Balance with free-floating weighing pan

What is claimed is: 1. A balance, comprising: a weighing pan; at least six position sensors, arranged to measure the position of the weighing pan in all three dimensions; a weighing mechanism with at least six electromagnetic mechanisms, each of which includes at least one permanent magnet and at least one force coil, such that the weighing mechanism generates compensation forces to act, through currents sent to each force coil, in each of the six translatory and rotatory degrees of freedom on the weighing pan, based upon the orientation and position of each force coil relative to the weighing pan; a regulating unit to regulate the individual currents flowing in the force coils, wherein the compensation forces, through the sum of their respective moments, hold the weighing pan in a constant, predefined and free-floating position relative to the six degrees of freedom; and an arithmetic unit provided with software to calculate the weighing result based on the amounts of current flowing in the respective force coils. 2. The balance of claim 1 , wherein the at least six electromagnetic mechanisms are arranged relative to each other in a manner that distributes the weight of the weighing pan essentially uniformly over the at least six electromagnetic mechanisms. 3. The balance of claim 2 , wherein the weighing pan is arranged above the weighing mechanism. 4. The balance of claim 2 , wherein the weighing pan is arranged below the weighing mechanism. 5. The balance of claim 2 , wherein the weighing pan is arranged to the side of the weighing mechanism. 6. The balance of claim 1 , wherein the electromagnetic mechanisms are arranged essentially in two groups of three that are placed, respectively, along a pair of lines which are in particular parallel and close to each other. 7. The balance of claim 1 , wherein at least three of the electromagnetic mechanisms are arranged on a first side of the weighing pan and at least the further three electromagnetic mechanisms are arranged on a second side of the weighing pan, opposite to the first side. 8. The balance of claim 1 , wherein the electromagnetic mechanisms are arranged on the weighing mechanism such that the electromagnetic mechanisms act on the weighing pan in the manner of a hexapod. 9. The balance of claim 2 , further comprising a coupling element that couples the at least six electromechanical mechanisms with the weighing pan. 10. The balance of claim 9 , wherein the coupling element comprises a carrier made of one piece of material and having a plurality of arms, the carrier connecting each of the electromagnetic mechanisms to the weighing pan. 11. The balance of claim 1 , wherein the electromagnetic mechanisms are essentially identical and essentially arranged in a plane. 12. A method for operating a balance, wherein the method comprises the steps of: measuring the position of a weighing pan of the balance in all three dimensions by means of the at least six position sensors; generating, during the weighing process, a compensation force in each of at least six electromagnetic mechanisms associated with the weighing pan to act on the weighing pan in the six translatory and rotatory degrees of freedom of the weighing pan, each of the electromagnetic mechanisms including at least one permanent magnet and at least one force coil, wherein the compensation force is generated by a current sent through each force coil, depending on the respective position and orientation of the force coil relative to the weighing pan; simultaneously regulating the respective current flowing in each force coil, so that the compensation forces, through the sum of their respective moments, hold the weighing pan in a predetermined, free-floating and constant position relative to the six degrees of freedom; and calculating a weighing result from the amounts of current flowing in the respective force coils. 13. The method of claim 12 , wherein the compensation forces generated act on the weighing pan through a coupling element that is connected to the weighing pan. 14. The method of claim 13 , wherein the position of the weighing pan is measured by measuring the positions of the force coils and wherein the position of the weighing pan relative to the position sensors is derived from the measurement and from the known position of the weighing pan relative to the positions of the force coils. 15. The method of claim 13 , wherein the position of the weighing pan is measured by measuring the position of the coupling element and wherein the position of the weighing pan relative to the position sensors is derived from the measurement and from the known position of the weighing pan relative to the coupling element. 16. The method of claim 12 , wherein the respective amounts of current flowing in the force coils are used to calculate the inclination of the weighing pan. 17. The method of claim 12 , wherein the respective amounts of current flowing in the force coils are used to calculate the location of the center of gravity of a weighing object lying on the weighing pan. 18. The method of claim 12 , wherein the positions of three predefined points of the weighing pan are measured along the Z-axis, the positions of two predefined points of the weighing pan are measured along the Y-axis, and the position of one predefined point of the weighing pan is measured along the X-axis.