Method and apparatus for automatically index testing a kaplan turbine

US 4,794,544 A
Filed: 03/26/1987
Issued: 12/27/1988
Est. Priority Date: 03/26/1987
Status: Expired due to Fees

First Claim

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1. Method of automatically determining, for a plurality of gross headwater levels and gate positions, optimal operating angles providing peak generating efficiency for variable pitch blades of a Kaplan-type turbine having movable gates, said turbine being controlled by a governor and an electronic 3D cam, said method comprising the steps of:

running the turbine on-cam at, and usnng the governor to control the positions of said gates so as to maintain said turbine at, a predetermined setpoint power generation level;

measuring on-cam values of particular operating parameters of the turbine;

evaluating the measured data to determine whether the turbine is operating in a steady-state condition;

when steady-state operation has been achieved, moving the blades of said turbine through a series of incremental off-cam variations in pitch in both flatter blade angle and steeper blade angle directions;

after making each incremental variation in the pitch of said blades, allowing the governor to reposition the gates so as to return the power generation level of the turbine to the setpoint, monitoring the operation of the turbine to determine when it has returned to steady-state and then measuring values of the particular operating parameters at the new gate-blade operating point;

computing an efficiency value corresponding to each of the measured operating points; and

comparing the efficiency values of the measured operating points to identify a peak value.

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Abstract

Method and apparatus for automatically determining the set of optimal operating angles for the variable pitch blades of a Kaplan-type turbine which has movable gates and is controlled by a governor and an electronic 3D cam. The governor controls the gates so as to maintain the turbine at a predetermined setpoint power generation level, and on-cam values of particular operating parameters of the turbine are measured. When evaluation of the measured data indicates that the turbine is in a steady-state condition, the blades are moved through a series of incremental off-cam variations in pitch. Following each incremental pitch variation of the blades, the governor repositions the gates to return the turbine to the predetermined setpoint power generation level. The operation of the turbine is then monitored, and values of particular operating parameters are measured at the new gate-blade operating point once the turbine has returned to steady-state. An efficiency value is computed for each of the measured operating points and are compared to identify a peak efficiency value.

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29 Claims

1. Method of automatically determining, for a plurality of gross headwater levels and gate positions, optimal operating angles providing peak generating efficiency for variable pitch blades of a Kaplan-type turbine having movable gates, said turbine being controlled by a governor and an electronic 3D cam, said method comprising the steps of:
- running the turbine on-cam at, and usnng the governor to control the positions of said gates so as to maintain said turbine at, a predetermined setpoint power generation level;
  
  measuring on-cam values of particular operating parameters of the turbine;
  
  evaluating the measured data to determine whether the turbine is operating in a steady-state condition;
  
  when steady-state operation has been achieved, moving the blades of said turbine through a series of incremental off-cam variations in pitch in both flatter blade angle and steeper blade angle directions;
  
  after making each incremental variation in the pitch of said blades, allowing the governor to reposition the gates so as to return the power generation level of the turbine to the setpoint, monitoring the operation of the turbine to determine when it has returned to steady-state and then measuring values of the particular operating parameters at the new gate-blade operating point;
  
  computing an efficiency value corresponding to each of the measured operating points; and
  
  comparing the efficiency values of the measured operating points to identify a peak value.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
- - 2. The method of claim 1, wherein steady-state operating condition of the turbine at an operating point is determined by taking a plurality of sets of measurements of each operating parameter at the operating point, each period of time for taking a set of measurements being separated from the other periods by at least a predetermined delay period;
    - computing, for each set, the individual set average value and standard deviation for each parameter and verifying that steady-state has been achieved when one of these computed individual set standard deviations exceed a first set of predetermined limits; and
      
      finally, as a second level, computing the average value and standard deviation of the computed individual set average values for each parameter and verifying that steady-state has been achieved when none of these second-level computed standard deviations exceed a second set of predetermined limits.
  - 3. The method of claim 1, wherein multi-rate sampling techniques are used to measure values of the particular operating parameters.
  - 4. The method of claim 1, wherein the pitch of the blades is varied up to 20% on either side of the on-cam position.
  - 5. The method of claim 1, wherein off-cam incrementation of the pitch of the blades, and the governor-controlled repositioning of the gates, monitoring of steady-state operation, measurement of particular operating parameters and computation of efficiency, are discontinued when an optimal operating point and a plurality of other adjacent operating points are identified which define a corresponding series of efficiency value steps such that on both the flatter-blade-angle and steeper-blade-angle sides of the optimal point there are, receding from the optimal point, at least two consecutive decreasing efficiency value steps.
  - 6. The method of claim 1, wherein the particular operating parameters being measured include headwater level, tailwater level, gate position, blade position, water flow, power generation and the blade position specified by the 3D cam.
  - 7. The method of claim 6, wherein the headwater and tailwater levels are measured by means of pressure transducers which are positioned in the water flow path of the turbine and are located before the turbine inlet and after the turbine outlet, respectively.
  - 8. The method of claim 6, wherein the water flow is determined by means of a differential pressure transducer across a pair of Winter-Kennedy taps located in a spiral flow case through which water flows to the gates and blades of the turbine.
  - 9. The method of claim 6, wherein power generation is measured by means of a watt transducer.
  - 10. The method of claim 6, wherein the gate position is measured by means of a potentiometer coupled to the gates.
  - 11. The method of claim 10, wherein gate position is further measured by means of a transducer installed on a gate servo, and wherein hysteresis in the governor feedback system is determined by comparing the difference between the gate servo transducer and the gate potentiometer.
  - 12. The method of claim 6, wherein blade position is measured by means of a transducer coupled to an oil head of a blade servo.
  - 13. The method of claim 12, wherein the blade position specified by the 3D cam is measured by means of a potentiometer coupled to a stepping motor which moves the blades, and wherein hysteresis of the turbine and accuracy of the blade positioning system may be determined by comparing the difference between the oil head transducer and the blade position specified by the electronic 3D cam.

