Load cell and method for adjusting a load cell

The invention claimed is: 1. A load cell comprising: a weighing system having a force application point, a load boom arm for receiving loads to be weighed at a position remote from the force application point, wherein the load boom arm extends, in a plan view of the load cell, from the force application point in a longitudinal direction (A), an adjusting weight boom arm which extends in the longitudinal direction (A) on a side opposing the load boom arm relative to the force application point and which has at least two pre-determined adjusting weight engagement points provided thereon, a further adjusting weight boom arm for placement of the adjusting weight, extending transversely to the longitudinal direction (A), and at least one activating unit which places at least one adjusting weight onto the adjusting weight engagement points. 2. The load cell as claimed in claim 1 , further comprising a housing from which the load boom arm extends, wherein the adjusting weight boom arm is accommodated in the housing. 3. The load cell as claimed in claim 2 , wherein the load boom arm and the adjusting weight boom arm extend within the housing at the same height and/or vertically offset. 4. The load cell as claimed in claim 1 , wherein a single adjusting weight can be placed selectively onto any of the adjusting weight engagement points of the adjusting weight boom arm. 5. The load cell as claimed in claim 1 , wherein an adjusting weight engagement point is essentially moment-free in relation to the weighing system and the other adjusting weight engagement point is remote from the force application point or wherein both adjusting weight engagement points are located at different distances from the force application point. 6. The load cell as claimed in claim 1 , wherein the two adjusting weights have mutually essentially identical mass. 7. The load cell as claimed in claim 1 , wherein at least one of: (i) the load boom arm and the adjusting weight boom arm are linked to a single site in the weighing system or (ii) the adjusting weight boom arm is a linear extension of the load boom arm extending beyond the force application point. 8. The load cell as claimed in claim 7 , wherein the load boom arm and the adjusting weight boom arm are linked to the single site in the weighing system and merge into one another. 9. The load cell as claimed in claim 1 , wherein a plurality of dedicated adjusting weights are provided for each of the adjusting weight engagement points, and wherein the activating unit places the adjusting weights one after the other onto the adjusting weight boom arm. 10. A method for adjusting a load cell as claimed in claim 1 and comprising: placing at least one adjusting weight on two adjusting weight engagement points provided at the adjusting weight boom arm, determining the weight values of the at least one adjusting weight at both the adjusting weight engagement points, calculating the change in the off-center load between a factory adjustment and the weight values determined as an off-center load error, and determining a calibration factor of the load cell taking account of the off-center load error or a change in the off-center load error. 11. The method as claimed in claim 10 , further comprising calculating a change in the off-center load from the deviation of the difference of the two determined weight values from the calibration factor. 12. The method as claimed in claim 10 , further comprising, during manufacturing, storing a limit value for a maximum off-center load in the load cell, and during operation and on reaching or exceeding the limit value of the stored off-center load, outputting an error message.