Radar beam deflection unit for a radar level indicator

The invention claimed is: 1. A radar beam deflection unit for a radar level indicator for controlling the deflection of a main emission direction of a transmission signal emitted from the radar level indicator, comprising: a first beam deflection element deflecting the main emission direction of the transmission signal; a first drive rotating the first beam deflection element about a first axis of rotation, with the result that the main emission direction of the transmission signal after passing through the first beam deflection element follows a closed path; a second beam deflection element deflecting the main emission direction of the transmission signal, after it has passed through the first beam deflection element; and a second drive rotating the second beam deflection element about a second axis of rotation, with the result that the main emission direction of the transmission signal after passing through the first and second beam deflection elements follows a closed path. 2. The radar beam deflection unit according to claim 1 , wherein the axis of rotation of the first beam deflection element and the axis of rotation of the second beam deflection element coincide. 3. The radar beam deflection unit according to claim 1 , further comprising: a third drive for rotating the first beam deflection element and/or the second beam deflection element about a third axis of rotation that is perpendicular to the first axis of rotation and the second axis of rotation. 4. The radar beam deflection unit according to claim 1 , wherein the first beam deflection element has a first optical surface and a second optical surface which include an angle that defines the deflection of the main emission direction. 5. The radar beam deflection unit according to claim 1 , wherein the first drive and the second drive are designed as a mechanically coupled drive. 6. The radar beam deflection unit according to claim 1 , wherein a ratio of a rotation frequency of the first beam deflection element with respect to a rotation frequency of the second beam deflection element is adjustable. 7. A measuring instrument, comprising: a radar beam deflection unit controlling a deflection of a main emission direction of a transmission signal emitted from a radar level indicator, the radar beam deflection unit including a first beam deflection element deflecting the main emission direction of the transmission signal; and a first drive rotating the first beam deflection element about a first axis of rotation, with the result that the main emission direction of the transmission signal after passing through the first beam deflection element follows a closed path, the radar beam deflection unit further including a second beam deflection element deflecting the main emission direction of the transmission signal, after it has passed through the first beam deflection element and a second drive rotating the second beam deflection element about a second axis of rotation, with the result that the main emission direction of the transmission signal after passing through the first and second beam deflection elements follows a closed path. 8. The measuring instrument according to claim 7 , comprising: an attachment mechanism for attaching the radar beam deflection unit to the measuring instrument. 9. The measuring instrument according to claim 7 , wherein the measuring instrument is embodied as a pulse radar instrument or FMCW measuring instrument. 10. The measuring instrument according to claim 7 , the measuring instrument determines a topography of a bulk solid. 11. A method for determining the topology of a bulk solid, comprising the steps: transmitting a transmission signal from a radar level indicator in a main emission direction of an antenna array; deflecting the main emission direction of the transmission signal; rotating a first beam deflection element about a first axis of rotation so that the main emission direction of the transmission signal after passing through the first beam deflection element follows a closed path; rotating a second beam deflection element about a second axis of rotation so that the main emission direction of the transmission signal after passing through the first and second beam deflection element follows a closed path; and determining the topology of the bulk solid by analysing the transmission signal reflected at the bulk-solid surface.