CN107543733A - A kind of condenser duty on-line monitoring system and measuring method - Google Patents

Abstract

The present invention relates to a kind of condenser duty on-line monitoring system and measuring method, the system includes online data collection module, data preprocessing module, performance test demarcating module and data computation analysis module, main steam volume flow corresponding to different valve positions is demarcated by the ASME performance tests on the basis of condensing water flow using the computational methods of the system, based on this test data, the main steam flow of therrmodynamic system is calculated by the subsidiary such as other pressure and temperatures data, main feedwater flow, the parameters such as reheated steam flow, and then obtain the gross energy into turbine system；According to system capacity law of conservation, condenser duty is obtained after generator power and every loss are deducted from the gross energy for entering turbine system, so that the thermic load data accuracy finally given is high, real-time is good.

Description

A kind of condenser duty on-line monitoring system and measuring method

Technical field

The present invention relates to a kind of condenser duty on-line monitoring system and measuring method, belongs to thermal power generating technology neck Domain.

Background technology

With attention of the country to Energy-saving for Thermal Power Units emission reduction work, real time on-line monitoring turbine condenser thermic load pair The energy-saving and emission-reduction work of thermal power generation corporations has great importance.

Currently acquired condenser duty typically has two methods：One kind is to calculate to enter condenser by positive balance method Steam flow and steam enthalpy, condensing water flow and condensate enthalpy, the hydrophobic flow into condenser and hydrophobic enthalpy, from And direct solution condenser duty；Another method is to flow through the circulating cooling water flow of condenser by measurement and pass in and out solidifying The circulating cooling coolant-temperature gage of vapour device calculates condenser duty.

Above-mentioned first method is because low pressure (LP) cylinder exhaust enthalpy will be calculated by the energy balance of complete machine, the test ginseng being related to Number and test instrumentation are more, therefore precision is difficult to be guaranteed.

Above-mentioned second method needs accurate measurement circulating cooling water flow and passes in and out the circulating water temperature of condenser.So And the unit recirculated cooling water pipeline diameter of 300MW grades and the above reaches 2m-3m, can not with the higher flow nozzle of precision or Orifice plate measures, and the measurement accuracy of ultrasonic flowmeter is poor；Secondly, recirculated cooling water temperature rise is usually no more than 10 DEG C, i.e., Less thermometric error also can be brought larger error to the calculating of condenser duty.

The relation of condenser duty computational methods utilization heat rate rate and load described in patent 201510007306.4 is bent Line, operational factor is reversely corrected, obtains thermal loss of steam turbine rate, and then try to achieve corresponding condenser duty.This method The heat consumption rate and load relation curve of institute's foundation are only capable of the thermal loss of steam turbine reflected under unit experiment isolation, and actual motion Middle unit is not at isolation, and most of units, in the presence of externally drawing gas, boiler soot-blowing blowdown etc. influences, therefore this method Computational accuracy be limited by having a great influence for system mode.

The content of the invention

The present invention is in order to solve problems of the prior art, there is provided a kind of accurately real time on-line monitoring condenser heat The System and method for of load.

In order to achieve the above object, technical scheme proposed by the present invention is：A kind of condenser duty on-line monitoring system, For monitoring the thermic load of condenser in thermal power generation unit on-line, the system includes online data collection module, data are located in advance Manage module, performance test demarcating module and data computation analysis module, the online data collection module and data prediction mould Block is connected, and data preprocessing module connection is connected with performance test demarcating module, and performance test demarcating module calculates with data to be divided Analyse module connection, the generator outlet that the online data collection module includes several pressure-temperature sensors, unit carries Flow sensor on the electrodymamometer and heat supply extraction line at place, several pressure-temperature sensors are respectively arranged at main steam Pipeline, reheated steam pipeline, heat supply bleed steam pipework, heat supply draw gas water return pipeline, final supply line, cold steam pipework again, again Hot desuperheat water lines, entrance and the water inlet of outlet and high-pressure heater of reheating attemperator, delivery port, air intake with it is hydrophobic At mouthful；The thermal power generation unit mesohigh heater is provided with three, respectively the first high-pressure heater, the second high-pressure heater With the 3rd high-pressure heater, the online data collection module is used to collect online data, and the data preprocessing module is used for Online data is pre-processed, the performance test demarcating module is used to store the base crossed by high-precision A SME Experimental Calibrations Quasi- data, and pretreated data are received, and the reference datas such as main steam volume flow are obtained according to pretreated data, The data computation analysis module is used to online data and reference data calculate analysis, and to obtain turbine condenser heat negative Lotus.

