Robot to which direct teaching is applied

What is claimed is: 1 . An articulated robot, comprising a base; and a manipulator having a plurality of arms serially connected with each other and mutually rotatable via an axis arranged between two arms mutually adjacent among the arms, the plurality of arms including a first arm and a leading arm, the first arm rotatably connected to the base via a first axis, the leading arm being manually gripped by an operator who operates the plurality of arms for performing direct teaching with the plurality of arms, the direct teaching being for teaching the robot movements of the plurality of arms, wherein the leading arm has a cylindrical outer surface having axial and circumferential directions, an anti-slip structure being formed i) partially on the cylindrical outer surface in an axial direction and ii) around the cylindrical outer surface in the circumferential direction, wherein the cylindrical outer surface is provided with at least one of a cable connector or a tube connector, and wherein the anti-slip structure is located on only a portion of the leading arm, the leading arm being adjacent to one of the plurality of arms, the one of the plurality of arms being adjacently and rotatably connected to the leading arm via the axis, the portion of the leading arm being adjacent and closer to the one of the plurality of arms than the at least one of the cable connector or the tube connector is. 2 . The articulated robot according to claim 1 , wherein the anti-slip structure is an unevenness of a predetermined pattern which is formed on the cylindrical outer surface in the circumferential direction. 3 . The articulated robot according to claim 1 , wherein the anti-slip structure is formed entirely around the cylindrical outer surface. 4 . The articulated robot according to claim 1 , wherein the anti-slip structure is a knurled part formed by applying knurling to the cylindrical outer surface. 5 . The articulated robot according to claim 1 , wherein the cylindrical outer surface includes a first part having a predetermined roughness level and a second part functioning as the anti-slip structure, the second part having a roughness larger than the predetermined roughness and being formed partially or entirely in the circumferential direction of the leading arm. 6 . The articulated robot according to claim 5 , wherein the second part, on which the anti-slip structure is formed, is located on an end of the leading arm in the axis direction, the end being adjacent to the arm adjacently connected to the leading arm. 7 . The articulated robot according to claim 6 , wherein the second part is located on only a portion of the leading arm, the portion being adjacent to the arm adjacently connected to the leading arm and closer to the adjacent arm than at least one of the cable connector or the tube connector. 8 . The articulated robot according to claim 6 , wherein the anti-slip structure is formed completely around the cylindrical outer surface. 9 . The articulated robot according to claim 5 , wherein the second part, on which the anti-slip structure is formed, is located on only a portion of the leading arm, the portion being adjacent to the arm adjacently connected to the leading arm and closer to the adjacent arm than at least one of the cable connector or the tube connector is. 10 . The articulated robot according to claim 5 , wherein the anti-slip structure is formed entirely around the cylindrical outer surface. 11 . The articulated robot according to claim 5 , wherein the anti-slip structure is a knurled part formed by applying knurling to the cylindrical outer surface.