Opening maching apparatus for heat transfer tube, method of forming opening in tube wall of heat transfer tube using same, and method of removing foreign material through same opening of same heat transfer tube

What is claimed is: 1 . A method of machining an opening in a tube wall of a heat transfer tube, the method comprising: inserting an electric discharge machining device connected to an electric discharge machining transport device to form an opening in the tube wall of the heat transfer tube; moving the electric discharge machining device inserted into the heat transfer tube to a target site in which the opening is to be formed by using the electric discharge machining transport device; rotating the electric discharge machining device moved to the target site using an electric discharge machining device rotation device and bringing the electric discharge machining device into contact with the tube wall of the heat transfer tube using an electric discharge machining device driving device; and forming an opening in the tube wall of the heat transfer tube by using the electric discharge machining device in contact with the tube wall of the heat transfer tube, wherein the electric discharge machining device comprises: a housing having a through hole extending in a radial direction, inserted into the heat transfer tube, and extending in a longitudinal direction of the heat transfer tube; a discharge body disposed in the housing, movably disposed through the through hole, and provided with a discharge electrode on a first surface facing the tube wall surface of the heat transfer tube; an operating shaft disposed in the housing, moved in a longitudinal direction of the housing by the electric discharge machining device driving device, and configured to move the discharge body to the outside through the through hole; and a dielectric supply member disposed in the housing and configured to supply a dielectric to the discharge electrode of the discharge body. 2 . The method according to claim 1 , wherein a second surface of the discharge body in contact with the operating shaft is inclined to have a downward inclination in a direction in which the operating shaft moves, and a first end of the operating shaft in contact with the second surface of the discharge body has an inclined surface corresponding to the inclined second surface of the discharge body. 3 . The method according to claim 2 , wherein the discharge electrode is provided on the first surface of the discharge body to protrude from the first surface, and the discharge electrode is provided on an entire surface of the first surface to be in contact with the tube wall surface of the heat transfer tube for surface machining. 4 . The method according to claim 2 , wherein the discharge electrode is provided on the first surface of the discharge body to protrude from the first surface, and the discharge electrode is provided at an upper portion and a lower portion of the first surface to be in contact with the tube wall surface of the heat transfer tube for linear machining. 5 . The method according to claim 1 , wherein the electric discharge machining transport device comprises: a first transport member provided at a front end of the electric discharge machining device; a first joint member rotatably connecting the first transport member and the electric discharge machining device; a second transport member provided at a rear end of the electric discharge machining device; a second joint member rotatably connecting the second transport member and the electric discharge machining device; and a connection cable transmitting force to move the second transport member. 6 . The method according to claim 5 , wherein the first transport member comprises a first body connected to the electric discharge machining device by the first joint member and a plurality of first support rings rotatably mounted on the first body and protruding from a surface of the first body to be in contact with an inner circumferential surface of the heat transfer tube, and wherein the second transport member comprises a second body connected to the electric discharge machining device by the second joint member and a plurality of second support rings rotatably mounted on the second body and protruding from a surface of the second body and configured to be in contact with the inner circumferential surface of the heat transfer tube. 7 . The method according to claim 1 , wherein the electric discharge machining device driving device comprises: a connection rod having a first end connected to the operating shaft via the electric discharge machining transport device; and a connection rod moving device connected to a second end of the connection rod to provide force for moving the connection rod back and forth. 8 . The method according to claim 7 , wherein the electric discharge machining device rotation device comprises: a connection rod attachment member in contact with a circumferential surface of the connection rod; and a connection rod rotation member connected to the connection rod attachment member to provide force for rotating the connection rod attachment member. 9 . The method according to claim 1 , further comprising: removing the electric discharge machining device connected to the electric discharge machining transport device from an inside of the heat transfer tube after the opening is formed; and inserting a foreign material removal tool into the heat transfer tube with the opening, drawing a foreign material disposed outside the heat transfer tube into the inside of the heat transfer tube, and discharging the foreign material to an outside of the heat transfer tube. 10 . The method according to claim 9 , wherein the foreign material removal tool comprises: gripping forceps configured to grip the foreign material; a moving shaft connected to the gripping forceps to move the gripping forceps; a manipulation handle connected to the gripping forceps and operated by an operator to rotate the gripping forceps so that the gripping forceps grasp the foreign material; a camera provided on the gripping forceps for capturing an image of a moving path of the gripping forceps; and a monitor connected to the camera and configured to check the moving path using the image captured by the camera. 11 . An apparatus that performs the method of claim 10 , the apparatus comprising: an electric discharge machining device inserted into the heat transfer tube and configured to form the opening in the tube wall of the heat transfer tube through the electric discharge; an electric discharge machining transport device connected to the electric discharge machining device and configured to transport the electric discharge machining device; an electric discharge machining device driving device connected to the electric discharge machining device and configured to provide force for bringing the electric discharge machining device into contact with a tube wall surface of the heat transfer tube; and an electric discharge machining device rotation device configured to provide force for rotating the electric discharge machining device in a circumferential direction of the heat transfer tube in the heat transfer tube, wherein the electric discharge machining device comprises: a housing having a through hole extending in a radial direction, inserted into the heat transfer tube, and extending in a longitudinal direction of the heat transfer tube; a discharge body disposed in the housing, movably disposed through the through hole, and provided with a discharge electrode on a first surface facing the tube wall surface of the heat transfer tube; an operating shaft disposed in the housing, moved in a longitudinal direction of the housing by the electric discharge machining device driving device, and configured to move the discharge body to the outsi