicating that there are no problems with the penetration of
liquor into dry nalgrass chips. This means that chips could be used from fresh or dry
material without significant changes in process conditions.
The pulping of the 7/8 inch cut nalgrass is compared to typical hardwood and
softwood kraft pulping in Table 7. The nalgrass cooks more rapidly than both types of
wood, requires less chemical and produces only slightly higher rejects (a not significant
difference).
Table 7. Pulping Conditions for 7/8 Inch Chip Size Compared to Wood Chips
Material 7/8 inch Nalgrass Hardwood Typical Softwood Typical
H-Factor 850 1200 1800
Temp (C) 170 170 170
Liquor/Material 4.5 4.5 4.0-4.5
EA (%) 15 17 18
Sulfidity (%) 24.4 25.0 25.0
Kappa No 17.6 25 28
Rejects (%) 3.6 3.0 1.5
Bleaching. Most published work on the bleaching of nonwood material is made
using the now outdated Chlorine (C), Extraction (E), Hypochlorite (H) bleach sequence.
Worldwide this sequence is typically used but it is not now acceptable environmentally in
the U.S. to meet present environmental standards bleaching of kraft pulp has to be with
an Elemental Chlorine Free (ECF) method. Bleaching tests were made on pulp from a
larger scale cook on the 7/8 inch cut material using an ECF bleach consisting of Chlorine
dioxide (Do). Extraction with oxygen and peroxide (Eop). Chlorine dioxide (D1). The
results are shown in Table 8.
Table 8. Bleach Response
D.Eop.D. Bleach Sequence—0.20 Kappa Factor
Stage Do Eop Dl
Consistency (%) 10 10 10
Kappa Factor 0.2 — —
Time (min) 30 90 120
Temp (C) 60 100 70
O2 (psi) __ 30 --
H2O2 (%) _ 0.7 —
NaOH (%) 1.7 _
C1O2 (%) 1.34 _ 1.5
pH 3.3 9.5 3.4
Brightness (%ISO) • — 83.84
D.Eop.D Bleach Sequence—0.25 Kappa Factor
Stage Do Eop Dl (run 1) Dl (run 2)
Consistency (%) 10 10 10 10
Kappa Factor 0.2 _ —
Time (min) 30 90 120 120
Temp (C) 60 100 70 70
O2 (psi) _— 30 —
H2O2 (%) _— 0.7 —
NaOH (%) __— 1.7 _—
CIO, (%) 1.68 — 1.25 1.5
PH 3.3 9.5 3.4
Brightness (%ISO) — — 85.6 86.4
Initially, a chlorine dioxide charge in the first stage of 0.20 kappa factor
(percentage equivalent chlorine/kappa number) was applied, followed by 1.5% chlorine
dioxide in the third stage. This resulted in a brightness of 83.8%. Modification to a
0.25 kappa factor application in the first stage resulted in brightness of 85.6 and 86.4
with 1.25% and 1.5% chlorine dioxide in the third stage, respectively.
A total chlorine dioxide charge of 3.18% was required for the 86.4. In earlier
tests, a brightness of 90.0 was reached in a five stage bleach using 4.34% chlorine
dioxide. Softwood kraft pulps typically require 5.8 to 6.2% chlorine dioxide to reach a
brightness level of 90.0%.
Handsheet Properties. Standard testing of pulp properties was made using
TAPPI procedures. Pulp from the 7/8 inch chip sample was beaten in a PFI mill to
various freeness levels. The PFI mill is a standard laboratory pulp beating apparatus used
to simulate refining in commercial papermaking operations. Typically the initial pulp
freeness of 600 to 750 ml CSF is reduced to about 400 to 500 ml before papermaking to
develop strength properties, tensile strength is increased with some small loss of tear
strength.
Handsheets were made from 7/8 inch of cut nalgrass pulp beaten to several
freeness levels and tested for strength properties, (Table 9). Pulps from the other chip
cut lengths were beaten to the 400 ml CSF level for comparison.
Table 9. Handsheet Strength Tests
Chip Size (inch) PFI(K) Freeness (ml) Burst Index Tear Index Tensile Index
seven-eighth 0 700 2.51 3.99 41.55
1 605 3.80 10.39 63.50
2 488 4.75 9.38 72.42
3 415 5.10 9.15 78.93
3.2 404 4.48 9.38 75.10
3.6 391 5.01 9.40 78.29