14. Method of automatically determining, for a plurality of gross headwater levels and gate positions, optimal operating angles providing peak generating efficiency for variable pitch blades of a Kaplan-type turbine having movable gates, said turbine being controlled by a governor and an electronic 3D cam, said method comprising the steps of:
- running the turbine on-cam at, and using the governor to control the positions of said gates so as to maintain said turbine at, a predetermined setpoint power generation level;
  
  measuring nn-cam values of particular operating parameters of the turbine;
  
  evaluating the measured data to determine whether the turbine is operating in a steady-state condition;
  
  when steady-state operation has been achieved, comparing the measured on-cam data with data compiled in a memory of a microprocessor to identify unique on-cam operating points;
  
  upon identifying a unique on-cam operating point, making a series of incremental off-cam variations in the pitch of the blades of the turbine in both flatter blade angle and steeper blade angle directions;
  
  after making each incremental variation in the pitch of the blades, allowing the governor to reposition the gates so as to return the power generation level of the turbine to the setpoint, monitoring the operation of the turbine to determine when it has returned to steady-state and then measuring values of the particular operating parameters at the new gate-blade operating point;
  
  computing an efficiency value corresponding to each of the measured operating points; and
  
  comparing the efficiency values of the measured operating points to identify a peak value.
- View Dependent Claims (15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27)
- - 15. The method of claim 14, wherein steady-state operating condition of the turbine at an operating point is determined by taking a plurality of sets of measurements of each operating parameter at the operating point, each period of time for taking a set of measurements being separated from the other periods by at least a predetermined delay period;
    - computing, for each set, the individual set average value and standard deviation for each parameter and verifying tha steady-state has been achieved when none of these computed individual set standard deviations exceed a first set of predetermined limits; and
      
      finally, as a second level, computing the average value and standard deviation of the computed individual set average values for each parameter and verifying that steady-state has been achieved when none of these second-level computed standard deviations exceed a second set of predetermined limits.
  - 16. The method of claim 14, wherein unique on-cam operating points are identified by using the measured on-cam data to select a preset uniqueness window and then verifying that no previous on-cam operating point has been measured which lies within the selected window.
  - 17. The method of claim 14, wherein multi-rate sampling techniques are used to measure values of the particular operating parameters.
  - 18. The method of claim 14, wherein the pitch of the blades is varied up to 20% on either side of the on-cam position.
  - 19. The method of claim 14, wherein off-cam incrementation of the pitch of the blades, and the governor-controlled repositioning of the gates, monitoring of steady-state operation, mesurement of particular operating parameters and computation of efficiency, are discontinued when an optimal operating point and a plurality of other adjacent operating points are identified which define a corresponding series of efficiency value steps such that on both of the flatter-blade-angle and steeper-blade-angle sides of the optimal point there are, receding from the optimal point, at least two consecutive decreasing efficiency value steps.
  - 20. The method of claim 14, wherein the particular operating parameters being measured include headwater level, tailwater level, gate position, blade position, water flow, power generation and the blade position specified by the 3D cam.
  - 21. The method of claim 20, wherein the headwater and tailwater levels are measured by means of pressure transducers which are positioned in the water flow path of the turbine and are located before the turbine inlet and after the turbine outlet, respectively.
  - 22. The method of claim 20, wherein the water flow is determined by means of a differential pressure transducer across a pair of Winter-Kennedy taps located in a spiral flow case through which water flows to the gates and blades of the turbine.
  - 23. The method of claim 20, wherein power generation is measured by means of a watt transducer.
  - 24. The method of claim 20, wherein the gate position is measured by means of a potentiometer coupled to the gates.
  - 25. The method of claim 24, wherein gate position is further measured by means of a transducer installed on a gate servo, and wherein hysteresis in the governor feedback system is determined by comparing the difference between the gate servo transducer and the gate potentiometer.
  - 26. The method of claim 20, wherein blade position is measured by means of a transducer coupled to an oil head of a blade servo.
  - 27. The method of claim 26, wherein the blade position specified by the 3D cam is measured by means of a potentiometer coupled to a stepping motor which moves the blades, and wherein hysteresis of the turbine and accuracy of the blade positioning system may be determined by comparing the difference between the oil head transducer and the blade position specified by the electronic 3D cam.

