The Preparation of Plantation Rubber Part 33
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[33] "Archief voor de Rubbercultuur" (De Vries and Spoon), Central Rubber Station, Java, May, 1921.
(1) During the rainy monsoon and at a height of 1,800 feet.
(2) During the dry monsoon on a low-country estate.
(3) In the experimental gardens at Buitenzorg during bright sunny weather and the most favourable conditions.
The agents used were (_a_) a mixture of alcohol and fusel oil, (_b_) alcohol and petrol (benzene).
In these experiments no advantage in weight of rubber was obtained by the Ilcken-Down process, and it would thus appear that the princ.i.p.al claim fails to be substantiated.
The general composition of the rubber was approximately the same as ordinary crepe obtained from undiluted latex. The rubber on vulcanisation was found to be normal in behaviour, and was similar to the controls.
The coagulum ordinarily is affected by oxidation, and does not produce a fine pale crepe. To remedy this defect the freshly prepared crepe is soaked in a solution of sodium bisulphite and sulphuric acid.
It may be noted that in the recent experiments coagulation was effected in vacuum in a specially designed wooden tank. From a study of the previous section on "Spontaneous Coagulation," the reader will perceive that results equal to those obtained by the Ilcken-Down process can be obtained _without_ the necessity of using such agents as alcohol, petrol, or fusel oil.
SLAB RUBBER.--This type of preparation has been the subject of much discussion of recent years. There is nothing really special in the mode of preparation, and in its original form "slab" rubber is only a thick sheet which may be obtained by coagulation with acetic acid or other agents.
The coagulum, when removed from the serum, is subjected to comparatively slight pressure, and the "slab" thus made is either placed to air-dry at once, or may be subject to treatment in other liquids before drying.
The rubber is not allowed to remain until wholly dry, but is s.h.i.+pped while still containing an appreciable percentage of enclosed moisture.
It is claimed[34] that the production of "slab" rubber by standardised methods eliminates to a great degree the variability which at present characterises plantation rubber, and that a fast-curing medium is obtained.
These claims will be discussed in later chapters dealing with the vulcanisation of rubber, and demand no notice in this section.
[34] "Preparation and Vulcanisation of Plantation Rubber" (Eaton, Grantham, and Day), Bulletin No. 27, F.M.S. Department of Agriculture, 1918.
From the producers' point of view, it may be noted that the preparation of slab rubber is a simple process, but not altogether as pleasant probably as might be desired, when undertaken in crude form.
The appearance of the partially dry slabs is unattractive, but that does not signify if the quality of the vulcanised product satisfies requirements.
For the average producer, the difficulty lies in having to meet the demands of the general market. Even, therefore, if one a.s.sumes that the intrinsic qualities of slab rubber are all that the claims advance, it would be necessary for the producer to be a.s.sured of definite and regular sales.
At present it would probably be fair to state that practically all the "slab" rubber being prepared is produced by those who are also consumers.
They are thus in the enviable position of being able to satisfy their requirements as to the mode of preparation. Until such time, therefore, as there exists a regular demand for "slab" rubber in the general market, the vast majority of estates must proceed on ordinary lines of preparation.
PART VI
VULCANISATION
(BY DR. H. P. STEVENS)
CHAPTER XXI
_INTRODUCTORY DEALING WITH TREATMENT AND VULCANISATION_
In the foregoing chapters the methods of treating latex, coagulating, rolling and curing, or drying, have been described in great detail. These details will give the reader some idea of the precautions taken, and procedure necessary to produce rubber which will be acceptable to the market. The expressions "inferior rubber," "defective crepe," "poor quality sheets," etc., are frequently met with, but these expressions must not be taken to indicate any defect in the rubber for manufacturing purposes, but merely that the rubber is defective for selling purposes--that is to say, being unsightly, it will not fetch the full market price.
