Low energy drying of swine lagoon sludge or digestate

The invention claimed is: 1. A waste drying system, the system comprising: a trough comprising: a hopper configured to receive a bulk waste product; and an extruder configured to extrude the bulk waste product in a form of an extruded waste product that is suitable for convective drying, wherein the trough defines a first end of the system; a housing comprising a first opening, which is at a boundary of the housing with an external environment comprising ambient air, and a second opening; one or more conveyors having an air-permeable conveyor belt, each conveyor being positioned in the second opening and configured to receive the extruded waste product from the trough for transport along a path from the first end of the system to a second end of the system, wherein the second end of the system is at an opposite end of the conveyors from the first end of the system; and one or more air moving devices (AMDs) mounted in the first opening and configured to pull the ambient air from the external environment into the housing, at the first opening, and to exhaust the ambient air from the housing through the air-permeable conveyor belt, at the second opening, and across the extruded waste product while being transported on the air-permeable conveyor belt along the path from the first end of the system to the second end of the system; wherein the system is configured to transform the extruded waste product into a dried waste product having a moisture content of about 5% to about 20%, inclusive, without use of any heat source for heating the ambient air during transport of the extruded waste product from the first end of the system to the second end of the system, wherein the one or more conveyors comprise a first conveyor and second conveyor and the one or more AMDs comprise a first AMD and a second AMD, the system comprising: a first drying stage comprising the first conveyor and the first AMD; a second drying stage comprising the second conveyor and the second AMD; and a controller configured to simultaneously and independently control the first and second drying stages to coordinate a transport speed of the extruded waste product along the air-permeable conveyor belt of the first and second conveyors, respectively, as well as a flow of the ambient air produced by each of the first and second AMDs. 2. The system of claim 1 , wherein: the extruder comprises a series of extrusion ports in at least one side of the hopper, and a rotatable member with one or more paddles configured to rotate about an axis and force the bulk waste product through the series of extrusion ports; or the extruder comprises a screw style in a tube. 3. The system of claim 2 , wherein the extruder extends transversely along one end of the air-permeable conveyor belt of the first conveyor and extends substantially across a width thereof. 4. The system of claim 3 , wherein the extruder is configured to continuously extrude the bulk waste product contained within the hopper onto the air-permeable conveyor belt of the first conveyor in a substantially even layer while the air-permeable conveyor belt of the first conveyor is in motion. 5. The system of claim 1 , wherein the first conveyor comprises a physical agitator configured to remove the extruded waste product, in a form of a partially dried waste product, from the air-permeable conveyor belt of the first conveyor, such that the partially dried waste product accumulates on a transport belt configured to transport the partially dried waste product from the first conveyor to the second conveyor. 6. The system of claim 5 , wherein the air-permeable conveyor belt of the second conveyor is configured to advance at a slower rate of speed than the air-permeable conveyor belt of the first conveyor, such that the partially dried extruded waste product accumulates on the air-permeable conveyor belt of the second conveyor at a thicker depth than a depth of the extruded waste product on the air-permeable conveyor belt of the first conveyor. 7. The system of claim 1 , wherein each air-permeable conveyor belt comprises a mesh, metal, fabric, textile, chain, interlocking, or otherwise linked material with sufficient rigidity to hold and transport the extruded waste product on an upper surface thereof, while being sufficiently flexible or bendable to track along a continuous revolving path. 8. The system of claim 1 , wherein each air-permeable conveyor belt comprises a metal, metal alloy, fabric or textile, plastic, and/or composite. 9. The system of claim 1 , wherein each air-permeable conveyor belt comprises a plurality of perforations, holes, or openings extending from a lower surface of the air-permeable conveyor belt to an upper surface of the air-permeable conveyor belt, the perforations, holes, and/or openings being sufficiently large to allow air from the first AMD or the second AMD to pass through the perforations, holes, or openings and contact the extruded waste product transported thereon. 10. The system of claim 1 , wherein the first AMD and the second AMD are positioned proximate to and/or below the air-permeable conveyor belts of the first conveyor and the second conveyor, respectively, wherein the first AMD and the second AMD are configured to produce a flow of the ambient air that contacts the extruded waste product on the surface of the respective air-permeable conveyor belt. 11. The system of claim 1 , wherein the trough, the air-permeable conveyor belts of the first conveyor and the second conveyor, and the first AMD and the second AMD are powered by one or more electric motors configured to provide sufficient power to each, wherein the one or more electric motors are controlled by the controller configured to simultaneously control each of the one or more electric motors such that each of the trough, the air-permeable conveyor belts of the first conveyor and the second conveyor, and the first AMD and the second AMD are configured for simultaneous operation. 12. The system of claim 1 , wherein the housing is configured to direct a flow of the ambient air from the first AMD and the second AMD in the first opening through the respective air-permeable conveyor belts positioned in the second opening. 13. The system of claim 1 , comprising a receptacle at the second end of the system, wherein the receptacle is configured to collect the extruded waste product in a form of a dried waste product. 14. A method of processing and drying a waste product, the method comprising: providing a waste drying system according to claim 1 ; providing the bulk waste product into the hopper of the trough; extruding, using the extruder, the bulk waste product, in a form of an extruded waste product, over the air-permeable conveyor belt of the first conveyor; transporting the extruded waste product along the air-permeable conveyor belt of the first conveyor; passing, via the first AMD, the ambient air from the external environment through the air-permeable conveyor belt of the first conveyor while the extruded waste product is being transported along the air-permeable conveyor belt of the first conveyor; transporting the extruded waste product from the air-permeable conveyor belt of the first conveyor to the air-permeable conveyor belt of the second conveyor; passing, via the second AMD, the ambient air from the external environment through the air-permeable conveyor belt of the second conveyor while the extruded waste product is being transported along the air-permeable conveyor belt of the second conveyor; and reducing a moisture content of the bulk waste product to produce a dried waste product. 15. The meth