Method and measurement device for ascertaining the thermal conductivity of a fluid

The invention claimed is: 1. A measurement device for ascertaining a thermal conductivity of a fluid, the measuring device comprising: a fluid volume holding the fluid; a controller; a sensor module disposed in said fluid volume, said sensor module having a supporting body and a plurality of sensor wires each extending freely between two respective contact positions of said supporting body, said supporting body being formed from an insulator material or a semiconductor material, said sensor wires each being formed by an application of a conductive coating on a respective support made from said insulator material or said semiconductor material extending between said respective contact positions of said supporting body, wherein one of said sensor wires serves as a heat source and is able to be energized for heating by said controller; and said controller is set up to capture, via at least two of said sensor wires functioning as temperature sensors and disposed at different distances from said heat source, temperature measurement values that depend on a temperature at each of said temperature sensors, and to ascertain the thermal conductivity in dependence on the temperature measurement values. 2. The measurement device according to claim 1 , wherein said supporting body and each said support for each of said sensor wires are embodied in one piece. 3. The measurement device according to claim 1 , wherein a distance of at least one of said temperature sensors from said heat source is less than 200 μm and/or in that a distance of said temperature sensor that is disposed furthest from said heat source is less than 1 mm. 4. The measurement device according to claim 1 , wherein said controller is set up to energize said heat source during a heating interval with a specified power and to ascertain the thermal conductivity in dependence on the specified power. 5. The measurement device according to claim 1 , wherein the measurement device is set up such that a temperature measurement value is proportional to a temperature increase at a respective said temperature sensor that is caused by energization of said heat source. 6. The measurement device according to claim 1 , wherein: said semiconductor material is silicon; and said conductive coating contains a metal or a metal alloy. 7. The measurement device according to claim 1 , wherein a distance of at least one of said temperature sensors from said heat source is less than 100 μm and/or in that a distance of said temperature sensor that is disposed furthest from said heat source is less than 500 μm. 8. The measurement device according to claim 1 , wherein said controller is set up to ascertain, in dependence on the temperature measurement values, a parameter or a plurality of parameters of a mathematical model that describes a relationship between a distance of a respective one of said temperature sensors from said heat source and a temperature measurement value that is ascertained thereby, or that describes, for at least one pair of said temperature sensors, a relationship between distances of said temperature sensors of said pair of said temperature sensors from said heat source and a difference of temperatures at said temperature sensors of said pair, and to ascertain the thermal conductivity in dependence on at least one said parameter. 9. The measurement device according to claim 8 , wherein the mathematical model is used to describe the relationship between the distance of said temperature sensor or said temperature sensors from said heat source and the temperature measurement value or a difference of the temperatures ascertained by said temperature sensor or said temperature sensors in dependence on a constant heat flow from said heat source to said temperature sensors, wherein the constant heat flow depends on a specified power. 10. The measurement device according to claim 8 , wherein the parameter in dependence on which the thermal conductivity is ascertained is a proportionality factor that describes a relationship between a function that is dependent on the distance of said temperature sensor or of at least one of said temperature sensors from said heat source and the temperature measurement value or a difference of the temperatures. 11. A method for ascertaining a thermal conductivity of a fluid disposed in a fluid volume in which a sensor module is disposed, which comprises the steps of: forming the sensor module with a supporting body and a plurality of sensor wires that each extend freely between two respective contact positions of the supporting body, the supporting body being formed from an insulator material or a semiconductor material, the sensor wires each being formed by an application of a conductive coating on a respective support made from the insulator material or the semiconductor material extending between the respective contact positions of the supporting body; using one of the sensor wires as a heat source which is energized by a controller; capturing temperature measurement values that are dependent on a temperature at a respective temperature sensor by the controller for at least two of the sensor wires that serve as temperature sensors and are disposed at different distances from the heat source; and ascertaining the thermal conductivity in dependence on the temperature measurement values. 12. A measurement device for ascertaining a thermal conductivity of a fluid, the measuring device comprising: a fluid volume holding the fluid; a controller; a sensor module disposed in said fluid volume, said sensor module having a supporting body and a plurality of sensor wires each extending freely between two respective contact positions of said supporting body, said supporting body being formed from a substrate material, said sensor wires each being formed by an application of a conductive coating on a respective support made from said substrate material extending between said respective contact positions of said supporting body, wherein one of said sensor wires serves as a heat source and is able to be energized for heating by said controller; and said controller is set up to capture, via at least two of said sensor wires functioning as temperature sensors and disposed at different distances from said heat source, temperature measurement values that depend on a temperature at each of said temperature sensors, and to ascertain the thermal conductivity in dependence on the temperature measurement values.