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A sugar cane mill is a factory that processes sugar cane to produce raw sugar or plantation white sugar. Some sugar mills are situated next to a back-end refinery, that turns raw sugar into (refined) white sugar.
The term is also used to refer to the equipment that crushes the sticks of sugar cane to extract the juice.
These processing steps will produce a brown or raw sugar. Raw sugar is generally sent to a sugar refinery to produce white sugar. This sugar refining can be done either at a completely separate factory or at a back-end refinery which is attached to the raw sugar factory.
A cane sugar mill can also produce sugar that is suitable for direct domestic or industrial consumption. This is called plantation white sugar or mill white sugar, see below.
Cane is transported by truck, narrow-gauge railway, container or cart. On arrival the cane is sold based on weight or sugar content. There are several ways to unload the harvest. Overall, limiting the time between cutting and milling is essential for achieving a high sugar yield and quality.
There are two modern types of processes for extracting juice from cane:
The products of the extraction phase are:
In 2004 and 2005 the Enterprise Sugar mill in Louisiana had a traditional mill and a diffuser, which both processed cane from the same area. Weekly raw juice samples were taken and analyzed. These were found to be very similar, despite the diffuser achieving a higher extraction.
At a chemical level, the first step is to open the cells. This is usually done by revolving cane-knives and a three roller crusher, which together open most of the thin-walled cells. The juice is then removed from these opened cells by leaching. I.e. the sucrose from these opened cells dissolves in water. The diffusion process proper takes place on the 10-16% of sugar containing cells that have not been opened. First hot water is applied to kill the protoplasm of the cells. This makes that the walls of the cell becomes semipermeable. By osmosis, water or thinner juice can then enter the cell and replace heavier juice until an equilibrium is reached. In this phase sucrose penetrates the walls faster than non-sugar with higher molecular weight. This makes that the purity of the last extracted juice from diffusion higher than that acquired by straight milling, even while diffusing extracts more sugar.
In the percolation system process, shredded cane is introduced into the diffuser at the feed end; hot water is poured over the shredded cane just before the discharge end of the diffuser. The hot water percolates through the bed of cane and removes sucrose from the cane. This dilute juice is then collected in a compartment under the bed of cane and is pumped to a point a little closer to the feed end of the diffuser and this dilute juice is allowed to percolate through the bed of cane. At this point the concentration of sucrose in the cane is higher than the concentration of sucrose in the dilute juice just mentioned and so sucrose diffuses from the cane to the juice; this now slightly richer juice is pumped back up the diffuser and the process is repeated, typically, 12 to 15 times (compared with the four to six times for the milling process)
The lime helps to prevent sucrose's decay into glucose and fructose. The superheated limed juice is then allowed to flash to its saturation temperature: this process precipitates impurities, which get held up in calcium carbonate crystals. The flashed juice is then transferred to a clarification tank.
In this clarification tank, the suspended solids are sedimented. The supernatant, known as clear juice is drawn off of the clarifier. The clarified juice is then sent to the evaporators. The settled solids can be filtered to produce a juice of poor clarity, which can be recycled for further purification.
The temperature, velocity and retention time in the evaporator are regulated to prevent sucrose inversion, or decomposition of sucrose in glucose and fructose. Another concern is scale formation on the heating surface of the evaporator. The application of a magnetic flow can help to prevent scaling.
In the crystallizer, the crystallization process of the massecuite continues. The purpose of the crystallizer is to reduce loss of sucrose by it remaining in the mother liquor / molasses, in particular with low-grade massecuites. The crystallizer works by cooling the massecuite. This decreases solubility and again increases saturation, forcing crystallization to continue. Crystallizers are cylindrical or U-shaped vessels equipped with low-speed stirring elements. They are often connected in series for continues operation.
Cooling the massecuite increases viscosity. At the optimum temperature for crystallization, the massecuite is too viscous for the centrifuge to properly separate the crystals from the molasses. However, as the mother liquor of the massecuite is still supersaturated at this point, the viscosity can be reduced without re-solution of the crystals. This can be done by bringing it to a state of saturation by heating or adding water.
While the mother liquor, molasses passes through the holes in the centrifuge, the sugar crystals are retained. After the sugar is purged, it is cut down, making the centrifuge ready for the next badge.
The most common boiling scheme is the three-boiling system. This method boils the sugar liquors in three crystallization/centrifugation stages, called A-, B- and C-. The sugar resulting from the first stage, A-sugar, is stored. The molasses from the A-centrifugation, A-molasses, are fed to the B vacuum pan. This results in B-sugar and B-molasses. A mix of A-sugar and B-sugar forms the commercial product of the factory.
