Sensor assembly and method for sensing status condition of electrical equipment

The invention claimed is: 1. A sensor assembly for sensing a status condition of a liquid-filled electrical equipment, the sensor assembly comprising: a light source; a first hydrogen detection section, the first hydrogen detection section being optically coupled to the light source for receiving light from the light source, wherein the first hydrogen detection section has a first hydrogen sensitive layer where the received light passes through the first hydrogen sensitive layer in a transmission mode and the first hydrogen sensitive layer abruptly switches an optical response between transmission and reflection with respect to light received at the first hydrogen sensitive layer depending on whether an amount of hydrogen at the first hydrogen sensitive layer is above or below a first threshold; and a first output section optically coupled to the first hydrogen detection section for receiving light having interacted with the first hydrogen sensitive layer such that received light depends on the optical response of the first hydrogen sensitive layer, the first output section being configured for outputting an output signal as a low-hydrogen output signal when the optical response corresponds to an amount of hydrogen below the first threshold, and as a high-hydrogen output signal, different from the low-hydrogen output signal, when the optical response corresponds to an amount of hydrogen above the first threshold, wherein the optical response is at least one of a reflection and a transmission of the first hydrogen sensitive layer, and wherein the first hydrogen detection section is immersed in an insulation liquid. 2. The sensor assembly according to claim 1 , wherein the first output section comprises: a light detector for detecting the received light; and a signal analyser for analysing a detection signal of the light detector, wherein the signal analyser is configured for selectively outputting the low-hydrogen output signal or the high-hydrogen output signal in dependence of the detection signal of the light detector. 3. The sensor assembly according to claim 1 , wherein the first output section comprises: a visual output element configured for displaying at least a portion of light received from the first hydrogen sensitive layer as the output signal. 4. The sensor assembly according to claim 1 , configured such that a wavelength of light radiated from the light source will remain unchanged after having interacted with the first hydrogen sensitive layer. 5. The sensor assembly according to claim 4 , configured for the optical response as a reflection, wherein the first hydrogen detection section is mounted on an end portion of a light guiding substrate, the substrate coupling the first hydrogen detection section to the light source and to the output section. 6. The sensor assembly according to claim 4 , configured for the optical response as a transmission, wherein the first hydrogen detection section is mounted between a light guiding material coupling the first hydrogen detection section to the light source and a light guiding material coupling the first hydrogen detection section to the output section. 7. The sensor assembly according to claim 1 , wherein the first hydrogen detection section is configured for being immersed in an insulation liquid of the electrical equipment. 8. The sensor assembly according to claim 1 , wherein the first hydrogen detection section comprises at least one of: an adhesion layer interposed between the first hydrogen sensitive layer and a light guiding substrate; a catalytic layer adjacent to the first hydrogen sensitive layer, the catalytic layer having a catalyst for splitting up hydrogen molecules to single H atoms; and a protection layer covering the first hydrogen sensitive layer and being selectively permeable for hydrogen but not for, or less for, at least some other component of the insulating liquid. 9. The sensor assembly according to claim 1 , comprising: a second hydrogen detection section having a second hydrogen sensitive layer that changes an optical response to the received light depending on whether an amount of hydrogen dissolved in the insulation liquid is above or below a second threshold. 10. The sensor assembly according to claim 9 , comprising: a third hydrogen detection section having a third hydrogen sensitive layer that changes an optical response to the received light depending on whether an amount of hydrogen dissolved in the insulation liquid is above or below a third threshold. 11. The sensor assembly according to claim 10 , wherein the first and second, and third thresholds are different from each other. 12. The sensor assembly according to claim 1 , wherein the first threshold corresponds to an H content of 50 ppm to 200 ppm in the insulation liquid. 13. The sensor assembly according to claim 1 , wherein the hydrogen sensitive layer comprises: a metal or metal alloy that changes the optical response depending on whether the amount of hydrogen is above or below a first threshold, the metal or metal alloy being at least one of Mg, Pd, Ti, a rare earth element including La, Y, Gd, or an alloy thereof. 14. The sensor assembly according to claim 1 , comprising: a thermostat unit arranged for keeping a temperature of the first hydrogen detection section within a predetermined temperature range. 15. The sensor assembly according to claim 1 , in combination with: a transformer, the sensor assembly sensing a status condition of the transformer, and the sensor assembly being immersed in transformer oil of the transformer as the insulation liquid. 16. A method of sensing a status condition of a liquid-filled electrical equipment, the method comprising: illuminating a first hydrogen detection section being immersed in insulation liquid of the electrical equipment with light, whereby a first hydrogen sensitive layer of the first hydrogen detection section interacts with the light, such that an optical response of the first hydrogen sensitive layer switches abruptly between light passing through in a transmission mode and reflection in respect to light received at the first hydrogen sensitive layer depending on whether an amount of hydrogen dissolved in the insulation liquid is above or below a first threshold; supplying a first output section with the light that has interacted with the first hydrogen sensitive layer, whereby light received by the output section depends on the optical response of the first hydrogen sensitive layer; and if the optical response corresponds to an amount of hydrogen below the first threshold, outputting via the first output section a low-hydrogen output signal, and if the optical response corresponds to an amount of hydrogen above the first threshold, outputting via the first output section a high-hydrogen output signal, different from the low-hydrogen output signal, the optical response being at least one of a reflection and a transmission of the first hydrogen sensitive layer. 17. The sensor assembly according to claim 1 , wherein the first hydrogen detection section comprises a catalytic layer adjacent to the hydrogen sensitive layer that allows facilitating the hydrogen dissociation of hydrogen molecules.