Turbomachine chemical reactor and method for cracking

What is claimed is: 1. A chemical reactor comprising: a housing having: a housing inlet; a housing exit; and an annular housing passage, which defines a unidirectional, axial flow path from the housing inlet to the housing exit, for receiving a process fluid therein; a rotary shaft, in the housing, circumscribed by the annular housing passage, for coupling to a shaft-rotating power source, the rotary shaft defining a shaft centerline axis that is in fixed orientation in the housing and congruent with its axis of rotation; a first axial impulse impeller and a second axial impulse impeller commonly mounted about the rotary shaft within the annular housing passage and in fluid communication with process fluid flowing between the inlet and exit of the housing, the first and second axial impulse impellers axially spaced from one another, with trailing edges of the first axial impulse impeller facing leading edges of the second axial impulse impeller; a row of stationary turning bucket vanes interposed between the first and second axial impulse impellers for aligning process fluid flow discharged from trailing edges of the first impeller parallel to leading edges of the second impeller; each impeller having: an impeller hub with an axial length extending axially along the shaft centerline axis of the rotary shaft; a row of a plurality of impeller blades projecting outwardly from the impeller hub, each of the impeller blades respectively having: a leading edge facing the housing inlet, a trailing edge facing the housing exit, a blade tip distal the impeller hub in opposed, spaced relationship with the annular housing passage, and opposed concave and convex blade sidewalls between the blade tip and the leading and trailing edges thereof; the impeller blades configured, upon rotation of the rotary shaft, to turn the flow of the process fluid tangentially relative to the shaft centerline axis from a first tangential direction at the blade leading edge to an opposite tangential direction at the blade trailing edge, and impart energy therein to discharge the process fluid from their respective trailing edges therefrom, at a velocity greater than Mach 1; a static annular diffuser in the annular housing passage, oriented between the second axial impulse impeller and the exit of the housing, the static annular diffuser having a row of a plurality of radially oriented, circumferentially spaced diffuser passages spanning the annular housing passage; each of the diffuser passages having: a first axial end facing the second axial impulse impeller, and a second axial end facing the housing exit, local cross section of each diffuser passage increasing from its first axial end to its second axial end; the diffuser passages configured to decelerate process fluid flowing through the diffuser passages, discharged from the impeller blades, to a speed less than Mach 1, and generating within the diffuser passages a shock wave in the process fluid and sufficiently raising temperature of the process fluid downstream of the shock wave to crack molecules in the process fluid, prior to discharge of the process fluid from the exit of the housing; and circumferentially spaced turning vanes in the annular housing passage, oriented between the static annular diffuser and the exit of the housing, the respective turning vanes having a leading edge facing the static annular diffuser and a trailing edge facing the exit of the housing, opposed pairs of turning vanes defining a turning vane throat there between, local cross section of each turning vane throat decreasing from its respective pair of opposed, turning-vane leading edges to its respective pair of opposed, turning-vane trailing edges. 2. The chemical reactor of claim 1 , wherein the respective circumferentially spaced, diffuser passages are defined between a shroud wall of the annular housing passage and helical diffuser vanes, the diffuser vanes having opposed, radially outwardly directed vane side walls separated by a hub wall; local cross section of the respective diffuser passages defined by vane throat width between opposing, adjoining vanes and vane throat height from the hub wall to the shroud wall of the annular housing passage, with either or both respective diffuser passage throat width and/or height increasing from the first axial end to the second axial end of the diffuser passage. 3. The chemical reactor of claim 1 , further comprising a process-fluid quenching zone axially downstream of the second axial impulse impeller, for introduction of coolant fluid into the process fluid, in order to stabilize temperature of the process fluid; or for introduction of anti-fouling fluid into the process fluid, in order to inhibit fouling within the diffuser passages. 4. A system comprising: at least two of the chemical reactors of claim 1 , sequentially coupled, with process fluid discharged by the turning vanes of one reactor in fluid communication with the first axial impulse impeller of another reactor, where the respective reactors are in separate respective housings or in a shared common housing. 5. The chemical reactor of claim 1 , wherein each axial impulse impeller comprises a monolithic impeller hub and impeller blades. 6. The chemical reactor of claim 1 , further comprising a process fluid preheater coupled to the housing inlet, for preheating process fluid prior to introduction into the reactor; the process fluid preheater including: a preheating impulse impeller for accelerating the process fluid to a velocity greater than Mach 1; and a pre-heating static annular diffuser comprising diffuser passages, for decelerating the process fluid flowing therethrough to a speed less than Mach 1, generating a shock wave in the process fluid within the diffuser passages of the pre-heating static annular diffuser, and raising the temperature thereof downstream of the shock wave. 7. A method for cracking comprising: providing a chemical reactor having: a housing having: a shaft centerline axis that is in fixed orientation in the housing; a housing inlet; a housing exit; and an annular housing passage defining a unidirectional, axial flow path for the process fluid from the housing inlet to the housing exit; a first axial impulse impeller and a second axial impulse impeller commonly mounted about the rotary shaft within the annular housing passage to be rotatively driven about an impeller axis of rotation that is congruent with the shaft centerline axis, the first and second axial impulse impellers axially spaced from one another, with trailing edges of the first axial impulse impeller facing leading edges of the second axial impulse impeller; a static annular diffuser within the annular housing passage, having a first axial end facing the second axial impulse impeller and a second axial end facing the exit of the housing, the static annular diffuser defining diffuser passages having locally increasing, cross-sectional area from the first to the second axial end thereof; and circumferentially spaced turning vanes in the annular housing passage, oriented between the static annular diffuser and the exit of the housing, the respective turning vanes having a leading edge facing the static annular diffuser and a trailing edge facing the exit of the housing, opposed pairs of turning vanes defining a turning vane throat there between, local cross section of each turning vane throat decreasing from its respective pair of opposed, turning-vane leading edges to its respective pair of opposed, turning-vane trailing edges; introducing a flow of process fluid into the housing inlet; driving the first and second axial impulse impellers rotatively with a shaft-rotating power source, turning flow of the process fluid tangentially relative to the shaft centerline axis from a fir