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A microturbine system includes a compressor, a recuperator assembly, a combustor, a turbine, and a generator. The recuperator assembly includes a core that preheats compressed air provided by the compressor with exhaust gas from the turbine. The preheated compressed air is mixed with a fuel and burn

A microturbine system includes a compressor, a recuperator assembly, a combustor, a turbine, and a generator. The recuperator assembly includes a core that preheats compressed air provided by the compressor with exhaust gas from the turbine. The preheated compressed air is mixed with a fuel and burned in the combustor. The products of combustion are used to drive the turbine, which in turn drives the compressor and generator. The recuperator core is surrounded by a recuperator housing that is intimate with the recuperator core such that the recuperator housing assumes substantially the same temperature as the recuperator core. The recuperator housing is constructed of materials that have a coefficient of thermal expansion that is substantially equal to that of the recuperator core, and that have thicknesses substantially equal to the thickness of the recuperator core materials. A superstructure supports the recuperator core and resists expansion of the core in a stackwise direction. The superstructure includes tie rods outside of the recuperator housing, and the tie rods are substantially thermally isolated from the heat of the recuperator assembly by insulation.

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A microturbine system includes a compressor, a recuperator assembly, a combustor, a turbine, and a generator. The recuperator assembly includes a core that preheats compressed air provided by the compressor with exhaust gas from the turbine. The preheated compressed air is mixed with a fuel and burn

A microturbine system includes a compressor, a recuperator assembly, a combustor, a turbine, and a generator. The recuperator assembly includes a core that preheats compressed air provided by the compressor with exhaust gas from the turbine. The preheated compressed air is mixed with a fuel and burned in the combustor. The products of combustion are used to drive the turbine, which in turn drives the compressor and generator. The recuperator core is surrounded by a recuperator housing that is intimate with the recuperator core such that the recuperator housing assumes substantially the same temperature as the recuperator core. The recuperator housing is constructed of materials that have a coefficient of thermal expansion that is substantially equal to that of the recuperator core, and that have thicknesses substantially equal to the thickness of the recuperator core materials. A superstructure supports the recuperator core and resists expansion of the core in a stackwise direction. The superstructure includes tie rods outside of the recuperator housing, and the tie rods are substantially thermally isolated from the heat of the recuperator assembly by insulation. e step of identifying includes the steps of: identifying the integer portion of the average period; identifying drift in the integer portion; determining when the drift exceeds a threshold value; and modifying the integer portion to compensate for the drift when the drift exceeds the threshold value. 3. The method of claim 2 wherein the step of identify drift includes the steps of: identifying a modulus-N residual corresponding to the N preceding trigger pairs as a lag value; and adding the lag value to a lag count. 4. The method of claim 3 wherein the step of determining when drift exceeds a threshold value includes the steps of determining when the lag count exceeds N. 5. The method of claim 4 wherein, when the step of modifying the integer portion includes, when the lag count exceeds N, incrementing the integer portion by one. 6. The method of claim 5 further including the step of, when the lag count exceeds N, identifying a modulus-N residual corresponding to the lag count and setting the lag count equal to the residual corresponding to the lag count. 7. The method of claim 2 wherein the trigger signal is a binary signal including a high time followed by a low time and where the step of generating the final trigger signal further includes dividing the integer portion by two to generate a half period, rounding the half period up and down to generate ceiling and floor periods, respectively, setting a one of the low and high times equal to one of the floor and ceiling periods and setting the other of the low and high times equal to the other of the floor and ceiling periods. 8. The method of claim 7 wherein the steps of setting the low and high times includes setting the high time equal to the floor period and setting the low time equal to the ceiling period. 9. The method of claim 1 wherein N includes the N immediately preceding pulse pairs. 10. The method of claim 1 wherein N corresponds to a fraction of a complete gantry rotation. 11. The method of claim 10 wherein N corresponds to 3 to 50 percent of a complete gantry rotation. 12. A method for use with a CT system including a gantry mounted position encoder that provides a digital encoder position signal including signal pulses that indicate gantry positions, the system including a phase locked loop (PLL) that receives the position signal and generates an intermediate trigger signal every X/Y position signals, each two consecutive intermediate trigger signals comprising a trigger pair, the method comprising the steps of: beginning with the first trigger pair and working toward the last trigger pair in the intermediate signal, for each trigger pair: identifying the integer portion of an average period corresponding to N preceding trigger pairs; identifying a modulus-N residual corresponding to the N preceding trigger pairs as a lag value; adding the lag value to a lag count; determining when the lag count exceeds N and, where the lag count exceeds N: (i) incrementing the integer portion by one; (ii) identifying a modulus-N residual corresponding to the lag count; (iii) setting the lag count equal to the residual corresponding to the lag count; and generating a final binary trigger signal including a high time followed by a low time, the step of generating including, dividing the integer portion by two to generate a half period, rounding the half period up and down to generate ceiling and floor periods, respectively, setting one of the low and high times equal to one of the floor and ceiling periods and setting the other of the low and high times equal to the other of the floor and ceiling periods. 13. An apparatus for use with a CT system including a gantry mounted position encoder that provides a digital encoder position signal including signal pulses that indicate gantry positions, the system including a phase locked loop (PLL) that receives the position signal and generates an intermediate trigger signal every X/Y position signals, each tw o consecutive intermediate trigger signals comprising a trigger pair, the apparatus comprising: a program running a pulse sequencing program to perform the steps of: beginning with the first trigger pair and working toward the last trigger pair in the intermediate signal, for each trigger pair: identifying an average period corresponding to N preceding trigger pairs; and generating a final trigger signal as a function of the average period. 14. The apparatus of claim 13 wherein the program causes the processor to perform the step of generating by performing the steps of: identifying the integer portion of the average period identifying a modulus-N residual corresponding to the N preceding trigger pairs as a lag value; adding the lag value to a lag count; determining when the lag count exceeds N and, where the lag count exceeds N: (i) incrementing the integer portion by one; (ii) identifying a modulus-N residual corresponding to the lag count; (iii) setting the lag count equal to the residual corresponding to the lag count; and generating a final binary trigger signal corresponding to the integer portion. 15. The apparatus of claim 14 wherein the final trigger signal includes a high time followed by a low time and wherein the program causes the processor to perform the step of generating by dividing the integer portion by two to generate a half period, rounding the half period up and down to generate ceiling and floor periods, respectively, setting one of the low and high times equal to one of the floor and ceiling periods and setting the other of the low and high times equal to the other of the floor and ceiling periods. 16. The apparatus of claim 15 wherein the program causes the processor to perform the steps of setting the low and high times by setting the high time equal to the floor period and setting the low time equal to the ceiling period. 17. The apparatus of claim 14 wherein N includes the N immediately preceding pulse pairs. 18. The apparatus of claim 14 wherein N corresponds to a fraction of a complete gantry rotation. 19. The apparatus of claim 18 wherein N corresponds to 3 to 50 percent of a complete gantry rotation. 59 (19990312)