half-inch 0 733 2.56 4.69 39.36
3.2 413 4.78 8.78 77.60

three-fourth 0 700 3.11 3.99 49.82
3.2 393 5.08 9.30 79.98

one and one-fourth 0 709 3.07 4.24 47.22
3.2 393 5.25 9.04 81.21
The initial pulp freeness before beating was 700 ml CSF which is a very high and
desirable level compared with typical nonwood material. In earlier tests a similar high
initial freeness of 630 ml CSF was found. These compare to >700 ml for softwood pulps
and 600-650 for hardwood pulps and are favorably high, allowing the papermaker to
modify the pulp properties without restriction and to allow high drainage in the
papermaking operation.
The handsheet strength measurement, burst, tensile and tear, are all at favorable
levels and higher than those obtained in earlier tests. Comparison of the two sets of
results from nalgrass and from typical wheatstraw, kenaf, hardwood and softwood are
shown in Table 10. The nalgrass has remarkably high strength in all categories. The
sheet bulk is high compared to other nonwoods which indicates the material has
significantly different characteristics than the straws.
Table 10. Comparison of Nalgrass with Other Pulps
Nalgrass A Nalgrass B Wheatstraw Whole Kenaf Aspen Kraft DFir Kraft
Freeness, ml 400 4 400 400 400 400 400
PFI Mill, revs. 3200 900 400 — 464 8100
Burst Index 4.5 — — 5.5 2.1 6.8
Tear Index 9.4 8.7 3.7 10 7.6 22.4
Tensile Index 75 53 40 65 46 92
Bulk, cc/g — 1.59 1.24 — 1.43 1.81
Brightness, % 86 90 85 — 89 89
While the preferred embodiment of the invention has been illustrated and
described, it will be appreciated that various changes can be made therein without
departing from the spirit and scope of the invention.
CLAIMS:
1. Arundo donax pulp, obtained by a process comprising cooking a furnish of
Arundo donax particles using an H-factor of about 850.
2. The pulp as claimed in claim 1, wherein Arundo donax particles are selected from
the group consisting of a chip and a flake.
3. The pulp as claimed in claim 1, wherein the Arundo donax particles are subjected
to comminution.
4. The pulp as claimed in claim 3, wherein the comminution is performed by a
hammermill.
5. The pulp as claimed in claim 3, wherein the comminution is performed by a rotary
disc refiner.
6. The pulp as claimed in claim 1, wherein the process involves kraft pulping.
7. The pulp as claimed in claim 1, wherein the process involves soda pulping.
8. The pulp as claimed in claim 1, wherein the process involves alkaline peroxide
mechanical pulping.
9. The pulp as claimed in claim 1, wherein the process involves sulfite pulping.
10. The pulp as claimed in claim ], wherein the process involves pulping and bleaching.
11. The pulp as claimed in claim 10, wherein the bleaching comprises elemental
chlorine free bleaching.
12. The pulp as claimed in claim 1, having a freeness in the range from about 150 to
about 750 CSF.
13. The pulp as claimed in claim 1, which has a brightness of at least about 55% ISO.
14. The pulp as claimed in claim 1, which has a brightness of at least about 75% ISO.
15. A method for forming an Arundo donax pulp, comprising subjecting a furnish of
Arundo donax particles to a pulping process, which involves cooking the furnish using an
H-factor of about 850.
16. The method as claimed in claim 15, wherein the pulping time to achieve a 48%
yield and a kappa value of about 15 is about 25% less than that required for pulping
hardwood to achieve the same yield and kappa value.
17. A method for forming an Arundo donax pulp, comprising the steps of:
(a) selecting a furnish of Arundo donax particles;
(b) subjecting the furnish to a pulping process to produce a brown stock of pulp,
the pulping process involving cooking the furnish using an H-factor of about 850; and
(c) bleaching the brown stock to a brightness of from about 55 to about 90% ISO.
18. The method as claimed in claim 17, wherein bleaching brown stock to a
brightness of about 90% ISO requires 25% less bleach than that required for bleaching
hardwood to the same brightness.
19. A paper product comprising Arundo donax pulp, wherein the paper product has a
tensile index of at least about 50.
20. The paper product as claimed in claim 19, having one or more other pulps.
21. The paper product as claimed in claim 19, wherein the other pulps comprise
softwood pulp, and mixtures thereof.
22. The paper product as claimed in claim 20, wherein the pulp blend comprises from
about 5 to about 80 percent by weight Arundo donax pulp.
23. The paper product as claimed in claim 19, having a brightness of at least about
82% ISO.
24. The paper product as claimed in claim 19, having a burst index of at least about
3.0.
25. The paper product as claimed in claim 19, having a tear index of at least about 8.5.
26. The paper product as claimed in claim 19, wherein the product is selected from
the group consisting of high brightness printing and writing grade paper.
27. The paper product as claimed in claim 19, wherein the product is selected from
the group consisting of newsprint and publication printing grade paper.
28. The paper product as claimed in claim 19, wherein the product is selected from
the group consisting of unbleached liner and corrugation boards.
29. A method for forming an Arundo donax paper product, comprising:
(a) subjecting a furnish of Arundo donax particles to a pulping process comprising
cooking the furnish using an H-factor of about 850.
(b) depositing the furnish onto a foraminous support;
(c) dewatering the deposited furnish to provide a fibrous web; and
(d) drying the web to provide a paper product. "
30. The method as claimed in claim 29, wherein the Arundo donax furnish contains
wood fibers.
31. An Arundo donax composite panel, the composite comprising:
(a) a binder resin; and
(b) Arundo donax particles bonded into a contiguous material with resin;
wherein the composite meets at least the M-3 standard for composite panels.
32. The panel as claimed in claim 31, which comprises from about 1 to about 10
percent by weight of a resin binder based on the total weight of the panel.
33. The panel as claimed in claim 31, which comprises from 1.5 to 3.0 percent by
weight of a resin binder based on the total weight of the panel.
34. The panel as claimed in claim 31, wherein the binder is selected from the group
consisting of methyl diisocyanate, urea-formaldehyde, phenolic, and inorganic binders.
35. The panel as claimed in claim 31, wherein the Arundo donax furnish contains
wood fibers.
36. The panel as claimed in claim 35, having from about 10% to about 90% by weight
Arundo donax based on the total weight of the panel.
37. The panel as claimed in claim 35, wherein the bending strength of the panel is
caused to be increased proportionally relative to the amount of Arundo donax in the panel
compared to a wood-based panel.
38. The panel as claimed in claim 35, wherein the moisture resistance of the panel is
caused to be increased proportionally relative to the amount of Arundo donax in the panel
compared to a wood-based panel.
39. The panel as claimed in claim 35, the bending strength whereof is at least about
55% greater than a similarly constituted wood-based panel.
40. The panel as claimed in claim 35, wherein the moisture resistance of the panel is
about 2.6 times greater than a similarly constituted wood-based panel.
41. The panel as claimed in claim 35, wherein the bending strength of the panel is
about 5% greater than a similarly constituted wheatstraw-based panel.
42. The panel as claimed in claim 35, wherein the moisture resistance of the panel is
15% greater than a similarly constituted wheatstraw-based panel.
43. A method of manufacturing an Arundo donax composite panel, the method
comprising:
(a) comminuting Arundo donax into particles of a size distribution suitable for
use as furnish in a composite panel;
(b) mixing the particles with a binder to provide a binder-particle mixture; and
(c) consolidating the binder-particle mixture into a composite panel.
44. The method as claimed in claim 43, wherein the particle-binder mixture contains
wood particles.
Composite panels and pulp, and paper products of the pulp, are
produced from Arundo donax. In the fabrication of the composite
panels, Arundo donax is comminuted (20) to a suitable size, combined
with a binder (40, 50), and consolidated (80) into panels that meet
standards for construction and/or furniture grade panels. The Arundo
donax particulates may be combined with wood particulates to produce
a mixed furnish that can be used in the preparation of composite
panels. Comminuted Arundo donax is treated, in conventional pulping
processes, to produce a high tensile strength pulp that can be used in the
production of paper. The pulp has a lighter color than wood pulp, and
thereby uses less bleaching chemicals to achieve a desired whiteness.
The pulp can be combined with wood pulp to produce a variety of
products.

