Optical monitoring system for observing internal conditions in the tuyere zone of a blast furnace

The invention claimed is: 1. Optical monitoring system for monitoring operating conditions in a tuyere zone of a blast furnace, said optical monitoring system comprising: a light deflecting device configured for connection to a rear portion of a blowpipe such that the tuyere, the blowpipe and the light deflecting device are positioned along a common axis; a peep sight arranged in a first face of said light deflecting device for allowing an operator to monitor the operating conditions in the tuyere zone with an unaided eye; an optical sensor arranged in a second face of said light deflecting device for electronic monitoring of the operating conditions in the tuyere zone; a light deflector arranged within said light deflecting device for directing incident light from the tuyere zone towards said peep sight and towards said optical sensor wherein said light deflecting device comprises a housing with a spherical body rotatably arranged therein, wherein said spherical body comprises, a first passage which is, when said light deflecting device is connected to the rear portion of the blowpipe, facing the tuyere for allowing incident light from the tuyere zone to enter the spherical body; a second passage facing said peep sight; a third passage facing said optical sensor; wherein said first, second and third passages are configured so as to meet each other within said spherical body; wherein said light deflector is arranged within said spherical body at an intersection of said first, second and third passages; wherein said light deflecting device further comprises an opening in a third face thereof for accessing the spherical body and allowing rotation of the spherical body within said housing; wherein said spherical body comprises a socket facing said opening in said third face of said light deflecting device allowing the insertion of an adjustment tool for rotating the spherical body within said housing; wherein said opening in said third face of said light deflecting device is a guiding slot whose width is substantially the same as a diameter of said socket; wherein a linear movement of said socket along the guiding slot causes said spherical body to rotate about a first rotation axis, and wherein a rotational movement of said socket causes said spherical body to rotate about a second rotation axis. 2. The optical monitoring system according to claim 1 , wherein said socket and said adjustment tool are self-locking and/or have any connection shape capable of transmitting a torque. 3. The optical monitoring system according to claim 1 , wherein said socket has non-circular cross-section and said adjustment tool is a key with corresponding cross-section. 4. The optical monitoring system according to claim 2 , wherein said socket has hexagonal cross-section and said adjustment tool is a hexagonal key. 5. The optical monitoring system according to claim 1 , wherein said first rotation axis is substantially perpendicular to said second rotation axis. 6. The optical monitoring system according to claim 1 , wherein the light deflector is fixedly arranged within said spherical body. 7. The optical monitoring system according to claim 1 , further comprising a spring element arranged between said spherical body and said housing for maintaining said spherical body in place through friction. 8. The optical monitoring system according to claim 7 , wherein said spring element is an annular spring. 9. The optical monitoring system according to claim 1 , wherein said light deflecting device comprises a removable mounting face for insertion and/or removal of said spherical body. 10. The optical monitoring system according to claim 9 , wherein said removable mounting face is said first face of said light deflecting device comprising said peep sight. 11. The optical monitoring system according to claim 9 , wherein a ring shaped seat element is arranged between said spherical body and said mounting face. 12. The optical monitoring system according to claim 7 , wherein said spring element is arranged between a mounting face and said ring shaped seat element. 13. The optical monitoring system according to claim 1 , wherein said spherical body comprises a slot for receiving said light deflector therein. 14. The optical monitoring system according to claim 11 , wherein said peep sight is formed by a glass plate sandwiched between said first face of said light deflecting device and said ring shaped seat element. 15. The optical monitoring system according to claim 14 , wherein a first annular seal is arranged between said ring shaped seat element and said glass plate, and a second annular seal is arranged between said glass plate and said first face.