The present invention relates generally to control systems for controlling temperatures. More specifically, the invention relates to a temperature control of steam in relation to inter-stage attemperation, which may be used in heat recovery steam generation (HRSG) systems in combined cycle power generation applications.
HRSG systems may produce steam with very high outlet temperatures. In particular, HRSG systems may include superheaters through which steam may be superheated before being used by a steam turbine. If the outlet steam from the superheaters reaches high enough temperatures, the steam turbine, as well as other equipment downstream of the HRSG, may be adversely affected. For instance, high cyclic thermal stress in the steam piping and steam turbine may eventually lead to shortened life cycles. In some cases, due to excessive temperatures, control measures may trip the gas turbine and/or steam turbine. This may result in a loss of power generation that may, in turn, impair plant revenues and operability. Inadequately controlled steam temperatures may also lead to high cyclic thermal stress in the steam piping and steam turbine, affecting their useful life. Conventional control systems have been devised to help monitor and control the temperature of outlet steam from HRSG systems. Unfortunately, these control systems often allow temperatures to overshoot during transient periods where, for instance, inlet temperatures into the superheaters increase rapidly.
Conversely, while trying to control high outlet steam temperatures, there are other potential adverse attemperation control effects. There is a danger of causing the temperature to go too low resulting in subsaturated attempertor fluid flowing through the superheaters, interconnecting piping, or steam turbine. Control stability problems can also use cyclic life of the steam system downstream of the attemperator as well as effect the life of the attemperation system valves, pumps, etc.
In particular, a non-model-based technique commonly used consists of a control structure where an outer loop creates a set point temperature for steam entering the finishing high-pressure superheater based on a difference between a desired and an actual steam temperature exiting the finishing high-pressure superheater. An outer loop proportional-integral-derivative (PID) controller may establish the set point temperature for an inner loop PID controller. The inner loop of the control logic may drive the control valve based on the difference between the actual and set point temperature to suitably reduce the steam temperature before it enters the finishing high-pressure superheater. Unfortunately, this technique may not always work to control steam temperature overshoots during transient changes in the gas turbine output. In addition, this technique may often require a great deal of tuning in order to verify satisfactory operation during all potential transients.
Regarding the overshoot problem with the non-model-based technique, as the temperature of the exhaust gas from the gas turbine increases, the temperature of the steam exiting the finishing high-pressure superheater may not only increase beyond the set point temperature, but may continue to overshoot a maximum allowable temperature even after the temperature of the exhaust gas begins to decrease. This overshoot problem may be due in part to the presence of significant thermal lag caused by the mass of metal used in the finishing high-pressure superheater. Other factors affecting attemperation may include the type and sizing of attemperation valves, operating conditions of the attemperator fluid supply pump, distances between equipment used, other limitations of equipment used, sensor location and accuracy, and so forth. This overshoot problem may also become more acute when the gas turbine exhaust temperature changes rapidly.
The conventional attemperator control logic requires an interactive and long tuning cycle. The model-based predictive technique consists of a cascading control structure where the outer loop (some combination of feedback and feed-forward) creates a set point temperature for steam entering the finishing superheater (FSH) (i.e. at the inlet of FSH) based on the difference between a desired and actual steam temperature exiting the finishing superheater (FSH). The inner loop drives the attemperator valves based on the difference between the actual and set point temperature for the inlet to the FSH to suitably reduce the steam temperature before it enters the FSH. Due to the presence of a cascade control structure the control tuning is not easy as the changes in one controller affect the performance of the other. This necessitates an interactive and long tuning cycle. Due to a competitive market and tight commissioning schedules such a controller can end up being less than optimally tuned, thus adversely affecting the long term performance of the whole system.
Accordingly, there is a need for an improved temperature control system in heat recovery systems which is easily tunable to be stable, and also prevents large temperature overshoots, and prevents the flow of subsaturated attempertor fluid through the steam system downstream of the attemperator.