Documents:

IN-PCT-2000-631-KOL-FORM 27.pdf

IN-PCT-2000-631-KOL-FORM-27.pdf

in-pct-2000-631-kol-granted-abstract.pdf

in-pct-2000-631-kol-granted-assignment.pdf

in-pct-2000-631-kol-granted-claims.pdf

in-pct-2000-631-kol-granted-correspondence.pdf

in-pct-2000-631-kol-granted-description (complete).pdf

in-pct-2000-631-kol-granted-drawings.pdf

in-pct-2000-631-kol-granted-examination report.pdf

in-pct-2000-631-kol-granted-form 1.pdf

in-pct-2000-631-kol-granted-form 18.pdf

in-pct-2000-631-kol-granted-form 3.pdf

in-pct-2000-631-kol-granted-form 5.pdf

in-pct-2000-631-kol-granted-form 6.pdf

in-pct-2000-631-kol-granted-gpa.pdf

in-pct-2000-631-kol-granted-others.pdf

in-pct-2000-631-kol-granted-pa.pdf

in-pct-2000-631-kol-granted-reply to examination report.pdf

in-pct-2000-631-kol-granted-specification.pdf

in-pct-2000-631-kol-granted-translated copy of priority document.pdf


Patent Number 225229
Indian Patent Application Number IN/PCT/2000/631/KOL
PG Journal Number 45/2008
Publication Date 07-Nov-2008
Grant Date 05-Nov-2008
Date of Filing 13-Dec-2000
Name of Patentee NILE FIBER PULP & PAPER, INC.
Applicant Address 1437-23RD AVENUE, SEATTLE, WA
Inventors:
# Inventor's Name Inventor's Address
1 ALTHEIMER ERNETT 5812 SOUTH M. STREET TACOMA, WA 98408
2 WOLCOTT MICHAEL P 1078 TEARE ROAD, MOSCOW ID 83843
PCT International Classification Number D21C 1/06
PCT International Application Number PCT/US99/13519
PCT International Filing date 1999-06-16
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 60/089,1998 1998-06-17 U.S.A.