Solenoid valve for a vehicle braking system

The invention claimed is: 1. A solenoid valve for a vehicle braking system, comprising: a magnet assembly including: a winding support; a coil winding; a housing; and a cover disc; a valve cartridge including: a capsule; a valve insert connected to the capsule; a valve seat; and an armature configured to be guided within the capsule in an axially movable manner between a closed position and an open position, the armature including a closing element, wherein the closing element and the valve seat are configured to form a valve that is operable to control a fluid flow through the valve cartridge, wherein the coil winding is wound on the winding support to form an electrical coil, the electrical coil being configured to be controlled by using control signals applied to electrical connectors, wherein the electric coil is further configured to generate a magnetic force that is operable to move the armature against a force of a return spring, wherein fluid temperature within the valve cartridge is changeable based on the control signals, wherein the control signals are configured to be applied to the coil winding as bipolar AC signals having a predetermined frequency and are further configured to generate eddy currents in an iron circuit of the solenoid valve and in the capsule, and wherein the eddy currents are operable to heat up the fluid in the valve cartridge. 2. The solenoid valve as claimed in claim 1 , wherein the iron circuit of the solenoid valve includes the armature, the housing, and the cover disc. 3. The solenoid valve as claimed in claim 1 , wherein a heating operation of the magnet assembly includes at least two heating modes that each have a predetermined frequency range for the bipolar AC signals. 4. The solenoid valve as claimed in claim 3 , wherein, in a first heating mode, the predetermined frequency of the bipolar AC signal is predetermined from a first frequency range so that the valve does not react to the applied control signals. 5. The solenoid valve as claimed in claim 4 , wherein the first frequency range includes frequencies in the range of ca. 0.1 kHz to 2.0 kHz. 6. The solenoid valve as claimed in claim 3 , wherein, in a second heating mode, the predetermined frequency of the bipolar AC signal is configured to be predetermined from a second frequency range so as to achieve a maximal inductive thermal output. 7. The solenoid valve as claimed in claim 6 , wherein the second frequency range includes frequencies in the range of ca. 2.1 kHz to 3.0 kHz. 8. The solenoid valve as claimed in claim 3 , wherein, in a third heating mode, the heating mode is switched between the first heating mode and the second heating mode based on an operating state of the vehicle, and wherein a prevailing frequency of the bipolar AC signal is dependent upon an available onboard network voltage. 9. The solenoid valve as claimed in claim 8 , wherein an optimal frequency for each voltage position is stored in the form of a characteristic curve. 10. A solenoid valve for a vehicle braking system, comprising: a magnet assembly including: a winding support; a coil winding; a housing; and a cover disc; a valve cartridge including: a capsule; a valve insert connected to the capsule; a valve seat; and an armature configured to be guided within the capsule in an axially movable manner between a closed position and an open position, the armature including a closing element, wherein the closing element and the valve seat are configured to form a valve that is operable to control a fluid flow through the valve cartridge, wherein the coil winding is wound on the winding support to form an electrical coil, the electrical coil being configured to be controlled by using control signals applied to electrical connectors, wherein the electric coil is further configured to generate a magnetic force that is operable to move the armature against a force of a return spring, wherein fluid temperature within the valve cartridge is changeable based on the control signals, wherein the control signals are configured to be applied to the coil winding as bipolar AC signals having a predetermined frequency and are further configured to generate eddy currents in an iron circuit of the solenoid valve and in the capsule, wherein the eddy currents are operable to heat up the fluid in the valve cartridge, and wherein the coil winding is configured to be arranged in a bridge branch of an H-bridge circuit, the H-bridge circuit including four switching transistors.