Raw rubber, as produced on the plantations, is almost invariably subjected to the process of vulcanisation in the production of manufactured rubber articles as we know them. Previous to the advent of plantation rubber, the raw material was purchased by the manufacturer in a moist and impure condition; frequently the rubber was adulterated with sand, dirt, and even small stones. Consequently it was the invariable practice of the rubber manufacturer to wash the raw rubber and convert it into crepe, which was then hung and air-dried before use. The effect on the rubber, if of high grade, was more severe than the was.h.i.+ng and crepeing process on the plantation, because the rubber was not a soft coagulum but generally dried on the surface and semi-hard. The power required was considerable, and the resulting crepe was consequently softer and more susceptible to heat than plantation first latex crepe. Much of the "wild" rubber was soft and tacky and inferior to "earth-sc.r.a.p."
Vulcanising in its simplest aspect consists in mixing the rubber with sulphur and heating the product under regulated conditions. The effect of heat on the inferior grades of "wild" rubber is very marked. A soft, sticky, and resinous material is transformed into a relatively tough and elastic product. The effect of vulcanising on the better grades is less marked, but immediately apparent. On the other hand, the effect of vulcanising is least apparent on first latex plantation grades, because in these we have a raw rubber prepared in a manner best suited to retain its natural characteristics.
The need of vulcanising in the process of manufacturing rubber goods became an axiom in pre-plantation days, and it is only quite recently that attempts have been made to utilise raw rubber directly, without vulcanisation, particularly for shoe soles. For this purpose a thick dense crepe has been found satisfactory. Smoked sheet rubber is not generally suitable, apparently owing to its microphysical structure. It is possible that the process of rolling in the making of dense crepe compacts the rubber particles, yielding a harder and more resilient product. The rolling must not be carried too far, or the "working" of the rubber will approximate to a preliminary mastication, and the product will be weakened.
The utilisation of crepe rubber directly has not yet been sufficiently tested to enable a definite conclusion to be reached as to its future scope, but it is obvious that for use in a raw state some modification in preparation may be advantageous. The present method--_e.g._, coagulation with acetic acid--does not yield the hardest and toughest rubber.
Hardness and toughness are actual drawbacks in the utilisation of rubber which is required for vulcanising. When the output of plantation rubber began to increase and to displace the inferior wild sorts, manufacturers complained of the increased power consumption of their machines. The power was required mainly to "break down" or "mill" the rubber preliminary to the mixing with sulphur and other ingredients. It is obvious that a material such as raw rubber cannot be mixed with powders such as sulphur with a pestle and mortar, or in any simple form of mixing machine. This difficulty was overcome by the earlier experimenters by immersing the rubber in a bath of molten sulphur. The latter was gradually absorbed and "dissolved" in the rubber, and the heat of the bath caused the dissolved sulphur to combine with the rubber to produce vulcanised rubber. The limitations of such a process are apparent. Thus the vulcanised rubber retains the form in which it was originally shaped. Moreover, other ingredients, such as mineral matters, cannot be dissolved or absorbed by the rubber in this manner. The method eventually adopted consisted in "breaking down," "milling," or "masticating" the rubber by pa.s.sing it continuously between differentially geared steam-heated rollers. By this means a high-grade rubber is converted into a soft, plastic ma.s.s, which will "take up" sulphur, mineral matter, and other ingredients as desired. The mixing operation may be carried through on the same roller machine as was used for breaking down the rubber, or separate machines of other designs may be adopted. Details of the process will be found in books dealing with rubber manufacturing.[35]
It will suffice here to explain that when rubber is kneaded between two hot rollers moving at different speeds the rubber forms a continuous band around the slower moving roller, and if the distance between the rollers be adjusted the excess of rubber held back by the nip of the rollers will form a "bank" or moving wedge-shaped ma.s.s on the top of the nip. This closes the s.p.a.ce between the rollers, so that sulphur and powder placed on the rubber pa.s.s round towards the nip, and are there driven into the rubber. In this manner it is easy to mix, say, 10 per cent. of sulphur into the rubber without a single particle falling through. In technical mixes where large quant.i.ties of powders require to be mixed there is always some caking, and part of the powder falls between the rollers into a tray underneath. This is swept up with a broom and put back on to the rollers, the process being repeated until the whole of the ingredients have been incorporated.