28. In a system for testing a hydro-powered Kaplan-type turbine having movable blades an movable gates and which is controlled by a governor and an electronic 3D cam in response to measured values of particular operating parameters, including gross headwater level and power generation level, the improvement comprising:
- an index test apparatus for automatically determining an optimal blade-to-gate positional relationship providing peak generating efficiency for a gross headwater level/power generation level operating condition, said index test apparatus comprising;
  
  analog-to-digital converting means for converting measured analog values of the operating parameters to digital values;
  
  memory means for storing both predetermined and measured values of the operating parameters; and
  
  microprocessor means for controlling the automatic determination of the optimal blade-to-gate positional relationships for said turbine, said microprocesor having a program for collecting measurements of the on-cam values of said operating parameters and storing said values in memory;
  
  evaluating the measured data to determine whether the turbine is operating at steady-state;
  
  when steady-state operation is achieved, moving the blades of said turbine through a series of off-cam incremental variations in pitch in both flatter blade angle and steeper blade angle directions;
  
  after making each incremental variation in the blade pitch, allowing the governor to reposition the gates as as to return the power generation level of the turbine to a predetermined setpoint, monitoring the operation of the turbine to determine when it has returned to steady-state and then measuring the values of the operating parameters at the new gate-blade operating point and storing those values in memory;
  
  computing for each gate-blade operating point a corresponding power generation efficiency value and storing that value in memory;
  
  comparing each power generation efficiency value with previously computed values which have been stored in the memory to identify a peak efficiency value and thereby define the optimal blade-to-gate positional relationship for said gross headwater level/power generation level operating condition; and
  
  , upon defining said optimal relationship, returning the turbine to on-cam operation.

29. In a system for testing a hydro-powered Kaplan-type turbine having movable blades and movable gates and which is controlled by a governor and an electronic 3D cam in response to measured values of particular operating parameters, including gross headwater level and power generation level, the improvement comprising:
- an index test apparatus for automatically determining an optimal blade-to-gate positional relationship providing peak generating efficiency for a gross headwater level/power generation level operating condition, said index test apparatus comprising;
  
  analog-to-digital converting means for converting measured analog values of the operating parameters to digital values;
  
  memory means for storing both predetermined and measured values of the operating paramtters; and
  
  microprocessor means for controlling the automatic detemination of the optimal blade-to-gate positonal relationships for said turbine, said microprocessor having a program for collecting measurements of the on-cam values of the operating parameters and storing said values in memory;
  
  evaluating the measured data to determine whether the turbine is operating at steady-state;
  
  when steady-state operation is achieved, comparing measured values of the operating parameters with previously measured and stored values to locate unique on-cam operating points;
  
  upon locating a unique on-cam operating point, making a series of incremental off-cam variations in the pitch of the blades of the turbine in both flatter blade angle and steeper blade angle directions;
  
  after making each incremental variation in the blade pitch, allowing the governor to reposition the gates so as to return the power generation level of the turbine to a predetermined setpoint, monitoring the operation of the turbine to determine when it has returned to steady-state and then measuring the values of the operating parameters at the new gate-blade operating point and storing those values in memory;
  
  computing for each gate-blade operating point a corresponding power generation efficiency value and storing that value in memory;
  
  comparing each power generation efficiency value with previously computed values which have been stored in the memory to identify a peak efficiency value and thereby define the optimal blade-to-gate positional relationship for said gross headwater level/power generation level operating condition; and
  
  , upon defining said optimal relationship, returning he turbine to on-cam operation.

Specification

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Litigation Campaign Assessment

Current Assignee
General Electric International BV (General Electric Company)
Original Assignee
Woodward Governor Company (Woodward Incorporated)
Inventors
Mittendorf, George H. Jr., Albright, Douglas J.
Primary Examiner(s)
Chin, Gary
Assistant Examiner(s)
Teska, Kevin J.

Application Number

US07/031,110
Time in Patent Office

642 Days
Field of Search

364/492-494, 364/550-552, 364/578, 364/495, 364/853, 364/856, 73/112, 60/364, 60/398, 290/43, 290/52, 416/17, 405/78, 415/148
US Class Current

700/287
CPC Class Codes

F03B 15/06 Regulating, i.e. acting aut...

Y02E 10/20 Hydro energy

Method and apparatus for automatically index testing a kaplan turbine

First Claim

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Method and apparatus for automatically index testing a kaplan turbine

First Claim

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