Method for the production of a_ fuel from waste
This invention relates to the production of a useful fuel, usable for example for steam-raising, from waste materials.
A discussion of the problems of waste disposal, and examples of methods of making use of waste materials as a fuel, are contained in British Patents 1551019 and 1551020.
The invention proposes a method for the production of fuel from waste materials comprising fermenting said waste materials in a rotating drum whereby the heat generated can so dry the materials as to prevent any further organic decomposition and thereafter pelletizing the fermented material to form the fuel.
Such a method requires the use of a pelletizer, which at first sight needs such a heavy energy input that the resultant fuel would be unecono ical ly expensive. Surprisingly, however, two highly beneficial effects are produced : first, the pelleted fuel is so much easier to handle, store and use that it is more desirable and thus more valuable; second, its water content is further reduced in pelletizing and its calorific value thus substantially enhanced.
Preferably, the process is a continuous one, rather than a batch process, and reduces the moisture content
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of the material at the exit from the composting drum to between 23 and 33%, and after the pelletizer to between 18 and 28%. The residence period in the drum is normally less than 12 hours.
In order that the invention shall be clearly understood, an exemplary embodiment thereof will now be described, with reference to the accompanying drawing which shows a process flow chart of a method according to the invention.
Waste materials for use in the process are derived from three main sources - houses (domestic waste), trade and agriculture. The proportions of each vary according to the location of the plant. Some of the waste, e.g. metal and glass, has no calorific value for the end fuel and must be removed so far as possible. At the other end of the scale, the more that organic materials, e.g. paper, wood, lastics , packaging or vegetable matter, are present, the higher the eventual calorific value of the fuel. These organic materials are preponderantly present in agricultural wastes, and may also include fibrous material e.g. husks, peelings, etc. from factories operating on agricultural products.
It can be seen that the method is therefore ideally suited to an area which is considerably agricultural but which also has a substantial urban population.
In the plant according to the invention, waste materials of all descriptions are delivered by lorry to a reception and storage area 10. It is preferred to be able to marshal the waste to produce an even mixture of all the different kinds, if this is not achieved without intervention. From area 10, the waste is
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passed to a powerful shredder 11, possibly in the form of a hammer mill. In this case, no pre-sorting of the waste is needed; only the very heaviest individual lumps e.g. engine blocks, need to be removed. All other waste will be isintegrated to less than 100 mm particle size, with 98% less than 50mm.
From the shredder the waste passes to a large volume intermediate store 12. This has two major functions. First, it serves as a buffer for smoothing out variations in supply of waste e.g. at weekends, and ensures continuous operation of the fermentation drum. Second, when simply piled, the shredded waste, which may have a total moisture content (i.e. free or surface moisture, plus internal moisture) in the region of 38% (the range may be 30 to 60%), can start anaerobic spontaneous fermentation with a consequent temperature rise. In fact, under suitable ambient conditions, its temperature can rise before it enters the fermentation drum to the operating temperature of the drum, i.e. 70 to 80°C. Thus, no heat and no extra water needs to be injected into the drum.
The shredded waste is moved by conveyor and/or hopper into the drum 13.
The drum may typically have a length of βOm and a diameter of 4.5m. Its function is to ferment and dry the raw shredded waste. The drum will process on a continuous basis a charge of about 300 tonnes. This will represent a charging rate of about 40 tonnes/hour and a discharge rate of about 30 tonnes/hour, the balance being the water removed. The charge will take between 6 and 12 hours to pass through, the average residence time being in the region of 9 hours and being
adjustable according to the charging rate by varying its speed of rotation so as to produce the dryest product possible. A forced air draught is passed through a drier 14 and then in countercurrent through the drum. It is important that the air passed through the drum should be dry, since this maximises the amount of water which can be removed and the effiency of the drying process in the drum. The air both removes the moisture released from the waste material, and assists the aerobic fermention. The latter serves to both further break down the waste, and to generate the heat necessary to drive off the water. The water content can be reduced from its starting figure to one in the region of 23 to 25% (by weight) at the drum exit. In fact, it cannot go below the lower figure because the conditions for fermentation cease to exist, and thus heat generation and further dewatering cease.
