Method and apparatus for determining the absolute value of the flow velocity of a particle-transporting medium

The invention claimed is: 1. A method for determining the absolute value of the flow velocity of a particle-transporting medium, comprising the steps of: emitting at least two measurement laser beams with linearly independent, non-orthogonal measurement directions; detecting the measurement laser beams scattered at particles and generating one measurement signal in each case for each measurement laser beam; and evaluating the measurement signals, a. wherein absolute values of velocity components are ascertained as projections of the flow velocity on the respective measurement directions; b. wherein a solid angle region is ascertained for the prevalent direction of the flow velocity and signs assigned to this solid angle region are chosen for the individual velocity components; and c. wherein the absolute value of the flow velocity is determined using the ascertained absolute values of the velocity components and using the chosen signs for the velocity components. 2. The method according to claim 1 , characterized in that at least three measurement laser beams with different measurement directions are emitted, of which at least three are non-orthogonal with respect to one another and three are linearly independent; and in that the value of the flow velocity is determined using the ascertained absolute values of the velocity components for three linearly independent measurement directions and using the chosen signs for the velocity components. 3. The method according to claim 2 , characterized in that each of the three linearly independent measurement directions is respectively assigned two mutually opposing predefined solid angle regions and in that the remaining two predefined solid angle regions cover the remaining measurement surroundings. 4. The method according to claim 3 , characterized a. in that the at least three absolute values of the velocity components are compared to one another, b. in that the maximum absolute value of the velocity components is ascertained and c. in that, if the difference between the maximum absolute value of the velocity components and the remaining absolute values of the velocity components exceeds a predetermined first limit value, the predetermined solid angle region that is assigned to the measurement direction with the maximum absolute value of the velocity components is determined as solid angle region for the prevalent direction of the flow velocity. 5. The method according to claim 1 , characterized in that the ascertained absolute values of the velocity components are transformed into an orthogonal coordinate system using the ascertained signs for the velocity components and the flow velocity of the particle stream is calculated in the orthogonal coordinate system, at least apart from the sign thereof. 6. The method according to claim 1 , characterized in that the solid angle region for the prevalent direction of the flow velocity is ascertained as one of eight predefined solid angle regions, which together cover the entire measurement surroundings, and in that respectively two predefined solid angle regions lying opposite one another are assigned the same signs for the individual velocity components. 7. The method according to claim 6 , characterized in that: at least one of a contrast value of the associated particle count rates and the mean particle dwell times is calculated for each pair of measurement directions, and the solid angle region for the prevalent direction of the flow velocity is ascertained as a predefined solid angle region that is assigned to no measurement direction if at least one of the contrast values exceeds a predetermined second or third limit value. 8. The method according to claim 1 , characterized in that a particle count rate is determined for every measurement direction and in that the differences between the particle count rates are taken into account when ascertaining the solid angle region for the prevalent direction of the flow velocity. 9. The method according to claim 8 , characterized in that: at least one of a contrast value of the associated particle count rates and the mean particle dwell times is calculated for each pair of measurement directions, and the solid angle region for the prevalent direction of the flow velocity is ascertained as a predefined solid angle region that is assigned to no measurement direction if at least one of the contrast values exceeds a predetermined second or third limit value. 10. The method according to claim 1 , characterized in that a mean particle dwell time in the region detected by the corresponding measurement laser beam is determined for each measurement direction and in that the differences between the mean particle dwell times are taken into account when ascertaining the solid angle region for the prevalent direction of the flow velocity. 11. The method according to claim 1 , wherein at least four measurement laser beams are emitted in different measurement directions, characterized in that, for at least two different sets of three linearly independent and non-orthogonally aligned measurement directions, a solid angle region for the prevalent direction of the flow velocity and an absolute value of the flow velocity are ascertained as estimates in each case and in that the prevalent direction of the flow velocity and the absolute value of the flow velocity are then determined by a consistency check. 12. The method according to claim 11 , characterized in that the absolute value of the at least one velocity component not belonging to the set is ascertained on the basis of the corresponding measurement signal, in that a hypothetical absolute value for the at least one velocity component not belonging to the set is determined on the basis of the estimates, ascertained for the set, of the solid angle region for the prevalent direction of the flow velocity and of the absolute value of the flow velocity, and in that the absolute value and the hypothetical absolute value for the at least one velocity component not belonging to the set are compared to one another in order to assess the accuracy of the respective estimates. 13. The method according to claim 11 , wherein a solid angle region for the prevalent direction of the flow velocity is ascertained in each case for at least three different sets of three linearly independent and non-orthogonally aligned measurement directions, characterized in that, for the purposes of determining the absolute value of the flow velocity, the solid angle region that has been ascertained for the plurality of sets is used for the prevalent direction of the flow velocity. 14. The method according to claim 1 , characterized in that the measurement signals are generated by self-mixing interference between the emitted measurement laser beams and the corresponding scattered measurement laser beams and in that the absolute values of the velocity components are each determined on the basis of the frequency shift between the emitted measurement laser beam and the corresponding scattered measurement laser beam. 15. Use of the method according to claim 1 for determining a particle number per unit measurement volume, wherein the measurement volume is determined on the basis of the ascertained absolute value of the flow velocity. 16. An apparatus for determining the absolute value of the flow velocity of a particle-transporting medium, comprising: an optical emitter device configured to emit at least three measurement laser beams with different measurement directions, of which at least three are non-orthogonal with respect to one another and three ar