Dynamic inwardly eccentrically-placed directional drill bit type rotation guidance apparatus

1 . A rotation guidance apparatus, comprising an upper connector and a lower connector which are connected to each other, wherein an end part of the lower connector has a ball-socketed ball-joint rod, a drill bit which is connected to the ball-socketed ball-joint rod; several circumferentially evenly distributed piston holes that are provided in a side wall of the lower connector, a piston which matches each of the piston holes, a piston rod connected to the piston being movably connected to the ball-socketed ball-joint rod; an eccentrically-placed valve core connected to a controller provided in the upper connector, a working face of the eccentrically-placed valve core being opposite to the piston holes, wherein rotation of the eccentrically-placed valve core makes the pistons in the piston holes move to control the rotation guidance of the ball-socketed ball-joint rod. 2 . The rotation guidance device of claim 1 , wherein the eccentrically-placed valve core is of an analogous conical structure, a cone surface of the eccentrically-placed valve core is provided with a concave part and a convex part, and when the eccentrically-placed valve core rotates, the concave part and the convex part are aligned to the piston holes respectively. 3 . The rotation guidance apparatus of claim 1 , wherein one end of the ball-socketed ball-joint rod is configured into a spherical structure which may be matched with the end part of the lower connector by adopting a spherical surface to form a ball-joint structure, such that the ball-socketed ball-joint rod may rotate relative to the lower connector by taking the ball-joint structure as a center, wherein the ball-socketed ball-joint rod is communicated with a central through hole of the lower connector to each other, a spline disc head is sheathed outside the middle part of the ball-socketed ball-joint rod, and the piston rod which matches each piston hole is movably connected to the spline disc head. 4 . The rotation guidance apparatus of claim 3 , wherein a large ball joint gland connected to the lower connector is sheathed outside the ball-joint structure; a gland nut for limiting the spline disc head is sheathed outside the middle part of the ball-socketed ball-joint rod; an anti-drop connector sheathed outside the ball-socketed ball-joint rod is connected to one end, close to the drill bit, of the lower connector, and the minimum drift diameter of the anti-drop connector is greater than the outer diameter of the spline disc head. 5 . The rotation guidance apparatus of claim 3 , wherein one end of each piston rod is ball-socketed to the spline disc head, a piston rod upper sealing packing is provided at the other end of the piston rod to form the piston, and the piston rod may drive the piston rod upper sealing packing to move relative to the piston holes; and a piston rod lower sealing packing which may move in a relative sealing manner is sheathed outside the piston rod, and is fixed to the lower connector. 6 . The rotation guidance apparatus of claim 1 , wherein an accommodating groove which is communicated with the piston hole is provided in a position, in the middle of each piston hole, of the lower connector, and a hydraulic bag is provided inside the accommodating groove and is sealed in the accommodating groove via a hydraulic bag gland. 7 . The rotation guidance apparatus of claim 1 , wherein a central hole for accommodating a controller is provided in the middle of the upper connector, several bypass holes which are located in the same circumference are provided in a side wall of the upper connector, and the bypass holes, a central through hole of the lower connector and a central through hole of the ball-socketed ball-joint rod are communicated correspondingly to form a channel, and the eccentrically-placed valve core is located in a region, where the lower connector and the upper connector are connected, inside the channel. 8 . The rotation guidance apparatus of claim 7 , wherein the controller comprises a rotating motor and a dragging motor which are located on the same axis inside the center hole; the eccentrically-placed valve core is provided at one end of an eccentrically-placed valve rod, the other end of the eccentrically-placed valve rod is connected to the rotating motor through a transmission shaft I, and the rotating motor is connected to the dragging motor through a transmission shaft II; and a control module is placed in a region, wherein a groove is formed, on the side wall of the upper connector, and the rotating motor and the dragging motor are connected to and controlled by the control module respectively. 9 . The rotation guidance apparatus of claim 8 , wherein a motor sleeve I and a motor support are provided in the central hole; the rotating motor is clamped inside the motor sleeve I, and bumps which are provided outside the motor sleeve I match a motor sleeve sliding groove in an inner wall of the central hole, such that the motor sleeve I may slide relative to the central hole; and a motor sleeve end cover I is provided at a tail part of the motor sleeve I and matches the transmission shaft II through threads, and the transmission shaft II is connected to the dragging motor provided inside a motor sleeve II. 10 . The rotation guidance apparatus of claim 2 , wherein one end of the ball-socketed ball-joint rod is configured into a spherical structure which may be matched with the end part of the lower connector by adopting a spherical surface to form a ball-joint structure, such that the ball-socketed ball-joint rod may rotate relative to the lower connector by taking the ball-joint structure as a center, wherein the ball-socketed ball-joint rod is communicated with a central through hole of the lower connector to each other, a spline disc head is sheathed outside the middle part of the ball-socketed ball-joint rod, and the piston rod which matches each piston hole is movably connected to the spline disc head. 11 . The rotation guidance apparatus of claim 2 , wherein an accommodating groove which is communicated with the piston hole is provided in a position, in the middle of each piston hole, of the lower connector, and a hydraulic bag is provided inside the accommodating groove and is sealed in the accommodating groove via a hydraulic bag gland. 12 . The rotation guidance apparatus of claim 4 , wherein an accommodating groove which is communicated with the piston hole is provided in a position, in the middle of each piston hole, of the lower connector, and a hydraulic bag is provided inside the accommodating groove and is sealed in the accommodating groove via a hydraulic bag gland. 13 . The rotation guidance apparatus of claim 5 , wherein an accommodating groove which is communicated with the piston hole is provided in a position, in the middle of each piston hole, of the lower connector, and a hydraulic bag is provided inside the accommodating groove and is sealed in the accommodating groove via a hydraulic bag gland. 14 . The rotation guidance apparatus of claim 2 , wherein a central hole for accommodating a controller is provided in the middle of the upper connector, several bypass holes which are located in the same circumference are provided in a side wall of the upper connector, and the bypass holes, a central through hole of the lower connector and a central through hole of the ball-socketed ball-joint rod are communicated correspondingly to form a channel; and the eccentrically-placed valve core is located in a region, where the lower connector and the upper connector are connected, inside the channel. 15 . The rotation guidance apparatus of