The B-molasses are of a much lower purity. They are boiled again in the C-pan. While the A and B stage do not always use a crystallizer, it is essential for this low-grade massecuite. The massecuite remains in the crystallizer for more than a day. The C-sugar from the centrifuge is mingled with syrup and used as massecuite seed, and so returns to the start of the process. The molasses resulting from this centrifuge step are called final molasses, or blackstrap. It is a heavy viscous material containing about one-third sucrose, one-fifth reducing sugars, and the remainder ash, organic non-sugars and water. It serves as a base for cattle-feed, industrial alcohol, yeast production and so on.
Boiling in a vacuum pan used to be a batch process, but continuous pan boiling is inherently far more efficient. In the 1970s the first commercially successful continuous vacuum pans (CVPs) were developed. In the 1980s these first pans achieved a better uniform crystal size than that which some factories achieved with their batch process vacuum pans.
Plantation white sugar is produced by making changes to some of the stages mentioned above. There are two ways to make plantation white sugar, carbonation and sulphitation.
In the purification step, the objective of carbonation is to separate non-sugar contents such as colloids and insoluble particles as well as colored material. If carbonation is used, the mixed juice is heated to 55 °C and lime is added till a pH of 10.5-11 is reached. Next, Carbon dioxide (CO2) is added, and the juice is pushed through pressure filters. This results in calcium carbonate mud. The juice is then again heated to 55 °C and lime and CO2 is added till a pH of 8.4-8.6 is reached. This is followed by a second pressure filtration.
At the end of the evaporation step, Sulfur dioxide (SO2) is added to lower the pH of the syrup to 7.0.
In sugar factories, carbonation is not widely used, because it requires large quantities of lime and CO2, and sulphitation is cheaper. India is the exception.
In the purification stage of cold acid sulphitation, SO2 is added to the mixed juice in order to lower the pH to 3.8-4.2. Lime is then added to increase the pH to 7.2-7.4. Next the juice is heated to 103-105 °C before moving to the clarifier. In the clarifier the impurities settle, and the resulting is then filtered.
The purification stage of hot acid sulphitation involves first heating the mixed juice to 70 °C before lowering the pH to 3.8-4.2 by adding SO2. The process then runs like that of cold acid sulphitation.
The purification stage of double liming consists of first heating the mixed juice to 70 °C and adding lime till a pH of 7.2-7.4 is reached. SO2 is then added to lower the pH to 5.4-5.6. Now a second portion of lime is added to again reach a pH of 7.2-7.4. Following this, the juice is heated to 103-105 °C before moving to the clarifier.
The evaporation step for plantation white is the same as that for raw sugar. At the end Sulfur dioxide (SO2) is added to lower the pH of the syrup from 6.5 to 5.5.
After evaporation, an extra clarification process can be inserted. Basic steps of this sub-process are: the addition of phosphoric acid; surface-active agents and phosphate, followed by heating and aeration of the syrup and addition of Flocculation. The syrup is then moved to a special clarifier.
The crystallization and centrifugation steps for plantation white might differ on account of the boiling system used. For plantation white the regular three-boiling system can be used. An alternative is to only ship A-Sugar. The B-sugar is then dissolved and fed back to the syrup, while the C-sugar is dissolved or used as seed for the B-sugar.
Bagasse makes a sugar mill more than energy self-sufficient; surplus bagasse goes in animal feed, in paper manufacture, or to generate electricity for sale.
There were four kinds of mills in the 1820s, those turned by wind, water, steam, or by cattle and mules. The wind mill was in wide use on Barbados. The preference for wind mills was due to their power (about 15 hp), but they required a supporting cattle-mill for when there was no wind. The machine itself consisted of three vertical rollers. Power was applied to the main (center) roller, which turned the other two by a gear.
A cattle mill on Jamaica was generally a round, covered building of no less than 60 feet diameter. Hard wood posts, or pillars of masonry supported the roof, which was mostly covered with wooden shingles. In an 1820s example, the lower four feet of the main roller were covered by a cast iron case, in the center of which was a gudgeon. This turned on a hardened piece of iron, which was set in a case-hardened iron step filled with oil. Above the cast iron case was the cogwheel, above which were the two external rollers held by braces. On the top, the main roller was driven by long levers attached to oxen walking in a roundabout.
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