CA1322435C

CA1322435C - Production of paper and paper board

Info

Publication number: CA1322435C
Application number: CA000594866A
Authority: CA
Inventors: John Graham Langley
Original assignee: Allied Colloids Ltd
Current assignee: Ciba Specialty Chemicals Water Treatments Ltd
Priority date: 1988-03-28
Filing date: 1989-03-28
Publication date: 1993-09-28
Anticipated expiration: 2010-09-28
Also published as: JPH026683A; FI891465A; JPH0529719B2; DE68905208T3; FI97307B; FI97307C; DE68905208D1; DE68905208T2; JPH05239800A; NO891301D0; NO174724B; KR960002733B1; EP0335575A2; EP0335575B2; NO891301L; AU3174989A; FI891465A0; EP0335575A3; AU613465B2; ES2053980T5

Abstract

ABSTRACT

Production of Paper and Paper Board Paper or paper board is made by providing an aqueous cellulosic suspension containing a cationic polymer and then adding cationic starch or a high molecular weight synthetic cationic polymer, subjecting the suspension to shear, and then adding inorganic material selected from bentonite or colloidal silica. The process is of particular value when the suspension is formed from a mechanically derived pulp and/or deinked pulp and when the product is to be newsprint or board.

Description

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Allied Colloids Limlted 60/2855/01 Production of Paper and Paper Board Paper or paper board is made by providing a thick stock, diluting the thick stock to form a thin stock, draining the thin stock to form a sheet and drying the sheet. The thick stock can be made either by mixing water into dried pulp or, in an integrated mill, by diluting a drained pulp.
It i5 standard practice to improve the process performance, or the product quality, by including various additives at one or more of these stages.
For instanee, if the pulp from the which the thick stock is made is impure, the normal way of preparin~ it for drainage is by adding inorganic material, such as alum, talc or bentonite, at the pulping or thick stock stages. These treatments can have the effect of minimising problems due to pitch and other sticky materials.
If it is necessary to improve the strength of the final sheet it is eommon to inelude a dry strength resin, for instance a cationic starch, in the stoek that is to be drained.
It is standard practiee to include cationic polymers in the stock that is to be drained in order to improve drainage and/or retention.
Processes for improving retention are described in U.S. ~,388,150 and involve the addition of cationic starch and colloidal silieic acid to the ~stock before drainage. Such processes have been commercialised under the trade name "Composil" (trade mark).
Processes tha* give improved drainage, retention, - drying and formation are described in EP 235893 and involve adding a first syn~hetic~cationic polymer before a shear st~ge and bentonite after that shear stage.

