Spring device for spring-mounting a functional unit of an electrical appliance, and method for influencing a spring device of this kind

That which is claimed: 1. Spring device for suspending or for spring-mounting a functional unit of an electrical appliance, wherein said spring device has: at least one main spring means and at least one additional spring means, and coupling means for coupling said at least one additional spring means to a portion of said spring device, wherein at least one of: said at least one spring means has a spring constant or spring properties which are temperature-dependent and are variable by a temperature effect on said at least one spring means, or said coupling means are designed in a temperature-dependent manner in such a way that said coupling means vary their coupling effect between said at least one additional spring means and said spring device by a temperature effect, and wherein heating means are provided for at least one of said at least one main spring means, said at least one additional spring means, or said coupling means for the purpose of warming up at least one of said at least one main spring means, said at least one additional spring means, or said coupling means and for the purpose of changing at least one of said spring properties or said coupling effect thereof. 2. Spring device according to claim 1 , wherein at least one of said at least one main spring means or said at least one additional spring means is a metal spring, which is in a portion at least partially composed of a metal alloy with a temperature-dependent memory effect. 3. Spring device according to claim 2 , wherein said heating means are designed for heating said portion composed of said metal alloy with said memory effect with a subsequent change in said spring constant or said spring properties due to said heating and warming up. 4. Spring device according to claim 2 , wherein at least one of said at least one main spring means or said at least one additional spring means is a helical spring. 5. Spring device according to claim 2 , wherein said at least one additional spring means is at least partially composed of said metal alloy with said temperature-dependent memory effect. 6. Spring device according to claim 2 , wherein said heating means are directly connected to a portion composed of said metal alloy with said temperature-dependent memory effect. 7. Spring device according to claim 1 , wherein at least one of said at least one additional spring means or said at least one main spring means are a pneumatic spring with an air volume, wherein said air volume is located in an air chamber. 8. Spring device according to claim 7 , wherein said heating means are associated with said air chamber for heating said air volume. 9. Spring device according to claim 7 , wherein said heating means are arranged on an outside of said air chamber or are mounted onto an outer side of said air chamber. 10. Spring device according to claim 7 , wherein a piston is arranged in the air chamber, said piston being able to be moved along said air chamber, and said piston separating off said air volume. 11. Spring device according to claim 7 , wherein a piston is arranged in said air chamber, said piston being able to be moved along said air chamber, and said piston separating said air chamber into a first air volume and into a second air volume, said piston is arranged between said first air volume and said second air volume, said first air volume and said second air volume are closed off, at least one of said first air volume or said second air volume are heatable by means of said heating means. 12. Spring device according to claim 11 , wherein: said heating means comprises a first heating means and a second heating means, the first and second heating means being configured for independent activation relative to one another; said first heating means is provided for said first air volume; and said second heating means is separately provided for said second air volume. 13. Spring device according to claim 1 , wherein said heating means have a resistance heating element. 14. Spring device according to claim 13 , wherein said heating means have a resistance heating element in the form of a flat heating element. 15. Spring device according to claim 14 , wherein said flat heating element is a thick-layer heating element. 16. Spring device according to claim 1 , wherein said spring device has a damping device on said functional unit. 17. Method for influencing a spring device according to claim 1 in an electrical appliance comprising a movable functional unit being spring-mounted by means of said spring device, wherein said functional unit of said electrical appliance is spring mounted by means of said spring device and has a resonant frequency, wherein at least one of: at least one of said at least one main spring means or said at least one additional spring means of said spring device is heated for changing its spring properties, or said coupling means are heated for changing a coupling effect between at least one of said at least one main spring means or said at least one additional spring means and said spring device. 18. Method according to claim 17 , wherein varying at least one of said spring properties or said coupling effect is not performed continuously but rather in steps. 19. Method according to claim 18 , wherein varying at least one of said spring properties or said coupling effect is performed in steps with a total of only two steps of 0% and 100%. 20. Method according to claim 17 , wherein, when said resonant frequency is reached, said spring properties are changed in such a way that said spring constant of at least one of said at least one main spring means or said at least one additional spring means is increased by at least 5%. 21. Method according to claim 17 , wherein, when a frequency of movement has reached at least 80% of said resonant frequency, said spring properties are changed in such a way that said spring constant of at least one of said at least one main spring means or said at least one additional spring means is increased by at least 5%. 22. Method according to claim 17 , wherein, when a frequency has reached at least 80% of said resonant frequency, said coupling effect is greatly increased in such a way that at least one of said at least one main spring means or said at least one additional spring means spring means is fully effectively coupled to said spring device or connected to said spring device. 23. Method according to claim 22 , wherein said coupling effect is greatly increased in such a way that at least one of said at least one main spring means or said at least one additional spring means spring means is rigidly coupled and connected to said spring device. 24. Spring device for suspending or for spring-mounting a functional unit of an electrical appliance, wherein said spring device has: at least one spring means, and coupling means for coupling said at least one spring means to another portion of said spring device, wherein at least one of: said at least one spring means has a spring constant or spring properties which are temperature-dependent and are variable by a temperature effect on said at least one spring means, or said coupling means are designed in a temperature-dependent manner in such a way that said coupling means vary their coupling effect between said at least one spring means and said spring device by a temperature effect, and wherein: heating means are provided for at least one of said at least one spri