Shaft for rotationally coupling a main device to a tubular device

The invention claimed is: 1. A coupling system for rotationally coupling a main device to a tubular device such that a torque can be transmitted between the main device and the tubular device via the coupling system, comprising: a shaft having a first end region at a free end that is configured to be introduced into the tubular device to mount the shaft with the tubular device, and a second end region that faces away from the first end region, and which is configured to fasten the shaft to the main device; and a securing device arranged on the shaft, and which is configured to at least axially secure the tubular device on the shaft, the securing device including: a blocking device formed as a sphere, the blocking device having a radially protruding retaining section that extends beyond an outer circumference of the shaft so as to engage the tubular device and block the tubular device against removal from the shaft when positioned in a locked state, and the blocking device being recessed in the shaft so as to enable removal of the tubular device when positioned in an unlocked state; and a locking device arranged in the first end region of the shaft and which is configured to lock and unlock the blocking device, the locking device defining a ramp surface against which the blocking device rests in the locked state, the ramp surface being angled with respect to a longitudinal axis of the shaft in such a way that a radially inwardly directed force acting on the blocking device urges the locking device in a direction toward the second end of the shaft and moves the blocking device from the locked state to the unlocked state, wherein the outer circumference of the shaft defines (i) a first supporting region which is configured to contact in a hollow receiving region of the tubular device when the tubular device is mounted on the shaft, and (ii) at least one torque-transmitting section which is configured to engage with a torque-transmitting section of the tubular device. 2. The coupling system as claimed in claim 1 , wherein the shaft is configured to be introduced, together with the blocking device and the locking device, into the tubular device. 3. The coupling system as claimed in claim 1 , wherein the blocking device is configured such that the radially protruding retaining section engages the tubular device as the tubular device is mounted on the shaft in such a way that the radially protruding retaining section is guided through the hollow receiving region of the tubular device as the tubular device is mounted on the shaft. 4. The coupling system as claimed in claim 1 , wherein the securing device is connected to the shaft in such a way that the securing device remains attached to the shaft at least when the tubular device is removed. 5. The coupling system as claimed in claim 1 , wherein the securing device is configured to move into a locking position when the blocking device is in the locked state and move into an unlocking position when the blocking device is in the unlocked state, the locking position and the unlocking position being spaced apart at least one of radially, tangentially, and axially on the shaft. 6. The coupling system as claimed in claim 1 , wherein the shaft includes a groove wall surface and a groove floor surface that collectively defines at least one groove extending from the first end, the radially protruding retaining section of the blocking device projecting from the groove floor surface of the at least one groove in the locked state. 7. The coupling system as claimed in claim 6 , wherein a ratio of a width of the at least one groove to a diameter of the first supporting region is in a range from 30% to 60%. 8. The coupling system as claimed in claim 6 , wherein: the first supporting region has a diameter of 11.7 mm; the at least one groove includes four grooves that each have a width of 5.2 mm and a length of 23.8 mm, starting from the first end of the shaft; and the four grooves are distributed uniformly on the circumference of the shaft, so that each groove is separated from a diametrically opposite groove by a distance of 8.55 mm. 9. The coupling system as claimed in claim 1 , wherein the locking device is arranged extending from an end side of the first end region of the shaft. 10. The coupling system as claimed in claim 1 , wherein the blocking device is configured to move from the locked state into the unlocked state when the locking device is at least one of axially pressed along a longitudinal axis of the shaft and rotated about the longitudinal axis of the shaft by less than 360°. 11. The coupling system as claimed in claim 1 , wherein: the blocking device is configured to be manually unlocked and is configured to be automatically locked when the tubular device is mounted, and the blocking device is retained in the locked state by an elastic force, which is overcome during mounting of the tubular device, such that the blocking device automatically moves to the unlocked state during mounting of the tubular device. 12. The coupling system as claimed in claim 1 , wherein: the shaft further defines an axial recess that extends into the shaft from an end side of the first end region, the axial recess having, on the end side, a cross-sectional area which (i) is substantially constant over a length of the recess over which the securing device extends, or (ii) tapers in a direction of the second end of the shaft; the locking device being axially movable in the axial recess; and in the locked state, the blocking device is acted on by the locking device with a force which acts outward transversely with respect to the axial recess. 13. The coupling system as claimed in claim 12 , further comprising a spring arranged on a base of the axial recess, said spring exerting a force which acts outward axially on the locking device. 14. The coupling system as claimed in claim 12 , wherein: the shaft further defines a lateral recess that is transverse with respect to the axial recess, said lateral recess having a first opening and a second opening on an outer circumference of the shaft; the first opening is smaller than the second opening; and the radially protruding retaining section of the blocking device projects from the first opening in the locked state. 15. The coupling system as claimed in claim 12 , wherein: the force acts to press the locking device in a direction from the second end region toward the first end region of the shaft; and the blocking device retains the locking device in the shaft. 16. The coupling system as claimed in claim 12 , wherein: the locking device the blocking device is arranged in the locking device; and the ramp surface is formed in the locking device in such a way that, when the locking device is displaced into the shaft in a direction from the first region toward the second end region, the blocking device is enabled to move away from the outer circumference to the unlocked position. 17. The coupling system as claimed in claim 1 , wherein: the first supporting region has a length of at least 30 mm starting from the first end region of the shaft; the shaft further defines a second supporting region that adjoins the first supporting region, and that has a larger diameter than a diameter of the first supporting region; the length of the first supporting region and a length of the second supporting region together are 63.5 mm. 18. A system comprising: a machine tool that includes: a receptacle; and a shaft received in the receptacle, the shaft configured to be driven in at least