[35] For instance, "India-Rubber and its Manufacture," by H. L. Terry.
From this description it follows that, preliminary to mixing, it is necessary to thoroughly masticate or "plasticise" the raw rubber. Much of the "wild" rubber was of so inferior a quality that it very readily broke down, and but little mastication was necessary. It was soft and resinous, and readily took up the powders which were to be mixed with it. The better grades of wild rubber, such as Fine Para, were more difficult to break down, but not so difficult as most plantation rubber, because they had already received a preliminary "working" in the process of was.h.i.+ng and crepeing, and we have already explained that such treatment takes more power than the crepeing of the soft moist coagulum on the plantations. The amount of "working" or "plasticising" produced in the rubber is connected with the power expended; the greater the expenditure of power, _caeteris paribus_, the greater the working effect on the rubber. Although the manufacturers possessed a relatively soft rubber in the form of washed Fine Para, it was customary in most cases to employ this rubber in conjunction with washed lower grades to produce a soft plastic material for further treatment. Now, however, the manufacturer has little else but plantation to deal with, and most of it more difficult to break down than washed Para crepe. This is the reason why a hard, tough rubber is no longer a desideratum with manufacturers, although originally taken as an indication of good quality. For the majority of purposes they want something which will break down easily. Hence if a rubber could be produced answering to these requirements, without loss of vulcanising quality, it would be preferred.
Having incorporated sulphur and other ingredients, the plastic ma.s.s is sheeted and run between layers of calico to prevent the superimposed sheets from adhering. From this "calendered sheet" the article, whatever it may be, is built up. The calender rollers are heated so as to keep the rubber compound plastic. There is a limit to the thickness of the sheet which can be produced. It is a difficult operation to perform satisfactorily so as to yield a smooth surface and a sheet free from enclosed air. When cool the rubber hardens and is readily handled. The object to be manufactured is then built up from the calendered sheet. Thus in the manufacture of a motor tyre the tread is built up on the casing or carcase by laying the sheets on the canvas and rolling these with a hand or power operated roller, so that they adhere firmly, the first layer to the canvas of the casing and subsequent layers to one another. This rough description will suffice to ill.u.s.trate how important it is that the rubber when mixed should be plastic enough to give a smooth sheet, and to allow the sheet to be manipulated in building up the article in process of manufacture. The testing of rubber in regard to its plasticity and power to absorb finely divided mineral matter will be discussed in a later chapter. We may, however, point out here, that the mineral matter is not generally added as an adulterant, but because of certain specific properties it confers on the product.
To proceed with our outline of vulcanisation, we have now arrived at the stage at which the goods are built up and ready for vulcanising. For this purpose they are generally enclosed in some manner, either in metal moulds bolted together, or tightly wrapped in cloth, as, _e.g._, in the manufacture of inner tubes, hose, etc. In the latter case, you can detect the cloth mark on the finished product. Sometimes the rubber is spewed--that is, driven out of a barrel by means of an endless screw revolving in it. In this way rubber tubing, perambulator tyres, and such articles, may be made. More recently even tyre treads and the shaped rubber for band tyres (heavy solid tyres) have been extruded in this manner, for the process is much cheaper than building up a tyre from calendered sheet, and then cutting the ma.s.s to shape by hand. But for spewing the rubber ma.s.s must be very soft and plastic; this condition is not obtainable unless the raw rubber originally used can be made thoroughly plastic without damage.
Nor can it be effected with a rubber ma.s.s containing much finely divided mineral matter, as this hardens the mixture.
For other purposes the rubber is swollen in a solvent, such as coal-tar naphtha, and subsequently masticated; the soft dough is then shaped or spread on cloth, and vulcanised after allowing the solvent to evaporate.
Here, again, the properties of the raw rubber are of immense importance.
Thus, the more plastic the dough, the less solvent required, and the less there is to drive off before vulcanising. The plasticity of the dough will depend on the plasticity of the raw rubber, and so forth. It is evident that the physical properties of the raw rubber are of great importance.
