The present invention relates to a method and devices for processing and drying moist organic waste. Organic wastes are moist sludge separated from sewage, moist organic matter separated from municipal garbage and moist manure from animal growing facilities. The organic wastes are wet, in most cases, have undesired smell and pollute the ground and ground water by leached water from them. The wastes have nutrients good for agricultural crops and can save fertilizers as well as being used as energy source. The organic wastes need some biochemical and/or drying process to be able to being spread in agricultural fields, which is the preferred use of them, or being used as an energy source.
Several manufacturers are drying sludge under transparent cover in batches, using rotary machines, powered by vehicles, to break the crust on the surface and aerate the surface of the sludge with the aid of fans to enhance the drying process.
It is an object of the invention to provide a method and devices for chemical processing and/or drying the waste in a continuous process, while using mainly solar energy for heating the waste and the air being used to take the vapors away. In order to dry the waste quickly, the contact area of the waste with the drying air is enlarged by cutting lumps of waste and throwing them up to the flowing air by rotary tillers, which is different from the known methods on the market. Another possibility to enlarge the contact area is by pressing air through the waste from holes in the floor or other surfaces in contact like a dragging blade. The biochemical processing by adding materials to the waste can be done at any point along the drying process. The dry waste coming out of the process will be ready for being spread in agricultural fields without polluting the soil or water, but saving fertilizers, or being used as energy source.
The invention provides a method for processing and or drying organic wastes in a continuous process, while using mainly solar energy, direct or indirect, and large surface area of waste in contact with the drying air for the process. The surface area is enlarged by cutting lumps and throwing them up in the drying air by rotary tillers, and/or pressing air through the waste from holes in the floor or other surfaces in contact. The wastes to be processed may be moist sludge from sewage treating facilities, moist organic municipal garbage or moist animal's manure. The process starts with heaps of wet waste being dumped from trucks on to a slow moving feeder. The biochemical process, if needed, takes place at this point or at the end of the drying process. At the end of the feeder a rotary pulverizer-feeder feeds the drying area with a continuous flow of wet waste.
In a preferred embodiment the aerating means and continuous flow of waste are rotary tillers, which pulverize the waste and throw lumps up into the drying air and directing it to fall backward to its place, while moving forward or forward in the moving direction, while moving back, until the dry waste reaches the unloading pit.
In a preferred embodiment the rotary tillers are powered by electric motors on them, connected to the electric source by stretched cables.
In another preferred embodiment the rotary tillers are powered by electric motors on them, connected to the electric source by cables rolled on a reel.
In another preferred embodiment the rotary tillers are powered by hydraulic motors on them, connected to the hydraulic pump by hoses rolled on a reel.
In another preferred embodiment the rotary tillers are powered by hydraulic motors on them, connected to the hydraulic pump by stretched hoses.
In another preferred embodiment the rotary tillers are powered by electric motor via drugging chains and sprockets engaged to linear gear-rods at the side walls.
In another preferred embodiment the rotary tillers are powered by electric motor via drugging chains and road wheels and gear boxes
In another preferred embodiment the rotary tillers are powered by internal combustion engine.
In another preferred embodiment the continuous flow of waste is performed by a dragging conveyor which pulls the waste from the feeding point along the drying chamber in relation to the tillers. The waste is being aerated and heated while being moved along the drying chamber. The dried waste, at the end of the dragging conveyor, enters a pit with loading facilities.
In another preferred embodiment the continuous flow of waste is performed by a rotary tiller throwing lumps of waste upward and forward and being moved by powered wheels.
In another preferred embodiment the continuous flow of waste is performed by a vibrating conveyor with floating air jets coming out of the floor. The floating air jets, which move through the sludge, are used also for the aerating and drying process by using the large area of contact.
The heating preferred embodiment is a transparent cover over the whole system, using the solar energy to heat the waste directly or in combination of air solar-heaters.
In another preferred embodiment the heating system is a floor with imbedded pipes in which hot water are flowing through.
In another preferred embodiment the aerating means are dry air jets flowing out of the dragging blades or from the floor under the conveyor.
In another preferred embodiment the aerating means are fans for circulating the air above the waste and through the moving and flowing lumps of waste.
The drying process is preferred to be controlled by a computerized control system, using sensors to measure the different parameters like the flow-rate of the waste by laser sensors, the temperatures of the waste, the air, the floor etc. by infra red cameras at different points. Measuring the energy usage by monitoring the electricity usage. Monitoring the water content of the waste at different points by measuring the moisture of samples. Sensors to measure the number of revolutions of the tillers, the forward or backward velocity of the tillers and any other parameter as needed. The measured data is transferred to the main computer by cables or wire-less communication. The system can be automatically or manually controlled by a remote computer which collects the processed data from the main computer and presenting it in tables and graphs. The system will be able to control the flow rate of the waste and the function of all the systems affecting the results of the drying process, like the number of revolutions of the tiller, the linear velocity of it, the flow rate of the feeder and the operation of the air fans. The control system will alarm in different ways for any undesired results in the drying process.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2008/008842 | 7/21/2008 | WO | 00 | 1/13/2010 |
Number | Date | Country | |
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60961159 | Jul 2007 | US |