At this stage the waste matter has been reduced to a particle size of less than 50 mm. with 90% less than 20mm. However, it still contains both metal and glass, which must now be removed in one or more separators 15. It is a positive advantage that this mineral waste is present in the drum, since it assists considerably in further reducing the particle size while the fermentation 'stage is proceeding. these may be magnetic (for ferrous metal) or gravity (for all heavy fractions). The latter type of separator can be very effective in respect of the waste matter now involved, since the really valuable fibrous waste for the fuel is inevitably very much less dense than all the rest. The metal extracted can obviously be baled and sold as scrap. The nature and amount of the remaining mineral solids, will vary enormously dependant upon the plant location, and must be disposed
of as appropriate - possibly as land-fill aggregate.
It is important to remove these solid mineral fractions, since they can otherwise cause excessive wear and damage to the pelletizer 16 which follows.
This is a conventional piece of apparatus, but its use in the present invention is important and surprisingly advantageous. In a typical application, it is used to produce extruded pellets of largely fibrous matter 75 mm length x 18 mm diameter. A considerable energy input (approximately one third of the process total energy, is required to the pelletizer to produce the compaction, but this process has the additional effect that the friction involved generates considerable heat and this is sufficient to reduce the water content of the waste by a further 5%, i.e. to between 18 and 23%.
In fact, the waste in the form it leaves the separators 15 is ideally suited for pelleting, since it has consistent, fibrous characteristics, without abrasive content, and of suitable moisture level. In turn, the pellets are a much more satisfactory fuel product than the loose waste produced by known processes. They can be burnt in conventional boilers, without admixture of coal, and because they are compacted with a smooth outer surface they are m-uch less hygroscopic than the loose fuel. Thus, there is less danger of renewed fermentation with production of noxious liquors and smells. Therefore, the pellets can be stored virtually indefinitely without deterioration (instead of requiring to be burnt immediately), and are easier to handle and require smaller storage space. They are also cheaper to transport.
In the integrated plant described, they are passed to
storage 17 and from there as required directly to a boiler 18. This boiler can be used to produce hot water, steam, or electricity, normally without any additional fuel. Its residue of ash is approximately 17% of the dry weight of the original fuel, rather less relative to the actual weight. The ash is also saleable as aggregate.
This process and plant, is designed for use in an area having a relatively high agricultural/fibrous waste input, and not too high a proportion of dense solids. It also runs at its most economical with a high ambient temperature, such as -exists in, for example, African countries. Samples of typical waste in a central African city gave figures of around 23% paper and cardboard, 60% putrescibles (i.e. vegetable and other organic waste), the remainder being plastics, textiles, metal, glass, etc. It is calculated that a plant handling 200 tonnes of this waste can produce a steam output of 3.633 x 10 KCal at a heat efficiency overall of about 70%. Such an outcome for what is in fact at the same time and primarily a comprehensive waste disposal system must be regarded as highly satisfactory.
In other areas and climates, certain modifications may be required. These would mainly concern the intermediate storage 12, and. the separators 15. In colder climates, it may not be sufficient simply to pile the waste to initiate fermentation, so that a second smaller fermentation drum may be required, possibly with some heat input. However, it is believed that otherwise the process could proceed as described. With more heavy industrial waste, more or different separators may be required. Moreover, the
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energy input to the shredder is higher the less water is present in the waste mate ials,so that overall the heat efficiency of the system may be lower. But the system is still capable of operating on unsorted waste and continuously.
In certain circumstances, in order to maintain the throughput of the continuous process, by reducing what would be an uneconomically long residence time in the drum, it may be advisable or necessary to inject heat into the drum. This can be achieved by using the drier 14 to heat the air as well. The aim would be to achieve an optimum 70 to 80°C in the drum.
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