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Such processes have been commercialised under the trade name "Hydrocol" (trade mark).
Although this process gives very good results in most instances, there is room for improvement ~ith some stocks, especially impure stocks, and for some end products, for instance newsprint and board.
In the inventlon, paper or paper board is made by a process comprising providing a cellulosic suspension, subjecting this to one or more shear stages selected from cleaning, mixing and pumping stages, adding a main polymer, selected from substantially linear synthetic cationic polymer having molecular weight above 500,000 and cationic starch, before one of the shear stages and adding inorganic material selected from bentonite and colloidal silicic acid after that shear stage, draining the suspension to form a sheet and drying the sheet, and in this process there is a preliminary polymer inclusion stage selected from (a) the inclusion in the suspension before the main polymer of a low molecular weight water soluble synthetic cationic polymer having molecular weight lower than the molecular weight of the main polymer, and (b) the inclusion of a water soluble synthetic cationic polymer as a drainage aid for the drainage of cellulosic pulp when the suspension is made by draining a cellulosic pulp tin the presence of the drainage aid) and diluting the drained pulp.
The preferred aspect of the invention comprises the incorporation of the said low molecular weight water soluble synthetic cationic polymer.
The inclusion of the low molecular weight cationic pol~mer in the thin stock before addition of the main polymer can lead to improvement in the processing and performance properties obtained by the addition of the main polymer before a shear stage and bentonite or colloidal silicic acid after that shear stage. For ~3~2~3 3 instance, depending upon the other conditions, it can lead to reduced problems due to pitch and other sticky materials and can lead to improved wet and/or dr~y strengths, runability, drainage, linting, opacity and S other paper qualities.
In this first aspect of the invention, the aqueous cellulosic suspension can be made either from dried pulp or, in an integrated mill, by diluting a drained pulp, all in conventional manner.
In the second aspect of the invention, the cellulosic suspension is made by diluting a drained pulp in an integrated mill and the drainage of the pulp is promoted by including a pulp drainage aid in the pulp that is to be drained, this draining aid comprising a water soluble cationic polymer. The cationic polymer for this purpose can be any of the synthetic polymers discussed below for use as the main cationic polymer.
When draining a pulp, in an integrated mill, to form a wet pulp that can then be diluted to make the thick stock and the thin stock, it is common to include no drainage aid in the pulp since drainage~ often occurs adequately without incurring the expense of a drainage aid. However in this aspect of the invention it is desirable to include a drainage aid since it promotes drainage and/or retention and provides~ a drained pulp that already contains cationic polymer and the inclusion of this cationic ~polymer has beneficial eff~ects on the subsequent treatment with the described main polymer~and the inorganic additive. For instance it can reducé the amount of main polymer that is required for optimum performance and the ~combined amount~of drainage aid and main polymer may then be appro~imately the same as the optimum amount of main polyme~r if~the pulp had not~ been treated with drainage aid. Thus~by applying drainage aid the process can be improved both at the pulp drainage ' -.
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stage and the sheet formation stage but the total amoun' of pol~mer that is used is substantiall-~ unchanged and the final performance quality can be substantiall~
unchanged.
The amount of drainage aid polymer is usually at least 0.005 or 0.013 often at least 0.03 or O.OS~ but it is generally unnecessary for it to be more than 0.3~
or at the most 0.5%. Amounts of 0.1 to 0.2% are often preferred. These percentages are based on the dry weight of the pulp.
The sunthetic polymeric drainage aid can be a drainage-promoting relatively low molecular weight polymer for instance any of those discussed below as the polymer having lower molecular weight than the main pol~mer but is generally a relatively hi~h molecular weight polymer for instance having a molecular weight conventional for dewatering aids and retention aids.
For instance the polymer typicalll~ is a substantially linear synthetic cationic polymer having molecular weight above 500 000 and preferably having intrinsic viscosit~
above 4dl/g. Thus it may be any of the pol~mers described in EP 0235893.
Intrinsic viscosities herein are derived in standard manner from determination of solution viscosities by suspended level viscometer of solutions at 25C in 1 Molar NaCl buffered to pH about 7 using sodium phosphate.
Irrespective of whether or not the thick~stock lS
made b~ dilution of a wet pulp that has been drained in the presence of a drainage aid it is preferred in the invention to incorporate the described low molecular weight weight soluble s~nthetic cationic polymer before the main poIymer. ~ ~
It is preferred that the remainder of the process should be ~imilar to the "Hydrocol" process and thus should be otherwise conducted as ln EP 235893 using a , ' ' :

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synthetic cationic polymer having molecular weight at least 500,000 before one of the shear stages and bentonite after. The materials and processing conditions described in EP 235893 can be used in the invention, subject to the modification that the suspension includes the low molecular weight polymer before addition of the main polymer. Alternatively, and less preferably, the bentonite can be replaced by colloidal silicic acid or other suitable fine particulate material or the synthetic polymer can be replaced by cationic starch.
Sometimes lower amounts of the main polymer than are recommended in EP'35893 can give good results in the present invention, for instance amounts of less than 300g/t e.g. 50g/t (0.005%) to 250g/t, especially above lOOg/t based on the dry weight of the stock.
The process can alternatively be similar to that described in US43~8150 with the addition of cationic starch into the suspension prior to the colloidal silicic acid (which can be modified as W086/5826).
The low molecular weight polymer can be present in the thick stock that is diluted to form the thin stock or it may be added to the thin stock. For instance generally the thick stock is diluted to form the thin stock by use of white water. It is desirable to add the low molecular weight polymer before, or immediately after or during, the dilution with white water and to add the main polymer to the thin stock, after the addition of the low molecular weight polymer.
The low molecular weight polymer should have a molecular weight sufficiently lower than the molecular weight of the main polymer that it will provide different process or performance benefits. For instance this aspect of the in~ention does not include a process in which both the low molecular weight and high molecular ~ 3~2~

