Orbital welding device with simplified handling

The invention claimed is: 1. An orbital welding device, the orbital welding device having a welding current source in a welding current source housing and a base controller therein or thereon and having an orbital welding head, which is separate from the welding current source housing and is connected to the welding current source by means of a cable, the orbital welding head having a pipe mount and a welding electrode holder, which is mounted rotatably with respect to the pipe mount and is intended for holding a welding electrode, the orbital welding device having a motor, which is configured to drive the welding electrode holder and thus turn it with respect to the pipe mount, the orbital welding head having a chamber for shielding gas, which is configured to surround a welding electrode of the orbital welding head and substantially seal it off from the outside during a welding process, the orbital welding head having an electrical circuit, wherein the electrical circuit is connected to a position sensor, the position sensor being configured to generate a position value, the position sensor being arranged in a fixed relative position with respect to the pipe mount and in a movable relative position with respect to the welding electrode holder, and the position value representing an orientation of the pipe mount with respect to gravitational force. 2. The orbital welding device as claimed in claim 1 , the electrical circuit or the base controller being configured to calculate in dependence on the position value and on a turn value, which represents the turning of the welding electrode with respect to the pipe mount, an orientation value, which represents an orientation of the welding electrode or of the welding electrode holder with respect to gravitational force. 3. The orbital welding device as claimed in claim 2 , the electrical circuit being configured to pass on to the base controller the position value or the orientation value calculated. 4. The orbital welding device as claimed in claim 3 , the base controller being configured to carry out an open-loop or closed-loop control of the welding process in dependence on the position value or the orientation value. 5. The orbital welding device as claimed in claim 4 , the base controller being configured to load a stored welding process program from a memory and the open-loop or closed-loop control of the welding process including a run of the welding process program, the base controller being configured to shift a starting point at which the run of the welding process program begins in dependence on the position value. 6. The orbital welding device as claimed in claim 1 , the orbital welding device having a display unit, which is configured to present a graphic representation of the orientation of the welding electrode with respect to gravitational force, the orbital welding device being configured to turn and/or tilt the graphic representation in dependence on the position value. 7. The orbital welding device as claimed in claim 1 , wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to store in the memory device at least one of a loading value or a calibrating value, wherein the electrical circuit is configured to store in the memory device at least one of: a) at least one of a number, a time period, a maximum current, or a current accumulated over time, corresponding to an electrical charge, of the welding processes carried out with at least one of the welding electrode, the orbital welding head, or arcs, b) a number of specific vibrations or c) an operating time of the motor, as the one or more loading values. 8. The orbital welding device as claimed in claim 1 , wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to store in the memory device a loading value, the orbital welding device having a loading sensor and the electrical circuit or the base controller being configured to determine the loading value from a measured value of the loading sensor. 9. The orbital welding device as claimed in claim 8 , the orbital welding head at least partially having the loading sensor, and the orbital welding head having a battery, and the orbital welding head being configured to operate the part of the loading sensor that the orbital welding head has with the aid of the electrical energy provided by the battery and to store one or more of the loading values in the memory device by means of the electrical circuit. 10. The orbital welding device as claimed in claim 1 , wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to store in the memory device a loading value, the electrical circuit being configured to receive the loading value from the base controller. 11. The orbital welding device as claimed in claim 1 , wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to store in the memory device a loading value, the base controller or the electrical circuit being configured to read out the loading value from the memory device and to emit an alarm signal if the loading value exceeds a threshold value predefined for the respective loading value. 12. The orbital welding device as claimed in claim 1 , wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to store in the memory device a calibrating value, the base controller or the electrical circuit being configured to carry out a calibrating run of the motor and thereby generate the calibrating value. 13. An orbital welding device, the orbital welding device having a welding current source in a welding current source housing and a base controller therein or thereon and having an orbital welding head, which is separate from the welding current source housing and is connected to the welding current source by means of a cable, the orbital welding head having a pipe mount and a welding electrode holder, which is mounted rotatably with respect to the pipe mount and is intended for holding a welding electrode, the orbital welding device having a motor, which is configured to drive the welding electrode holder and thus turn it with respect to the pipe mount, the orbital welding head having a chamber for shielding gas, which is configured to surround a welding electrode of the orbital welding head and substantially seal it off from the outside during a welding process, the orbital welding head having an electrical circuit, wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to store a loading value in the memory device, the base controller or the electrical circuit, being configured to carry out a calibrating run of the motor and thereby generate the calibrating value, the calibrating run comprising: activating the motor with a defined voltage u 1 ; detecting a specific first angular position φ 1 of the motor or of the welding electrode holder or of a gear part and starting a time measurement at t 1 ; detecting a specific second angular position φ 2 of the motor or of the welding electrode holder or of a gear part and stopping the time measurement at t 2 ; and calculating a parameter p as the calibrating value for converting the motor input voltage u 1 into the angular velocity ω 1 of the motor or of the welding electrode holder or of a gear part in dependence on φ 1 , φ 2 , t 1 and t 2 . 14. The orbital welding device as claimed in claim 1 , wherein the electrical circuit is connected to a memory device, the electrical circuit being configured to