Solid material comminution or disintegration – Processes – Wood and similar natural-fibrous vegetable material
Reexamination Certificate
2003-01-30
2004-05-25
Tolan, Ed (Department: 3725)
Solid material comminution or disintegration
Processes
Wood and similar natural-fibrous vegetable material
C241S024200
Reexamination Certificate
active
06739533
ABSTRACT:
The invention relates to a method for recovery of branch knot wood and/or normal wood from oversize chips, according to the preamble of the enclosed independent claim.
Branches and limbs of a tree have their origin within the tree trunk. This inner part of a branch or limb is called a branch knot or an internal branch. The branch knot starts at the pith at the centre of the trunk and continues outwards to the periphery of the trunk, and then it extends as an external branch. The branch knot's diameter in the trunk increases towards the periphery of the trunk. Limbs which have dried out and have fallen or which have been cut away may end within the trunk and become enclosed by normal stem wood.
The morphology and the chemical composition of the branch knots differ from those of the normal stem wood. The fibres in the branch knots are shorter and they have thicker walls than the normal stem wood. For instance in spruce the branch knots' fibres have a length of about 1 mm, while in normal stem wood their length is 2 to 4 mm. The lower part of a branch knot differs from its upper part regarding the morphology. In softwood the lower part comprises so-called compression wood having fibres with thick walls and a circular cross-section. The compression wood contains more lignin but less cellulose than normal wood. The upper part contains fibres which are more like normal wood. In hardwood it is the upper part that differs from the normal wood the most. The upper part comprises so-called tension wood which contains more cellulose and less lignin than normal wood. However, the main part of the branch knot comprises pith wood with a low moisture content. The surrounding sapwood, on the contrary, has a high moisture content, even over 70%.
When trees are pruned the branch knots, i.e. the base parts of the branches or limbs remain in the trunk, and thus they will end up in the chips.
The branch knots are characterised by a high content of so-called extractive substances, which primarily protect the trees against fungus and microbe attacks, if the branch is broken or if it dries and falls off. In pines the branch knots contain up to 20-30% resin, which mainly comprises resin acids solved in a mixture of monoterpene hydrocarbons. There exists further phenolic substances, primarily pinosylvine and pinosylvinemethylether. Branch knots of spruce contain generally no more resin than normal wood, but they contain up to 20% phenolic substances of the so-called lignan-type. The main component, hydroxymatairesinol, which in Nordic spruce (Picea abies L.) constitutes 5 to 7% of the branch knots, has proved to have very strong antioxidative and anticarcinogenic characteristics. Also in hardwood the branch knots have a high content of phenolic extractive substances.
When felling trees the branches are cut away from the trunk, both when felling sawn timber and when felling pulp wood for paper and board production. On the other hand, the branch knots remain in the trunks. Their proportion of the trunk wood varies widely between different timber species, and also between different trees of the same species. Normally the branch knots form between 1 and 5% of the weight of the stem wood.
At the production of sawn timber the outer part of the trunk becomes waste, which usually is cut to chips and then supplied to a pulp plant or to the production of energy. At thermomechanical and chemi-thermomechanical pulp production the wood is first cut to chips and then defibered in a disc refiner. Also in chemical pulping the process starts with wood cut into chips. However, at groundwood and pressurised groundwood pulp production the source material is debarked stem wood.
As the wood is cut to chips the branch knots will form large chip lumps, so-called oversize chips. The hard branch knots are separated as such, together with more or less normal wood. Usually the chips are screened, it has thereby been observed that even more than 90% of the branch knots remain in the oversize chips fraction. The standard procedure is to cut the oversize chips once more in a special chipper, and return the chips to the chip screening. This means that practically all branch knot material eventually will be supplied to the fibre production. A separation of the whole oversize chip fraction will not be economically reasonable, as it usually constitutes 5 to 10% of the total amount of the chips. In certain pulp mills requiring particularly clean chips, a small part of the branch knot material is separated by air screening.
The branch knots provide due to their short and thick fibres a weak pulp for the production of paper and board. The branch knot material is further difficult to defiber, as they can not be impregnated by the cooking liquor or by water. In chemical pulp cooking the cooking liquor poorly penetrates into the knots, and knots remain in the pulp after the cooking in the form of splinter or even larger lumps. In mechanic pulp production the branch knots are not defibered at all in practice, but they are ground to a slime-like pulp (TAPPI Journal 78:5, 1995, pp. 162-168). The higher the proportion of branch knots in the chips, the weaker a pulp is obtained. The branch knots contain substances which absorb light and therefore provide a darker pulp which is difficult to bleach to a high brightness.
The high amount of extractive substances in the branch knots will cause additional problems in the production of pulp and paper. The resin components cause big problems by forming sticky deposits, particularly on paper machines. The extractive substances also result in an increased consumption of chemicals during cooking and bleaching. They can also generate condensation reactions with the chemicals, and thus completely inhibit delignification and fibre separation.
In order to summarise it can be stated that branch knots are undesirable in the production of pulp and paper, and that they should be screened out. The problem is that the known screening methods are not sufficiently selective, so that only branch knots, and then particularly their pith part could be screened out, without losing valuable normal stem wood.
Another reason for screening out the branch knot material is that it contains high amounts of valuable extractive substances. As an example can lignans in spruce be mentioned, the main component of the lignans being hydroxymatairesinol, which is a particularly interesting bioactive substance. Branch knots of pine contain bioactive stilbenes and other phenolic substances. In addition there exist very high amounts of resin, whereby the branch knots can be utilised e.g. in the production of so-called wood rosin. Such wood rosin is produced at a smaller scale from pine stubs, but it is difficult and expensive to pull out the stubs and to further process them for the extraction.
It is previously known to separate branch knots from production-chips by thickness screening. Namely, it has been found that the larger part of the oversize fraction contains knots, and that about 90% of the knot material is concentrated there (STFI-kontakt Nr 4, 1987, pp. 6-7; and TAPPI Journal 78:5, 1995, pp. 162-168). Thus pulp production, particularly the production of mechanical pulp and thermomechanical pulp can be facilitated, and the quality of the pulp be improved, while the separated branch knot material is used for the production of energy by combustion.
However, the separation of the branch knot material from normal wood will increase the costs of the pulp production, and it may not be that the achieved advantages motivate such a cost increasing measure. However, further advantages can be achieved if it was possible in a simple and economical manner to recover the extractive substances contained in the branch knot material in such high amounts.
It is previously known that pith wood, and particularly branches, contain a high amount of lignans (R. Ekman, Holzforschung 30, 1976, pp. 79-85; and Acta Academiae Aboensis Ser B, 39, 1979, pp. 1-6). Lignans exist in all softwoods and particularly in the pith of pine and spruce, which conta
Eckerman Christer
Holmbom Bjarne
Lydon James C.
Oy Separation Research AB
Tolan Ed
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