weight polymers are primarily cationic retention aids.
Instead, it is restricted to processes in which the low molecular weight polymer does provide a dif erent performance benefit. Generally the low molecular weight polymer has intrinsic viscositv below 2dl/g and usually has molecular weight below SOO,OOO. The molecular weight is usually above 50,000 and often above lOO,OOO.
A preferred relatively low molecular weight polymer is polyethylene imine. A suitable grade of this type of polymer is the material sold under the trade name Polymin SK. Other suitable materials are polymers and copol-lmers of diallyl dimethyl ammonium chloride, of dialkyl amino alkyl (meth) acrylates and of dialkylaminoalkyl (meth) acrylamides (both generally as acid addition or quaternary ammonium salts), as well as pol~amines and polydicyandiamides-formaldehyde polymers.
Amphoteric synthetic polymers may be used.
One preferred process according to the invention utilises a relatively crude stock containing significant amounts of pitch and/or having high cationic demand.
For instance it may require at least O.l~ Polymin SK to give improved re~ention when the Polymin SK is used in conventional manner as retention aid. Polymin is a trade mark. Such stoc~s are, for instance, those containing more than 25% by weight, usually more than 50~
by weight, of mechanicall~ derived pulps and/or deinked pulps. By mechanically derived pulps we mean groundwood, pressure refined groundwood, thermo-mechanical, chemi-thermo mechanical or any other high yield mechanically derived fibres.
In these instances, the low molecular weight polymer can be selected primarily to reduce cationic demand and/or avoid pitch problems and/or linting.
When using these relatively crude pulps, the process is of particular value when the stock is to be used for 2 ~

the manufacture of newsprint, and for this purpose stock is generally substantially unfilled or only contains small amounts of filler, for instance O to 15~ and often O to 10~ based on the dry weight of the stock. Benefits are however also achieved if the stock contains filler in amounts to ~ive up to 30~ filler in the final paper produc~d.
The process is also of value in the manufacture of board, again often from similar crude pulps containing little or no filler. In these instances an alternative or additional property of the low molecular weight polymer may be to improve the strength of the board and for this purpose a low molecular weight water soluble synthetic cationic dry strength resin may be used as the polymer. Amphoteric polymers are particularly suitable for this purpose.
The amount of low molecular weight polymer is up to 0.5~ generally in the range 0.01 or 0.05 to 0.2%, based on the dry weight of the stock, and the optimum can be found by routine e~perimentation. Often the pulp, before treatment with the low molecular weight polymer, has a cationic demand (as measured by titration with the main cationic polymer) of above 400g/t and the low molecular weight polymer is included in the stock, or 2~ ahead of the stock, in an ~mount-to reduce thP cationic demand of the thin stock to below 300g/t before adding the main polymer.
The process of the invention is found to give an improvement in the performance since it can give improved pitch and/or stickies removal, improved paper quality such as opacity and linting characteristics improved wet strength or runnability during manufacture. Furthermore the performance of the process when assessed in terms of the drainage characteristics is improved by the incorporation of the second~ polymer, as compared to a , :

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process without that polymer, for instance a pracess as described in EP235893 or US4388150.
In the following examples, Polymer A is a polymer of IV 7dl/g formed from 753 acxylamide and 25%
dimethylaminoethyl acrylate, MeCl quaternised, and Polymer B is a modified polyethyleneimine as sold under the trade name Polymin SK.
Example 1 A 100% mixed waste stock having a consistency of 0.5% was prepared. Drainage tests were conducted on the stock using a modified Shopper Riegler freeness tester, the time for 600mls of backwater to drain from the stock sample being measured. The stock was subjected to shear and the drainage was measured. In one test no additions were made be~ore or after the shear. In other tests bentonite was added after the shear and polymer A and/or polymer B was added before the shear. When both polymers A and B were added, B was added considerably ahead o~ polymer A.
The results are as follows.
Table 1 Polymer B Polymer ABentonite Drainage _ o 0 0 74 0 0.04% 0.2% 32 0.02% 0.04% 0.2% 18 0.04% 0.04% 0~2% 13 0.04% o 0.2% 51 Example 2 A process similar to the preceding example was conducted using a stock having a high mechanical ibre content, and in particular being a 50:50 groundwood:bleached ~raft pulp having a consistency of ~322~ 3 1.0%. In addition to measuring the drainage time as in the previous example, a pitch count was made (in particles/ml by the Allen method). The following results were obtained.
Table 2 Polymer B Polymer A Bentonite Drainage Pitch Percentage Count Pitch Reduction o 0 0 80 5.8 x 106 0 0.025% 0.2~ 49 1.7 x 106 70%
0.025% 0.02S~ 0.2% 35 1.2 x 106 79%
0.05% 0.025% 0.2% 31 5.1 x 105 91%

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These examples clearly demonstrate the value of adding, for instance 0.01 to 0.196, generally around 0.02 to 0.07%, polyethylene imine so as to reduce the amount of high molecular weight (for instance IV above 4~
cationic retention aid that is required for good drainage and retention and so as to counteract the effect of stock having high cationic demand and, especially, high pitch count.
Example 3 Newsprint is made using a stock based on 3% kraft, 17% magnefite, 38% thermomechanical pulp and 42%
groundwocd, and to which 20~6 broke has been added. High molecular weight polymer is added, in some tests, just before the~last shear stage and bentonite is added, in some tests, after the last shear stage. Low molecular weight polymer is added to the thin stock soon after it is diluted rrom the thick stock.
In these tests the low molecular weight polymer is ~:
polymer K which is a solution polymer of about IV 1 dl/g and formed from about 20%~ acrylamide and 80% by weight `, ', , ~