Above-mentioned technical proposal is improved to：The data computation analysis module includes data conversion module and data calculate Module, the data conversion module are used for the pressure for collecting pressure-temperature sensor by water and vapor quality computation software package The data such as density and enthalpy are converted to temperature data.

Above-mentioned technical proposal is improved to：Also include terminal display module, the terminal display module calculates with data Analysis module connects, for receiving condenser duty data and being shown.

A kind of condenser duty On-line Measuring Method using above-mentioned condenser duty on-line monitoring system, including such as Lower step：

Step 1, pass through the pressure and temperature of steam and water in each pipeline in pressure-temperature sensor collection thermal power generation unit Deng online data, and collect the online datas such as the generator power in thermal power generation unit DCS system and the heat supply amount of drawing gas；

Step 2, required reference data is calculated by ASME Experimental Calibrations；

Step 3, according to step 1 collect pressure and temperature data using water and vapor quality computation software package calculate steam with The density and enthalpy data of water；

The mass flow of steam and water in each pipeline in step 4, calculating thermal power generation unit；

Step 5, the heat that turbine system obtains in thermal power generation unit is calculated,

Q₀=F_mh_m+F_rh_r-F_wh_w-F_crh_cr-F_rhsh_rhs-F_cq(h_cq-h_hs)+3600(W_f+W_n)η_T (9)

In formula：Q₀The heat obtained for turbine system, F_mFor main steam flow, h_mFor main steam enthalpy, F_rFor reheated steam stream Amount, h_rFor reheated steam enthalpy, F_wFor final feedwater flow, h_wFor final Enthalpy of Feed Water, F_crFor cold steam flow again, h_crTo be cold Steam enthalpy again, F_rhsFor reheating attemperation water flow, h_rhsFor reheating desuperheating water enthalpy, F_cqFor heat supply extraction flow, h_cqFor heat supply Draw gas enthalpy, h_hsDrawn gas backwater enthalpy for heat supply, W_fFor water supply pump motor power, kW； W_nFor solidifying pump motor power, η_TFor work(heat Conversion efficiency；

Step 6, calculate condenser duty；

Principle according to system capacity conservation calculates condenser duty；

In formula：Q_nFor condenser duty, W_cFor generator power, η_gFor generator efficiency, η_mFor mechanical efficiency.

Above-mentioned technical proposal is improved to：The content of ASME experiments is in the step 2：

1. main steam volume flow corresponding to different steam turbine comprehensive valve positions is tested by high-precision thermal performance test,

2. by becoming steam temperature experimental test high pressure cylinder and the gap bridge steam loss D of intermediate pressure cylinder conjunction cylinder junction_g。

Above-mentioned technical proposal is improved to：The mass flow calculated in the step 4 includes main steam mass flow, most Whole feedwater flow, cold steam flow again, reheating spray water flux and reheated steam flow.

Above-mentioned technical proposal is improved to：The computational methods of the main steam mass flow are：

1. gather steam turbine comprehensive valve place value ψ_i, current composite valve place value ψ is obtained according to the reference data of step 2_iCorresponding master Vapour volume flow Q_i；

2. gather main steam pressure force value P_mWith main steam temperature value t_m, main steaming is calculated by water and vapor quality computation software package Vapour density ρ_m；

3. utilize main steam volume flow Q_iWith main steam density p_mCalculate main steam mass flow F_m；

The computational methods of the final feedwater flow are：

F_w=F_m+D₀

In above formula：D₀For furnace side carbonated drink working medium discharge rate.

Above-mentioned technical proposal is improved to：The computational methods of the cold steam flow again are：

1. gather the intake pressure P of the first high-pressure heater_1j, inflow temperature t_1j, discharge pressure P_1c, leaving water temperature t_1c, enter vapour Pressure P₁, throttle (steam) temperature t₁, hydrophobic pressure P_s1, drain temperature t_s1Etc. parameter；

The water inlet enthalpy h of high-pressure heater is calculated by water and vapor quality computation software package_1j, water outlet enthalpy h_1c, steam admission enthalpy Value h₁, hydrophobic enthalpy h_s1, calculate extraction flow F₁；