In accordance with an embodiment of the invention, a heat recovery steam generation system is provided. The heat recovery steam generation system includes at least one superheater in a steam path for receiving a steam flow and configured to produce a superheated steam flow. The system also includes an inter-stage attemperator for injecting an attemperation fluid into the steam path. The system further includes a control valve coupled to the inter-stage attemperator. The control valve is configured to control flow of attemperation fluid to the inter stage attemperator. The system also includes a controller coupled to the control valve and the inter-stage attemperator. The controller further includes a feedforward controller and a trimming feedback controller. The feedforward controller is configured to determine a desired amount of flow of the attemperation fluid and the trimming feedback controller is configured to compensate for inaccuracies in the determined amount of flow of the attemperation fluid to determine a net desired amount of flow of attemperation fluid through the control valve into an inlet of the inter-stage attemperator based upon an outlet temperature of steam from the superheater. The controller also determines a control valve demand based upon the flow to valve characteristics. The controller further manipulates the control valve of the inter-stage attemperator, and injects the desired amount of attemeration flow via the inter-stage attemperator to perform attemperation upstream of an inlet into the superheater.
In another embodiment, a method for controlling outlet temperatures of steam from a finishing superheater of a heat recovery steam generation system is provided. The method includes determining a desired amount of flow of an open loop attemperation fluid via a feedforward controller. The method also includes compensating for inaccuracies in the determined amount of flow of the open loop attemperation fluid via a trimming feedback controller to determine a net desired amount of flow of attemperation fluid through a control valve into an inlet of an inter-stage attemperator based upon an outlet temperature of steam from a finishing superheater of a heat recovery steam generation system. The method also includes determining the control valve demand based upon attemperation flow to valve characteristics. The method further includes manipulating the control valve of the inter-stage attemperator and injecting the desired attemperation amount to perform attemperation upstream of an inlet into the finishing superheater.
In accordance with an embodiment of the invention, a controller is provided. The controller is coupled to the control valve and the inter-stage attemperator. The controller further includes a feedforward controller and a trimming feedback controller. The feedforward controller is configured to determine a desired amount of flow of the attemperation fluid and the trimming feedback controller is configured to compensate for inaccuracies in the determined amount of flow of the attemperation fluid to determine a net desired amount of flow of attemperation fluid through the control valve into an inlet of the inter-stage attemperator based upon an outlet temperature of steam from the superheater. The controller also determines a control valve demand based upon the flow to valve characteristics. The controller further manipulates the control valve of the inter-stage attemperator, and injects the desired amount of attemeration flow via the inter-stage attemperator to perform attemperation upstream of an inlet into the superheater.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
The present techniques are generally directed to a control system and method for controlling operation of an inter-stage attemperation system upstream of the finishing superheater, further controlling the outlet temperature from the finishing superheater. The control system includes a feed-forward and a feedback control and employs valve characteristics calculation for converting attemperating flow to valve demand for controlling temperature. In particular, embodiments of the control system may determine if attemperation is desired based on whether the outlet temperature of steam from the finishing superheater exceeds a set point temperature as well as whether the inlet temperature of steam into the finishing superheater approaches or is less than the saturation temperature of steam.
When introducing elements of various embodiments of the present invention, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. Any examples of operating parameters are not exclusive of other parameters of the disclosed embodiments.
The combined cycle power generation system 10 may also include a multi-stage heat recovery steam generator (HRSG) 30. The illustrated HRSG system 30 is a simplified depiction of a general operation of a HRSG system and is not intended to be limiting. Exhaust gases 32 from the gas turbine 12 may be used to heat steam in HRSG 30. Exhaust from the low-pressure stage 24 of the steam turbine 20 may be directed into a condenser 34. Condensate from the condenser 34 may, in turn, be directed into a low-pressure section of the HRSG 30 with the aid of a condensate pump 36. The condensate may flow first through a low-pressure economizer 38 (LPECON), which LPECON 38 may be used to heat the condensate and then may be directed into a low-pressure drum 40. The condensate may be drawn into a low-pressure evaporator 42 (LPEVAP) from the low-pressure drum 40, which LPEVAP 42 may return steam to the low-pressure drum 40. The steam from the low-pressure drum 40 may be sent to the low-pressure stage 24 of the steam turbine 20. Condensate from the low-pressure drum 40 may be pumped into an intermediate-pressure economizer 44 (IPECON) by an intermediate-pressure boiler feed pump 46 and then may be directed into an intermediate-pressure drum 48. The condensate may be drawn into an intermediate-pressure evaporator 50 (IPEVAP) from the intermediate-pressure drum 48, which IPEVAP 50 may return steam to the intermediate-pressure drum 48. The steam from the intermediate-pressure drum 48 may be sent to the intermediate-pressure stage 26 of the steam turbine 20. Condensate from the low-pressure drum 40 may also be pumped into a high-pressure economizer 52 (HPECON) by a high-pressure boiler feed pump 54 and then may be directed into a high-pressure drum 56. The condensate may be drawn into a high-pressure evaporator 58 (HPEVAP) from the high-pressure drum 56, which HPEVAP 58 may return steam to the high-pressure drum 56.