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diallyl dimethyl ammonium chloride. The high molecular weight polymers are L, which is 70% acrylamide, 30%
methyl chloride quaternised dimethylaminoethyl acrylate IV 8, and polymer M which is 95% acrylamide and 5% methyl chloride quaternised dimethylaminoethyl acrylate IV ll.
The drainage rate for each of the treated suspensions is measured, w.ith the best results being those that have the hiyhest drainage figure. The results are as follows.
Table 3 -Polymer K ~igh MWBentonite Drainage Polymer 15o.~% o 0 195 0.2% 0 0.2% 300 0.2~ 0.05%L0.2% 335 0.2% 0.05%M0.2~ 340 0 0.05%M0.2% 325 These results clearly demonstrate the benefit in the manufacture of newsprint from adding high molecular weight cationic polymer immediately before shear and bentonite after shear even when the high molecular weight polymer only has a relatively low cationic charge, and they also show that a useful result can be obtained when the high molecular weight polymer is replaced by a lower molecular weiyht polymer having molecular weight above 500,000, but that best results are obtained using a combination of both.

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Claims

1. A process in which paper or paper board is made by forming an aqueous cellulosic suspension, passing the suspension through one or more shear stages selected from cleaning, mixing and pumping stages, adding a main polymer selected from cationic starch and high molecular weight water soluble cationic polymer to the suspension before one of the shear stages and adding inorganic material selected from bentonite and colloidal silica after that shear stage, draining the suspension to form a sheet and drying the sheet, characterised in that the process includes a preliminary polymer inclusion stage selected from (a) adding to the suspension, before the addition of the main polymer, a low molecular weight water soluble synthetic cationic polymer having molecular weight lower than the molecular weight of the main polymer and (b) adding a water soluble, cationic, polymeric, drainage aid to a cellulosic pulp and then draining the pulp and diluting the drained pulp to form the aqueous cellulosic suspension.

2. A process according to claim 1 in which the main polymer is a high molecular weight linear water soluble cationic polymer having molecular weight above 500,000.

3. A process according to claim 2 in which the inorganic material is bentonite.

4. A process according to claim 1 in which at least 25% by weight of the cellulosic suspension is formed from mechanically derived pulp and/or deinked pulp.

5. A process according to claim 1 in which the product is newsprint or board.

6. A process according to claim 1 in which the main polymer is a synthetic polymer having intrinsic viscosity at least 4dl/g or is cationic starch and a low molecular weight water soluble synthetic cationic polymer having lower molecular weight is incorporated in the suspension before the main polymer.

7. A process according to claim 6 in which the low molecular weight polymer has intrinsic viscosity below 2dl/g.

8. A process according to claim 6 in which the low molecular weight polymer has molecular weight 100,000 to 500,000.

9. A process according to claim 6 in which the low molecular weight polymer is selected from polyethylene imine, polyamines, polycyandiamide formaldehyde polymers, amphoteric polymers, and polymers of monomers selected from diallyl dimethyl ammonium chloruide, diallylaminoalkyl (meth) acrylates and dialkylaminoalkyl (meth) acrylamides.

10. A process according to claim 6 in which the low molecular weight polymer is an amphoteric cationic dry strength resin and the product is board.

11. A process according to claim 6 in which the suspension to which the low molecular weight polymer is added has a cationic demand, as measured on the main cationic polymer, of at least 400g/t and the amount of low molecular weight polymer that is added reduces the said cationic demand to below 300g/t.

12. A process according to claim 6 in which the suspension that is drained to form the paper or paper board is a thin stock formed by dilution of a thick stock and the main polymer is added to the thin stock and the low molecular weight polymer is present in the thick stock.

13. A process according to claim 12 in which the suspension that is drained to form the paper or paper board is a thin stock formed by dilution of a thick stock and the main polymer is added to the thin stock and the low molecular weight polymer is added to the thin stock or to the thick stock in an amount of from 0.01 to 0.5%
based on the dry weight of suspension.

14. A process according to claim 1 in which the suspension that is drained to form the paper or paper board is made by diluting a drained pulp that has been made by draining a cellulosic pulp containing a pulp drainage aid and in which the drainage aid comprises a water soluble, cationic, synthetic, polymeric drainage aid having intrinsic viscosity above 4dl/g.