They directly affect the manufacturing operations up to the vulcanising stage, and indirectly affect the results obtained on vulcanising.
The actual vulcanising consists of heating the ma.s.s of mixed rubber for a definite time and at a definite temperature, each "heat" being chosen to suit the particular mixture. These data are arrived at empirically--that is, by trying a number of "heats" and choosing that which appears the most suitable. The suitability will depend on the nature of the article, the service to which it is to be put, and the time it is intended to last. All vulcanised rubber goods, whatever the process, have a limited life or period during which they can be relied on to give useful service. After a time, vulcanised rubber tends to harden, cracks appear on the surface when the article is bent or stretched, and eventually the rubber becomes rotten and "perished." This tendency varies with the quality of the original raw rubber and the conditions of vulcanising. Before plantation rubber was available, the manufacturers were dependent on inferior wild grades for a great part of their output, and, consequently, the goods made from these inferior rubbers never showed very good mechanical properties and soon deteriorated. The severest critics of plantation rubber have admitted the advantages to the manufacturers of the replacement of the lower wild grades by plantation rubber.[36] But even the best grades give a vulcanised product which rapidly deteriorates if the vulcanisation is carried too far. This results from too long heating, or too high a temperature, and the product is termed "overvulcanised" or "overcured."[37] The appearance of the product is deceptive, as the physical properties are remarkably good if the overvulcanising is not more than 50 to 100 per cent. in excess of the normal cure. Only in the case of very much overvulcanised rubber do we obtain a product which is brittle from the beginning.
[36] See Williams, "The Rubber Industry," 1914, p. 284. It must also be remembered that the inferior wild grades were derived from latices often containing a large proportion of "resinous" matter, and which could not yield a really high grade of vulcanised rubber whatever the care and skill employed in preparation.
[37] The terms "curing" and "vulcanising" are generally employed as if synonymous. Twiss has suggested that the former be applied in regard to a change in physical properties, and the latter to the chemical change whereby sulphur is combined with the rubber. The term "curing" is also applied to the process of preparation of raw rubber. This must be kept in mind so as to avoid confusion.
The degree of vulcanising will vary with the type of article to be produced, and where a long life is desired, the tendency will be to "undervulcanise"; but if the best mechanical properties are desired, the tendency will be towards "overvulcanising," or, more correctly, "fully"
vulcanising. These considerations are aptly ill.u.s.trated by reference to pneumatic tyres. The inner tube need not possess high tensile strength, provided that it is easily distensible, for the reason that, during use, it is protected by the casing of the tyre proper, which confines and supports it against the air-pressure applied. Inner tubes are therefore cured to give a long life without developing the maximal physical properties. On the other hand, the casing and tread of the tyre are required to withstand severe mechanical conditions--particularly the constant flexing of the cover, and the abrasion of the road surface. Tyres are not stored for any long period, and, when put into service, have a limited period of useful life. Consequently it is needful to develop maximal mechanical properties, and vulcanisation is therefore carried further than in the manufacture of inner tubes.
The rate of cure is controlled by a number of factors in addition to the period and temperature of vulcanisation, in particular by the proportion and nature of the other ingredients, especially sulphur and accelerators, and also by the rubber itself. The main complaint as regards plantation rubber is that it varies excessively in this respect. This matter will not be discussed here, but is only introduced in order to explain the importance of a constant rate of vulcanising to the manufacturer.
Plantation rubber should, therefore, be prepared so as to be as uniform as possible in this respect, and the earlier part of this book gives full details of the precautions advised, and in many cases adopted on the plantations. Unfortunately, it is impossible to secure uniformity of methods among all producers, even when they are Europeans, to say nothing of the native producers, who account for perhaps one-third of the output.
Hence the importance of branding the rubber whenever possible, so that the manufacturer may identify the rubber he purchases. If found satisfactory, he can then secure further supplies from the same estate.
CHAPTER XXII
The Preparation of Plantation Rubber Part 33
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