Dry gas seal cooling arrangement and method

What we claim is: 1. A shaft seal arrangement for a rotatable turbomachine shaft having a rotation axis, comprising: a rotor part that rotates during operation; a stationary part; a dry gas seal comprising at least one rotary element having a rotary sealing surface and arranged for rotation with the rotor part and at least one stationary element in a fixed relationship with the stationary part and having a stationary sealing surface, the rotary sealing surface and the stationary sealing surface being resiliently biased one against the other; a dry gas delivery path configured for delivering dry sealing gas between the stationary sealing surface and the rotary sealing surface; at least one cooling fluid volume comprising a cooling fluid chamber extending around the rotation axis of the shaft for receiving a cooling fluid and in heat exchange relationship with the dry gas seal; and a venting arrangement configured for collectively venting exhaust cooling fluid and dry sealing gas from the shaft seal arrangement. 2. The shaft seal arrangement of claim 1 , wherein venting arrangement comprises a venting chamber, in fluid communication with the cooling volume and with the dry gas seal, collecting exhaust cooling fluid and dry sealing gas. 3. The shaft seal arrangement of claim 1 , further comprising a liquid drainage arrangement, fluidly coupled to the cooling fluid volume, configured and arranged for draining cooling fluid in a liquid state from said cooling fluid volume. 4. The shaft seal arrangement of claim 1 , wherein the venting arrangement is fluidly coupled to a venting chamber located between a first additional shaft seal and a second additional shaft seal. 5. The shaft seal arrangement of claim 1 , wherein the cooling fluid chamber is further arranged adjacent the stationary element and opposite the rotary element of the dry gas seal. 6. The shaft seal arrangement of claim 5 , wherein at least one cooling fluid port is arranged in the cooling fluid chamber and oriented to generate at least a cooling fluid jet impinging against the rotary part of the shaft seal arrangement. 7. The shaft seal arrangement of claim 6 , wherein the at least one cooling fluid port comprises a plurality of cooling fluid ports provided in a circular arrangement around the axis of the shaft, and oriented to generate a plurality of cooling fluid jets impinging against the rotary part of the shaft seal arrangement. 8. The shaft seal arrangement of claim 6 wherein the shaft seal arrangement has a high-temperature axial end and a low-temperature axial end, and wherein the the at least one cooling fluid port is arranged between the dry gas seal and the high-temperature axial end of the shaft seal arrangement. 9. The shaft seal arrangement of claim 1 , wherein the cooling fluid volume comprises an external cooling fluid chamber surrounding the stationary part of the shaft seal arrangement. 10. The shaft seal arrangement of claim 9 wherein the external cooling fluid chamber extends around the dry gas seal. 11. The shaft seal arrangement of claim 1 , wherein the pressure of the dry sealing gas and of the cooling fluid are such that dry sealing gas flows from the dry gas seal towards the cooling fluid volume. 12. A turbomachine arrangement comprising: a turbomachine, wherein a working fluid is processed and comprised of: a casing, a shaft arranged for rotation in the casing, at least one impeller mounted on the shaft and a shaft seal arrangement according to claim 1 ; and a cooling fluid source fluidly coupled to the shaft seal arrangement and delivering cooling fluid thereto. 13. The turbomachine arrangement of claim 12 , wherein the vapor venting arrangement and the liquid drainage arrangement of the shaft seal arrangement are in fluid communication with the cooling fluid source. 14. The turbomachine arrangement of claim 12 , wherein the cooling fluid is working fluid processed by the turbomachine, or a fluid compatible therewith. 15. A power conversion system comprising: a working fluid circuit having a high pressure side and a low pressure side and configured to flow a working fluid therethrough; a cooler arranged and configured to remove heat from the working fluid in the low pressure side of the working fluid circuit; a pump or compressor fluidly coupled to the working fluid circuit between the low pressure side and the high pressure side thereof, configured to rise the pressure of the working fluid in the working fluid circuit; a heat exchanger configured to circulate the working fluid in heat exchange relationship with a hot fluid, to vaporize the working fluid; and a turboexpander fluidly coupled to the working fluid circuit and disposed between the high pressure side and the low pressure side thereof, configured to expand working fluid flowing therethrough and generating mechanical power therewith, wherein the turboexpander comprises: a casing, a shaft arranged for rotation in the casing, an impeller mounted on the shaft for rotation therewith and a shaft seal arrangement according to claim 1 to sealingly co-act with the shaft of the turboexpander. 16. The power conversion system of claim 15 , wherein the shaft seal arrangement is fluidly coupled to the high pressure side of the working fluid circuit, downstream of the pump or compressor. 17. The power conversion system of claim 16 , wherein the vapor venting arrangement and the drainage arrangement are fluidly coupled to the low pressure side of the working fluid circuit. 18. The power conversion system of claim 17 , wherein the drainage arrangement and the vapor venting arrangement are fluidly coupled to the cooler.