Finally, steam exiting the high-pressure drum 56 may be directed into a primary high-pressure superheater 60 and a finishing high-pressure superheater 62, where the steam is superheated and eventually sent to the high-pressure stage 28 of the steam turbine 20. Exhaust from the high-pressure stage 28 of the steam turbine 20 may, in turn, be directed into the intermediate-pressure stage 26 of the steam turbine 20, and exhaust from the intermediate-pressure stage 26 of the steam turbine may be directed into the low-pressure stage 24 of the steam turbine 20. In certain embodiments, a primary and secondary re-heater may also be used with the primary high-pressure superheater 60 and the finishing high-pressure superheater 62. Again, the connections between the economizers, evaporators, and the steam turbine may vary across implementations as the illustrated embodiment is merely illustrative of the general operation of an HRSG system.
To maintain the efficiency of the processes of HRSG systems and the life of the steam turbine 20 including the associated equipment, a superheater and re-heater inter-stage attemperation may be used to achieve robust temperature control of the steam leaving the HRSG 30. An inter-stage attemperator 64 may be located in between the primary high-pressure superheater 60 and the finishing high-pressure superheater 62. The inter-stage attemperator 64 enables more robust control of the outlet temperature of steam from the finishing high-pressure superheater 62. The inter-stage attemperator 64 may be controlled by a simple loop attemperation control for more precisely controlling the steam outlet temperature from the finishing high-pressure superheater 62. The inter-stage attemperator 64 may, for instance, control the temperature of steam by enabling cooler, high-pressure feedwater, such as a feedwater spray into a steam path when appropriate. Again, although not illustrated in
As illustrated in
At step 82, an anti-quench attemperator fluid flow WQ may be determined based on whether the inlet temperature Tin as shown in
Therefore, even if it is determined in step 76 that attemperation may be desirable in order to keep the outlet temperature Tout of steam under the set point temperature Tsp, attemperation may be bypassed in order to maintain the steam temperature sufficiently above the saturation point. In other words, the outlet temperature Tout of steam may be allowed to temporarily rise above the set point temperature Tsp. At step 84, it is determined whether the anti-quench attemperator fluid flow WQ is desired to be included with the attemperation fluid flow WT.
At step 86, the valve demand is determined based upon the flow demand, valve coefficient, density and change in pressure in the inlet of the inter-stage attemperator and at inlet of the finishing superheater. The control valve demand may be defined as a flow which is a function of the valve lift of a control valve while compensating for pressure variation, density, or corrected flow based on feed forward and feed back, and saturation limitations. Finally, at step 88 the process of attemperation may be performed upstream of the inlet into the finishing high-pressure superheater 62 in order to reduce the inlet temperature Tin of steam such that the outlet temperature Tout can be maintained to desired level. As discussed above with respect to
In one embodiment, the feed-forward value may be determined using model-based predictive techniques, such as, but not limited to, a steady state first principle thermodynamic model. Thus, the controller may be a model-based predictive temperature control logic including an empirical data-based model, a thermodynamic-based model, or a combination thereof. This model-based predictive temperature control may further comprise a proportional-integral controller configured to compensate for inaccuracies in a predictive temperature model. In another embodiment, the feed-forward value may be determined using a physical model such as a first principle physics model. In yet another embodiment, the feed-forward value may be determined using a model based on table look-up or regression based input-output map. The PI trimming feedback controller 96 used in parallel with the feed-forward controller 92 has parallel control paths forming a single loop. However, the exact control elements and control paths may vary among implementations as the illustrated control elements and paths are merely intended to be illustrative of the disclosed embodiments.
