Gas circuit breaker

What is claimed is: 1. A gas circuit breaker comprising: a filling container which is filled with an insulating gas having an arc-extinguishing property; a driving-side main conductor which is supported and fixed by an insulating support tube disposed inside the filling container, and is connected to a driving-side lead-out conductor connected to an electric power system, and has an exhaust hole configured to exhaust the insulating gas whose temperature and pressure have been increased by an arc generated during breaking; an exhaust shaft which is provided inside the driving-side main conductor so as to be movable in an axial direction of the driving-side main conductor and has a shaft exhaust hole configured to exhaust the insulation gas whose temperature and pressure have been increased; an operating mechanism which is connected to the exhaust shaft and outputs an operating force in an axial direction of the exhaust shaft via an operation rod; a cylinder which is coaxially coupled to the exhaust shaft and is axially slidable on an inner peripheral surface of the driving-side main conductor; a puffer piston which is fixed inside the driving-side main conductor, and has an opening in the axial direction of the driving-side main conductor, and allows the exhaust shaft to be slidable on an inner peripheral surface of the opening; a driving contact which is electrically connected to the cylinder and the driving-side lead-out conductor; and a driven contact which is electrically connected to a driven-side lead-out conductor and is connectable and disconnectable to and from the driving contact, the driven-side lead-out conductor being connected to the electric power system, wherein: the driving contact has a driving-side main contact, an insulating nozzle, and a driving-side arc contact, the driven contact has a driven-side main contact and a driven-side arc contact, the driving-side arc contact is connected to the operating mechanism, the driven-side arc contact is coupled to a bidirectional drive mechanism section, the bidirectional drive mechanism section includes a driving rod to receive a driving force from the driving-side main contact, a coupling member coupling the insulating nozzle and the driving rod, and a coupling mechanism to operate the driven-side arc contact in an opposite direction with respect to an operation of the driving rod, the insulating nozzle is disposed so as to cover an inner surface of the coupling member such that an end surface of the coupling member and an end surface of the insulating nozzle form one surface, in order to suppress contact between a high-temperature and high-pressure gas generated by the arc and the coupling member, and the insulating nozzle and the coupling member are coupled by engaging a nozzle coupling portion, which is provided on and protruding from an outer periphery of the insulating nozzle, with a cutout portion formed on an end surface opposite to the end surface of the coupling member and by fixing an engagement portion therebetween with a locking member from an axial direction. 2. The gas circuit breaker according to claim 1 , wherein a space is formed on an inner peripheral surface of the coupling member so as to face an outer peripheral surface of the insulating nozzle. 3. A gas circuit breaker comprising: a filling container which is filled with an insulating gas having an arc-extinguishing property; a driving-side main conductor which is supported and fixed by an insulating support tube disposed inside the filling container, and is connected to a driving-side lead-out conductor connected to an electric power system, and has an exhaust hole configured to exhaust the insulating gas whose temperature and pressure have been increased by an arc generated during breaking; an exhaust shaft which is provided inside the driving-side main conductor so as to be movable in an axial direction of the driving-side main conductor and has a shaft exhaust hole configured to exhaust the insulation gas whose temperature and pressure have been increased; an operating mechanism which is connected to the exhaust shaft and outputs an operating force in an axial direction of the exhaust shaft via an operation rod; a cylinder which is coaxially coupled to the exhaust shaft and is axially slidable on an inner peripheral surface of the driving-side main conductor; a puffer piston which is fixed inside the driving-side main conductor, and has an opening in the axial direction of the driving-side main conductor, and allows the exhaust shaft to be slidable on an inner peripheral surface of the opening; a driving contact which is electrically connected to the cylinder and the driving-side lead-out conductor; and a driven contact which is electrically connected to a driven-side lead-out conductor and is connectable and disconnectable to and from the driving contact, the driven-side lead-out conductor being connected to the electric power system, wherein: the driving contact has a driving-side main contact, an insulating nozzle, and a driving-side arc contact, the driven contact has a driven-side main contact and a driven-side arc contact, the driving-side arc contact is connected to the operating mechanism, the driven-side arc contact is coupled to a bidirectional drive mechanism section, the bidirectional drive mechanism section includes a driving rod to receive a driving force from the driving-side main contact, a coupling member coupling the insulating nozzle and the driving rod, and a coupling mechanism to operate the driven-side arc contact in an opposite direction with respect to an operation of the driving rod, the insulating nozzle is disposed so as to cover an inner surface of the coupling member such that an end surface of the coupling member and an end surface of the insulating nozzle form one surface, in order to suppress contact between a high-temperature and high-pressure gas generated by the arc and the coupling member, the insulating nozzle and the coupling member are coupled by engaging a nozzle coupling portion, which is provided on and protruding from an outer periphery of the insulating nozzle, with a cutout portion formed on an end surface opposite to the end surface of the coupling member and by fixing an engagement portion therebetween with an electric field relaxation ring from an axially outer side, and a space is formed on an inner peripheral surface of the coupling member so as to face an outer peripheral surface of the insulating nozzle. 4. The gas circuit breaker according to claim 3 , wherein a distal end portion of the driven-side arc contact is positioned on a downstream side of the electric field relaxation ring during current breaking by the gas circuit breaker. 5. A gas circuit breaker comprising: a filling container which is filled with an insulating gas having an arc-extinguishing property; a driving-side main conductor which is supported and fixed by an insulating support tube disposed inside the filling container, and is connected to a driving-side lead-out conductor connected to an electric power system, and has an exhaust hole configured to exhaust the insulating gas whose temperature and pressure have been increased by an arc generated during breaking; an exhaust shaft which is provided inside the driving-side main conductor so as to be movable in an axial direction of the driving-side main conductor and has a shaft exhaust hole configured to exhaust the insulation gas whose temperature and pressure have been increased; an operating mechanism which is connected to the exhaust shaft and outputs an operating force in an axial direction of the exhaust shaft via an operation rod; a cylinder which is coaxially coupled to the exhaust shaft and is axially slidable on an inner peripheral surface of the driving-s