Ultrasound probe with optimized thermal management

The invention claimed is: 1. An ultrasound probe comprising: a) a housing; b) a transducer assembly operable to transmit ultrasonic energy towards a zone of the probe adapted to be acoustically coupled to an object or area of interest; c) a cooling system comprising a heat transfer device arranged to transfer heat generated by the transducer assembly to one or more regions or areas located outside such transducer assembly, characterized in that such heat transfer device comprises graphene. 2. Probe according to claim 1 , wherein the transducer assembly comprises one or more transducer elements operable to generate ultrasound waves, the heat transfer device comprising one or more layers of graphene arranged to form a heat transfer layer placed between such transducer elements and the coupling zone of the probe. 3. Probe according to claim 2 , wherein the transducer assembly comprises one or more acoustic matching layers, the heat transfer layer being one of such matching layers. 4. Probe according to claim 3 , wherein the layers are arranged as a stack starting from the transducer elements, the heat transfer layer being the furthest from the transducers elements towards the coupling zone of the probe. 5. Probe according to claim 1 , wherein the heat transfer layer has a thickness not greater than a ¼ of the wavelength of the ultrasound waves the probe is configured to generate. 6. Probe according to claim 1 , wherein the heat transfer device comprises a composite obtained from graphene and resin in the form of stripes of graphene interleaved with stripes of resin or layer of graphene with holes filled with resin. 7. Probe according to claim 1 , wherein the cooling system comprises a heat dissipating and/or storing device in thermal communication with the heat transfer device. 8. Probe according to claim 7 , wherein the transducer assembly comprises a backing element located on the rear side of transducer elements opposite to the emitting surface, the backing element comprising graphene, particularly a resin charged with graphene, to improve thermal exchange with the heat dissipating and/or storing device. 9. Probe according to claim 7 , wherein the heat storing device ( 7 , 103 ) is a thermostating device based on Phase Change Material (PCM), able to absorb heat maintaining the temperature constant. 10. Probe according to claim 7 , wherein the heat storing device comprises graphene, such heat storing device being arranged to fill available spaces inside the probe housing to temporarily store heat drained away from the transducer assembly. 11. Probe according to claim 7 , wherein the heat storing device comprises a composite material including a PCM and a filler charged with graphene. 12. Probe according to claim 11 , wherein the filler is a resin, such as an epoxy resin, charged with graphene, the PCM being micro-encapsulated by such graphene-charged resin. 13. Probe according to claim 7 , wherein the heat storing device is an organic reversible PCM that accumulates heat in the form of latent heat while changing phase from solid to liquid and releases accumulated heat when changing phase from liquid to solid. 14. Probe according to claim 1 , wherein the transducer assembly comprises matching/heat transfer layer located between the frontal emitting surface and the coupling zone of the probe and a backing element located on the rear side of transducer elements opposite to the emitting surface, a heat dissipating and/or storing device being located between the backing element and the housing opposite to the coupling zone of the probe to receive heat from the heat transfer layer and/or the backing element. 15. Probe according to claim 14 , wherein the heat dissipating and/or storing device is in thermal communication with the heat transfer layer via a heat transfer circuit comprising a conductive material located in the housing. 16. Probe according to claim 15 , wherein the heat transfer layer and the heat transfer circuit are formed of graphene. 17. Probe according to claim 1 , wherein the heat transfer device comprises a layer of graphene located between the transducer elements and the coupling zone of the probe, the layer being peripherically bended to form a longitudinal path extending laterally from the front to the rear of the probe. 18. Probe comprising a housing, a transducer assembly operable to transmit ultrasonic energy towards a zone of the housing of the probe adapted to be acoustically coupled to a target object or area of interest through an interface comprising an acoustic lens, the transducer assembly comprising transducer elements and one or more matching layers located between the transducer elements and the acoustic lens, the probe comprising a backing material located rearwardly the transducer assembly in direction opposite to the acoustic lens, a support for the backing material, a thermal path for conveying heat from the transducer assembly to the support of the backing material and/or to any other zone located within the housing outside the transducer assembly and arranged to dissipate and/or storage heat, wherein the thermal path is in thermal communication with at least one of the matching layers, such at least one of the matching layers comprising graphene.