2. gathering the second height adds water pressure P_2j, inflow temperature t_2j, discharge pressure P_2c, leaving water temperature t_2c, initial steam pressure P₂, enter Stripping temperature t₂, hydrophobic pressure P_s2, drain temperature t_s2Etc. parameter；

#2 height is calculated by water and vapor quality computation software package and adds water enthalpy h_2j, water outlet enthalpy h_2c, steam admission enthalpy value h₂、 Hydrophobic enthalpy h_s2, calculate 2 sections of extraction flow F₂, wherein the second high discharge pressure P added_2c, leaving water temperature t_2cAdd with the first height Intake pressure P_1j, inflow temperature t_1jTake same numerical value；

3. calculate cold steam flow F again_cr,

F_cr=F_m-F₁-F₂-D_m-D_g-D_zIn above formula：D_gFor gap bridge air leakage, D_mFor door rod steam loss, D_zFor high pressure cylinder rear shaft seal Steam loss.

Above-mentioned technical proposal is improved to：The computational methods of the reheating spray water flux are：

1. gather the pressure P before reheating attemperator_zqWith temperature t_zq, pressure P after reheating attemperator_zhWith temperature t_zh, reheating subtracts The pressure P of warm water_rhsWith temperature t_rhs；

2. the steam enthalpy h before reheating attemperator is calculated by water and vapor quality computation software package_zq, after reheating attemperator Steam enthalpy h_zh, reheating desuperheating water enthalpy h_rhs, calculate reheating spray water flux F_rhs；

Above-mentioned technical proposal is improved to：The calculation formula of the reheated steam flow is：

F_r=F_cr+F_rhs。

Beneficial effects of the present invention are：

(1) main steam flow and reheated steam flow are to calculate acquisition indirectly using the data and reference data of on-line monitoring, because This is not influenceed by isolation of system, is adapted in line computation；(2) main steam volume flow is tested by high-precision ASME and obtained, and As a reference value, therefore accuracy is high；(3) parameter needed for the present invention, such as comprehensive valve position, generator power, pressure, temperature Deng, these parameters are direct measurement parameter, therefore parameter easily obtain and data it is reliable；(4) because Steam Turbine is big every time It is required for carrying out thermal performance test before and after repairing, therefore is advantageous to present invention demarcation main steam flow coefficient of discharge.

Brief description of the drawings

Fig. 1 is the structural representation of system of the embodiment of the present invention.

Fig. 2 is that data acquisition element of the embodiment of the present invention arranges schematic diagram.

Embodiment

Below in conjunction with the accompanying drawings and specific embodiment the present invention is described in detail.

Embodiment：

As shown in figure 1, a kind of condenser duty on-line monitoring system of the present embodiment, for monitoring thermal power generation unit on-line The heat consumption rate of middle condenser, the system include online data collection module, data preprocessing module, performance test demarcating module, Data computation analysis module and terminal display module, online data collection module are connected with data preprocessing module, and data are located in advance Reason module connection is connected with performance test demarcating module, and performance test demarcating module is connected with data computation analysis module.

The electric work at generator outlet that online data collection module carries including several pressure-temperature sensors, unit Flow sensor on rate meter and heat supply extraction line, online data collection module is used to collect pressure and temperature etc. in line number According to data preprocessing module is used to pre-process online data, and performance test demarcating module passes through high accuracy for storage The reference data that ASME Experimental Calibrations are crossed, and pretreated data are received, and obtain main steam according to pretreated data The reference data such as volume flow and reheated steam mass flow, data computation analysis module include data conversion module and data meter Calculate module, data conversion module be used for pressure pressure-temperature sensor collected by water and vapor quality computation software package with Temperature data is converted to the data such as density and enthalpy, and data computation module is used to online data and reference data calculate to divide Analysis obtains thermal loss of steam turbine rate.Terminal display module is connected with data computation analysis module, is gone forward side by side for receiving heat rate data Row display.

