Direct-current relay resistant to short-circuit current

1 . A DC relay resistant to short-circuit current, comprising two stationary contact leading-out terminals, a straight sheet type movable spring and a push rod component, in which the movable spring is mounted on the push rod component so that movable contacts on two ends of the movable spring are in contact with stationary contacts on bottom ends of the two stationary contact leading-out terminals under an action of the push rod component, and a current flows in from one of the two stationary contact leading-out terminals and flows out of the other of the two stationary contact leading-out terminals via through the movable spring, wherein upper magnetizers arranged in a width direction of the movable spring are mounted above a preset position of the movable spring; lower magnetizers arranged in the width direction of the movable spring and capable of moving with the movable spring are mounted below the preset position of the movable spring; at least one through hole is provided in the movable spring at the preset position, so that the upper magnetizers and the lower magnetizers can approach one to another or come into contact with each other through the through hole; and at least two independent magnetically conductive loops are formed in the width direction of the movable spring by means of the upper magnetizers and the lower magnetizers; magnetic pole faces of the respective magnetically conductive loops at the through hole are increased such that when the movable spring has a large fault current, attraction force in a contact pressure direction is generated to resist an electro-dynamic repulsion force generated, due to the fault current between the movable spring and the stationary contact leading-out terminals. 2 . The DC relay resistant to short-circuit current according to claim 1 , wherein the preset position is between two movable contacts in a width direction of the movable spring. 3 . The DC relay resistant to short-circuit current according to claim 1 wherein the upper magnetizers comprise at least one rectangular upper magnetizer, and the lower magnetizers comprise at least two U-shaped lower magnetizers, wherein one of the at least two U-shaped lower magnetizer and a corresponding one of the at least one rectangular upper magnetizers form an independent magnetically conductive loop, and the two U-shaped lower magnetizers are not in contact with each other. 4 . The DC relay resistant to short-circuit current according to claim 3 , wherein adjacent two U-shaped lower magnetizers share one of the rectangular upper magnetizers, the two U-shaped lower magnetizers are fitted below the corresponding one of the at least one rectangular upper magnetizers. 5 . The DC relay resistant to short-circuit current according to claim 3 , wherein rectangular adjacent two U-shaped lower magnetizers are independent from each other, the two U-shaped lower magnetizers are fitted below the corresponding rectangular upper magnetizers. 6 . The DC relay resistant to short-circuit current according to claim 3 , wherein there are two magnetically conductive loops, the movable spring is provided with one through hole, and each of the two U-shaped lower magnetizers has one side wall attached to a side in the width direction of the movable spring, and the other side wall passing through the through hole of the movable spring, and a gap is presented between the other side walls of the two U-shaped lower magnetizers. 7 . The DC relay resistant to short-circuit current according to claim 6 , wherein the other side walls of the two U-shaped lower magnetizers are arranged side by side in a width direction of the movable spring within the through hole of the movable spring, such that the two magnetically conductive loops corresponding to the two U-shaped lower magnetizers are arranged side by side in the width direction of the movable spring. 8 . The DC relay resistant to short-circuit current according to claim 6 , wherein the other side walls of the two U-shaped lower magnetizers are arranged in a staggered manner in a width direction of the movable spring within the through hole of the movable spring, such that the two magnetically conductive loops corresponding to the two U-shaped lower magnetizers are distributed in the staggered manner in the width direction of the movable spring. 9 . The DC relay resistant to short-circuit current according to claim 3 , wherein there are two magnetically conductive loops, the movable spring is provided with two through holes that are arranged side by side in a width direction of the movable spring, and each of the two U-shaped lower magnetizers has one side wall attached to a side in the width direction of the movable spring, and the other side wall fitted in one of the two through holes of the movable spring, such that the two magnetically conductive loops corresponding to the two U-shaped lower magnetizers are arranged side by side in the width direction of the movable spring. 10 . The DC relay resistant to short-circuit current according to claim 3 , wherein there are two magnetically conductive loops, the movable spring is provided with two through holes that are arranged in a staggered manner in a width direction of the movable spring, each of the two U-shaped lower magnetizers has one side wall attached to a corresponding side in the width direction of the movable spring, and the other side wall fitted to one of the two through holes of the movable spring, such that the two magnetically conductive loops corresponding to the two U-shaped lower magnetizers are arranged in a staggered manner in the width direction of the movable spring. 11 . The DC relay resistant to short-circuit current according to claim 3 , wherein there are three magnetically conductive loops, the movable spring is provided with two through holes, and three U-shaped lower magnetizers are sequentially arranged in the width direction of the movable spring, wherein the two side walls of the U-shaped lower magnetizer in the middle pass through the two through holes of the movable spring respectively, and each of the two U-shaped lower magnetizers on two sides have one side wall attached to a corresponding side of the movable spring, and the other side wall passing through one of the two through holes of the movable spring, and a gap is presented between the two sides within the same through hole in the movable spring. 12 . The DC relay resistant to short-circuit current according to claim 6 , wherein top ends of the side walls of the U-shaped lower magnetizer are substantially flush with an upper surface of the movable spring. 13 . The DC relay resistant to short-circuit current according to claim 1 , wherein the upper magnetizer is an upper armature secured to the push rod component, and the lower magnetizer is a lower armature secured to the movable spring, and the movable spring is mounted in the push rod component by a spring; when the movable contacts of the movable spring are in contact with the stationary contacts of the stationary contact leading-out terminals, a preset gap is presented between the upper armature and the lower armature. 14 . The DC relay resistant to short-circuit current according to claim 3 , wherein the upper magnetizer is an upper armature secured to the push rod component, the lower magnetizer is a lower armature secured to the movable spring, the movable spring is mounted in the push rod component by a spring, when the movable contacts of the movable spring are in contact with the stationary contacts of the stationary contact leading-out terminals, a preset gap is presented between the upper armature and the lower armature.