Further, the corrected flow demand WT signal is received by a control selector and an override controller 104. As discussed above with respect to
In one embodiment, the control selector and override control 104 may take control of an output from one loop to allow a more important loop to manipulate the output. The override controller 104 not only selects signals from multiple signals being received by it from multiple controllers but also reverts to signal the PI quench controller 108 to stop integrating or winding up. Therefore, the control selector and override controller 104 avoids the wind up problem associated to the PID controls. If the inlet temperature Tin is already below Tsat+Δ, the adjusted attemperator water flow may be overridden by the control selector and override controller 104. Thus, the controller structure 90 is configured to bypass attemperation whenever an inlet temperature of steam into the finishing superheater 62 does not exceed a saturation temperature of steam by a pre-determined safety value. The saturation temperature Tsat of steam into the finishing high-pressure superheater 62 may be calculated based upon, among other things, the inlet pressure Pin of steam flowing into the finishing high-pressure superheater 62. This calculation may be made based on some function of pressure, for instance, via steam tables. Once the saturation temperature Tsat of steam into the finishing high-pressure superheater 62 is calculated, this value plus some safety value Δ may be used by the anti-quench controller 108 to determine the flow signal WQ to the control selector and an override controller 104.
Furthermore, valve demand may be determined based on the flow demand and valve characteristics which in turn is based upon valve coefficient, density and change in pressure across the attemperator valve, thereby operating the control valve 68 to either increase or decrease the amount of attemperation at the inter-stage attemperator 64, which in turn, may affect the inlet temperature Tin of steam at the inlet of the finishing high-pressure superheater 62. In one embodiment, the control valve 68 may be accompanied with a linearization function block to make the loop gain generally constant. This approach may allow for simplified tuning (e.g., requiring tuning only at one load) and consistent loop response over the load range. Linearization of the control valve 68 responses in this manner may also prove particularly useful when operating a large plant with heavy load variation where the loop gain changes significantly across the load range.
Advantageously, the present invention uses a simple loop structure with a feed forward controller to give a flow, which is then converted to the precise valve demand for attemperation using the valve characteristics. Thus, the thermal lag associated with the additional PI controller of inner loop as used in the present system is done away with. Thereby, the present invention has considerably smaller induced thermal lag. Also, the other advantage is that the tuning parameters are less owing to the simple loop structure in the system. In today's competitive market and tight commissioning schedules such controller normally would be more preferred as it can be optimally tuned in a shorter time, thus enhancing the performance of the whole system.
Moreover, while the disclosed embodiments may be specifically suited for inter-stage attemperation of steam, they may also be used in other similar applications such as food and liquor processing plants. Further, the concept of using a single controller instead of a cascade controller is applicable at almost all places where the inner loop is very fast compared to the outer loop and the control variable associated with the inner loop is not required to be regulated or tracked to some desired value.
As discussed above, the disclosed embodiments may be utilized in many other scenarios other than the control of outlet steam temperatures. For instance, the disclosed embodiments may be used in virtually any system where a fluid is to be heated, or cooled for that matter, using a heat transfer device. Whenever it may be important to control the outlet temperature of the fluid from the heat transfer device, the disclosed embodiments may utilize model-based predictive techniques to predict the outlet temperature based on inlet conditions into the heat transfer device. Then, using the predicted outlet temperature with the disclosed embodiments, attemperation of the inlet temperature into the heat transfer device may be performed to ensure that the actual outlet temperature from the heat transfer device stays within an acceptable range (e.g., below a set point temperature or above a saturation temperature). Furthermore, control of the model-based prediction and attemperation process may be performed using the techniques as described above. Therefore, the disclosed embodiments may be applied to a wide range of applications where fluids may be heated or cooled by heat transfer devices.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
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