Device and method for sewage treatment using constant magnetic field

The invention claimed is: 1. A device for sewage treatment, comprising: a) a reactor, the reactor comprising a stirrer, an aerator, an activated sludge zone, an upper end comprising a water inlet, a side wall comprising a water outlet, a bottom comprising a sludge outlet; and b) a magnetic field generator, the magnetic field generator comprising two magnets and two iron plates; wherein: the activated sludge zone is disposed inside the reactor; the stirrer and the aerator are disposed within the activated sludge zone, and the aerator is arranged beneath the stirrer; the magnetic field generator is disposed outside the reactor; the two magnets are symmetrically disposed on two opposite sides of the reactor, the two iron plates are symmetrically disposed on the two opposite sides of the reactor, and each of the two magnets is disposed on an inner side of one of the two iron plates; and the two magnets disposed on the two opposite sides of the reactor produce magnetic fields having the same direction. 2. The device of claim 1 , wherein the magnetic field generator further comprises an upper fixed plate and a lower fixed plate; the upper and lower fixed plates are horizontally arranged with respect to the ground; an upper end and a lower end of each of the two magnets and the two iron plates are removably disposed on the upper fixed plate and the lower fixed plate, respectively; and positions of the two magnets and the two iron plates are adjustable. 3. The device of claim 2 , wherein the two magnets are permanent magnets. 4. The device of claim 3 , wherein the aerator employs jet aeration. 5. The device of claim 1 , wherein a magnetic field detector is arranged inside the reactor. 6. The device of claim 4 , wherein a magnetic field detector is arranged inside the reactor. 7. A method for sewage treatment using the device of claim 1 , the method comprising the following steps: a) filling the reactor with activated sludge to form the activated sludge zone in the bottom of the reactor; b) respectively mounting the two magnets in parallel on two opposite sides of the reactor for allowing the two magnets to form magnetic fields having the same direction in the reactor, wherein each magnet is sized to ensure the activated sludge zone to be within ranges of the magnetic fields; and respectively mounting the two iron plates outside the two magnets; c) inoculating the activated sludge at a temperature of between 4 and 15° C., introducing a simulated domestic sewage into the reactor, increasing an organic load from 0.03 kg/(m 3 ·d) to 0.8 kg/(m 3 ·d) COD at a constant gradient; jet aerating and stirring the activated sludge zone; d) allowing the reactor to work in the form of sequencing batch, domesticating the activated sludge for 10-15 d, reversing the direction of each of the two magnets on two sides of the reactor, domesticating the activated sludge for another 10-15 d, and reversing the direction of the two magnets again; and repeating the domestication for between 4 and 5 times until a COD removal rate is 80% and maintains a stable state; and e) after between 1 and 2 months of sludge domestication, introducing a domestic sewage after being filtered by a grid into the reactor, controlling the organic load at 0.4-1.0 kg/(m 3 ·d) COD; reversing the direction of the two magnets for every 10-15 d during the sewage treatment to form an intensified sewage treatment system comprising the magnetic field and microorganisms.