Electromagnetic-force-based dewatering for sewage sludge reduction

We claim: 1. An apparatus comprising: a front-end auxiliary filter plate; a back-end auxiliary filter plate; a plurality of filter plate modules disposed between the front-end auxiliary filter plate and the back-end auxiliary filter plate, wherein each of the filter plate modules includes a middle main filter plate, a middle auxiliary filter plate, and a plurality of electromagnetic modules comprising an electromagnetic coil wound around an electromagnetic core, the middle main filter plate and the middle auxiliary filter plate are disposed at opposite sides of the electromagnetic modules, the middle main filter plates of the plurality of filter plate modules face the front-end auxiliary filter plate and the middle auxiliary filter plate of the plurality of filter plate modules face the back-end auxiliary filter plate and there is a consistent one-to-one match between the main filter plates and the auxiliary filter plates that form a plurality of filter chambers into which sewage sludge enters via sludge inlet pipes; wherein the outer side of the front-end auxiliary filter plate and the inner side of the back-end auxiliary filter plate are each provided with the plurality of electromagnetic modules; and wherein an electric current is applied to the electromagnetic coil, attracting the middle auxiliary filter plates and the main filter plates and applying pressure to the sewage sludge. 2. The apparatus of claim 1 , wherein the front-end auxiliary filter plate, the middle main filter plates, the middle auxiliary filter plates and the back-end auxiliary filter plate are connected via a link mechanism and can achieve a linkage motion under electromagnetic force. 3. The apparatus of claim 2 , wherein the link mechanism comprises main connecting rods and auxiliary connecting rods, the main connecting rods are disposed on the rotating shafts of the middle auxiliary filter plates in the odd positions, the auxiliary connecting rods are disposed on the rotating shafts of the middle auxiliary filter plates in the even positions, and the main and auxiliary connecting rods are connected by hinge. 4. The apparatus of claim 3 , wherein the middle auxiliary filter plate in the odd positions is provided with a retention device, and the retention device comprises an electromagnetic core of limit block, an electromagnetic coil of limit block, a spring baffle, a reset spring, a sliding rail and a sliding block, wherein the sliding rail is fixed on the middle filter plate so that the extended sliding block accurately limits the angle of rotation of the main connecting rod, indirectly limiting the distance between the middle auxiliary filter plate and the middle main filter plate, wherein the electromagnetic core of limit block is fixed on the sliding block, the spring baffle is fixed on the sliding rail, and the reset spring withdraws the sliding block within the sliding rail. 5. The apparatus of claim 4 , wherein the back of the sliding block is magnetic, and in response to the coil of limit block being energized, the back of the sliding block moves within the sliding rail, the reset spring is compressed, and the front end of the sliding block extends out to stop the main connecting rod. 6. The apparatus of claim 1 , wherein each of the outer rings of the middle main filter plates is provided with a seal ring, and a reinforced substrate cloth and a filter cloth are disposed in turn on the middle main filter plate from interior to exterior. 7. The apparatus of claim 1 , wherein a plurality of intake branch pipes is connected with the intake main pipe, the plurality of intake branch pipes is correspondingly connected with the plurality of the filter chambers so that the high-pressure gas from intake branch pipes enters the corresponding filter chambers. 8. The apparatus of claim 1 , wherein drainpipes for discharging the filtered water are disposed on the front-end auxiliary filter plate and each of the middle main and auxiliary filter plates. 9. The apparatus of claim 1 , further comprising a dust collector that absorbs and removes sludge dust via negative pressure. 10. A system comprising: a front-end auxiliary filter plate; a back-end auxiliary filter plate; a plurality of filter plate modules disposed between the front-end auxiliary filter plate and the back-end auxiliary filter plate, wherein each of the filter plate modules includes a middle main filter plate, a middle auxiliary filter plate, and a plurality of electromagnetic modules comprising an electromagnetic coil wound around an electromagnetic core, the middle main filter plate and the middle auxiliary filter plate are disposed at opposite sides of the electromagnetic modules, the middle main filter plates of the plurality of filter plate modules face the front-end auxiliary filter plate and the middle auxiliary filter plate of the plurality of filter plate modules face the back-end auxiliary filter plate and there is a consistent one-to-one match between the main filter plates and the auxiliary filter plates that form a plurality of filter chambers; a high-pressure pump that pumps sewage sludge into the filter chambers via sludge inlet pipes; wherein the outer side of the front-end auxiliary filter plate and the inner side of the back-end auxiliary filter plate are each provided with the plurality of electromagnetic modules; wherein an electric current is applied to the electromagnetic coil, attracting the middle auxiliary filter plates and the main filter plates and applying pressure to the sewage sludge; and a high-pressure sludge inlet pump that pumps high-pressure gas through air inlets and through holes on the main filter plates and auxiliary filter plates via intake branch pipes to blow away sludge cakes. 11. The system of claim 10 , wherein the front-end auxiliary filter plate, the middle main filter plates, the middle auxiliary filter plates and the back-end auxiliary filter plate are connected via a link mechanism and can achieve a linkage motion under electromagnetic force. 12. The system of claim 11 , wherein the link mechanism comprises main connecting rods and auxiliary connecting rods, the main connecting rods are disposed on the rotating shafts of the middle auxiliary filter plates in the odd positions, the auxiliary connecting rods are disposed on the rotating shafts of the middle auxiliary filter plates in the even positions, and the main and auxiliary connecting rods are connected by hinge. 13. The system of claim 12 , wherein the middle auxiliary filter plate in the odd positions is provided with a retention device, and the retention device comprises an electromagnetic core of limit block, an electromagnetic coil of limit block, a spring baffle, a reset spring, a sliding rail and a sliding block, wherein the sliding rail is fixed on the middle filter plate so that the extended sliding block accurately limits the angle of rotation of the main connecting rod, indirectly limiting the distance between the middle auxiliary filter plate and the middle main filter plate, wherein the electromagnetic core of limit block is fixed on the sliding block, the spring baffle is fixed on the sliding rail, and the reset spring withdraws the sliding block within the sliding rail. 14. The system of claim 13 , wherein the back of the sliding block is magnetic, and in response to the coil of limit block being energized, the back of the sliding block moves within the sliding rail, the reset spring is compressed, and the front end of the sliding block extends out to stop the main connecting rod. 15. The system of claim 10 , wherein each of the outer rings of the middle main filter pla