Scale with overload detection

The invention claimed is: 1 . A scale which operates according to the principle of electrodynamic force compensation, the scale including: (a) a carrying coil and a magnet which interact with one another and are movable relative to one another, wherein the carrying coil is connected in a load coil circuit to receive a carrying coil current supplied to the carrying coil from an output stage; (b) a resistor arrangement which forms an electrical load resistance for the load coil circuit, the resistor arrangement comprising the carrying coil having a coil electrical resistance and a measuring resistor arrangement having a measuring electrical resistance, wherein the scale operates in a measuring mode for a force acting on the scale in a predetermined load measuring range, the electrical load resistance having a measuring mode resistance value when the scale is operating in the measuring mode so that the carrying coil current supplied to the carrying coil by the output stage comprises a carrying coil measuring current to compensate, by electrodynamic interaction between the carrying coil and the magnet, for the force acting on the scale and the scale determines a measured value associated with the force acting on the scale from a measuring voltage drop at the measuring resistor arrangement; and (c) a switching arrangement for switching from the measuring mode to an overload mode for detecting an overload force acting on the scale which exceeds or falls below the predetermined load measuring range, wherein in the overload mode the electrical load resistance is reduced from the measuring mode resistance value and wherein the carrying coil current supplied to the carrying coil by the output stage comprises a carrying coil overload current to compensate, by electrodynamic interaction between the carrying coil and the magnet, for the overload force acting on the scale; (d) wherein the switching from the measuring mode to the overload mode occurs automatically. 2 . The scale of claim 1 wherein when the scale is operating in the overload mode the carrying coil overload current is quantitatively determined by tapping an overload detection voltage within the load coil circuit and feeding the overload detection voltage to an A/D converter. 3 . The scale of claim 1 further including a first A/D converter with a first load measuring range to which a voltage representing the measuring voltage drop is fed when the scale is operating in the measuring mode and wherein a transition between a force within the predetermined load measuring range and an overload force outside the predetermined load measuring range is detectable in that the voltage representing the measuring voltage drop exceeds or falls below a predeterminable threshold value for the first load measuring range of the first A/D converter. 4 . The scale of claim 1 further including: (a) a first A/D converter with a first load measuring range to which a voltage representing the measuring voltage drop is fed when the scale is operating in the measuring mode; and (b) a second A/D converter with a second load measuring range to which an auxiliary voltage tapped within the load coil circuit is fed when the scale is operating in the measuring mode, wherein a transition between a force within the predetermined load measuring range and an overload force outside the predetermined load measuring range is detectable in that the auxiliary voltage exceeds or falls below a predeterminable threshold value for the second load measuring range. 5 . The scale of claim 4 wherein the second load measuring range of the second A/D converter is selected to be larger than the first load measuring range of the first A/D converter. 6 . The scale of claim 1 wherein the electrical load resistance is reduced in the overload mode by short circuiting a measuring resistor in the measuring resistor arrangement. 7 . The scale of claim 1 wherein the electrical load resistance is reduced in the overload mode by replacing a measuring resistor in the measuring resistor arrangement with an additional resistor having an electrical resistance less than the measuring resistor. 8 . The scale of claim 1 wherein the electrical load resistance is reduced in the overload mode by connecting an additional resistor in parallel with a measuring resistor of the measuring resistor arrangement. 9 . The scale of claim 1 wherein the electrical resistance of the resistor arrangement is reduced by at least 50% in the overload mode. 10 . The scale of claim 1 wherein the electrical resistance of the resistor arrangement is reduced by at least 80% in the overload mode. 11 . The scale of claim 1 wherein the electrical resistance of the resistor arrangement is reduced by at least 90% in the overload mode. 12 . The scale of claim 1 wherein the electrical resistance of the resistor arrangement is reduced by at least 95% in the overload mode. 13 . The scale of claim 1 further including a first A/D converter with a first load measuring range to which a voltage representing the measuring voltage drop is fed when the scale is operating in the measuring mode and wherein: (a) the scale is operable to switch to the overload mode when a measured value exceeds a predefined first threshold value to signal an overload, in order to (i) feed a reduced measuring resistor voltage to the first A/D converter for determining the overload force, or (ii) supply an auxiliary voltage tapped at the resistor arrangement to a second A/D converter with a second load measuring range for determining the overload force; and (b) the scale is operable to switch back from the overload mode to the measuring mode when the measured value falls below the predefined first threshold value or a predefined second threshold value different from the predefined first threshold value. 14 . The scale of claim 1 wherein the output stage is operable to at least double the current flowing through the resistor arrangement when the scale is operating in the overload mode as compared to the current flowing through the resistor arrangement when the scale is operating in the measurement mode. 15 . The scale of claim 1 upon switching between the measuring mode and the overload mode the carrying coil current adjusts to a required compensation current within less than 500 ms from the time of switching. 16 . A method for operating a scale according to the principle of electrodynamic force compensation, wherein the scale includes, (i) a carrying coil and a magnet which interact with one another and are movable relative to one another, wherein the carrying coil is connected in a load coil circuit to receive a carrying coil current supplied to the carrying coil from an output stage; and (ii) a resistor arrangement which forms an electrical load resistance for the load coil circuit, the resistor arrangement comprising the carrying coil having a coil electrical resistance and a measuring resistor arrangement having a measuring electrical resistance, wherein the scale operates in a measuring mode for a force acting on the scale in a predetermined load measuring range, the electrical load resistance having a measuring mode resistance value when the scale is operating in the measuring mode so that the carrying coil current supplied to the carrying coil by the output stage comprises a carrying coil measuring current to the carrying coil to compensate, by electrodynamic interaction between the carrying coil and the magnet, for the force acting on the scale and the scale determines a measured value associated with the force acting on the scale from a m