As shown in Fig. 2 include boiler 1, major steam line, again using the thermal power generation unit of the monitoring system of the present embodiment Vapours pipeline, cold steam pipework again, high pressure cylinder 2, intermediate pressure cylinder 3, low pressure (LP) cylinder 4, generator 5, condenser 6, solidifying pump 7, low pressure add Hot device 8, oxygen-eliminating device 9, feed pump 10, the first high-pressure heater 11, the second high-pressure heater 12, the 3rd high-pressure heater 13, most Whole supply line 14, overheat attemperator 15, reheating attemperator 16,17, one sections of bleed steam pipeworks 18, heat supplies of diminishing pipeline are drawn gas again Pipeline 19 and heat supply draw gas water return pipeline 24, overheat attemperator 15 and reheating attemperator 16 be arranged in boiler 1, overheat desuperheat The outlet of device 15 is connected by major steam line with the entrance of high pressure cylinder 2, and the outlet of high pressure cylinder 2 passes through cold steam pipework again and reheating The entrance connection of attemperator 16, the outlet of reheating attemperator 16 are connected by reheated steam pipeline with the entrance of intermediate pressure cylinder 3, middle pressure The outlet of cylinder 3 is connected with the entrance of low pressure (LP) cylinder 4, and the outlet of low pressure (LP) cylinder 4 is connected with condenser 6, coagulates pump 7, low-pressure heater 8, oxygen-eliminating device 9 And feed pump 10 is set in turn between condenser 6 and high-pressure heater along water (flow) direction, high-pressure heater is by finally feeding water Pipeline 14 is connected with overheating the entrance of attemperator 15, heat supply draw gas water return pipeline 24 be connected to low-pressure heater 8 and oxygen-eliminating device 9 it Between, heat supply bleed steam pipework 19 is connected to the exit of intermediate pressure cylinder 3, and one section of one end of bleed steam pipework 18 is connected on high pressure cylinder 2, the other end It is connected with the air intake of the first high-pressure heater 13, then diminishing pipeline 17 is between feed pump 10 and reheating attemperator 16, and with Feed pump 10 and reheating attemperator 16 are connected, and the air intake of the second high-pressure heater 12 is connected with cold steam pipework again, in main steam Pipeline, reheated steam pipeline, heat supply bleed steam pipework, heat supply draw gas water return pipeline, final supply line, cold steam pipework again, again Hot desuperheat water lines, entrance and the water inlet of outlet and high-pressure heater of reheating attemperator, delivery port, air intake and hydrophobic Pressure-temperature sensor is equipped with mouthful.

It is to be based on thermal performance test data and be using the thermal loss of steam turbine rate On-line Measuring Method of said detecting system What law of conservation of energy of uniting proposed, comprise the following steps：

(1) reference data needed for calculating in high-precision thermal performance test calibration and measuring system is passed through

1. main steam volume flow corresponding to some groups of difference comprehensive valve positions is tested by high-precision thermal performance test, it is such as public Shown in formula (1)：

In formula：ψ is comprehensive valve place value, unit %；Q is main vapour volume flow, unit m³/h；

2. by becoming the gap bridge steam loss D at steam temperature experimental test high intermediate pressure cylinder conjunction cylinder_g；Divide cylinder unit for high pressure, be not required to This is tested, now gives tacit consent to this numerical value for 0；

(2) steam turbine comprehensive valve place value is gathered, it is current comprehensive by the way that two column datas described in formula (1) are carried out with linear interpolation acquisition Close valve place value ψ_iCorresponding main steam volume flow Q_i；

The main steam pressure force value P that will be collected simultaneously_mWith main steam temperature value t_m, pass through water and vapor quality computation software package meter Calculate main steam density p_m, the volume flow of main steam is converted into main steam mass flow F_m；

(3) main feedwater flow is calculated by formula (3),

F_w=F_m-D₀Formula (3)

In formula：F_wFor main feedwater flow, unit t/h；F_mFor main steam flow, unit t/h；D₀Arranged for furnace side carbonated drink working medium Output, is a constant, unit t/h；

(4) the first height of collection adds water pressure P_1j, inflow temperature t_1j, discharge pressure P_1c, leaving water temperature t_1c, initial steam pressure P₁, enter Stripping temperature t₁, hydrophobic pressure P_s1, drain temperature t_s1Etc. parameter, and #1 height is calculated by water and vapor quality computation software package and added Water inlet enthalpy h_1j, water outlet enthalpy h_1c, steam admission enthalpy value h₁, hydrophobic enthalpy h_s1, substituted into formula (4) and calculate 1 section of extraction flow F₁；

In formula：F_wFor main feedwater flow, unit t/h；h_1cFor the first high plus water outlet enthalpy, unit kJ/kg；h_1jFor first Height adds water enthalpy, unit kJ/kg；h₁Vapour enthalpy, unit kJ/kg are added for the first height；h_s1For the first HP heater drainage enthalpy Value, unit kJ/kg；

(5) the second height of collection adds water pressure P_2j, inflow temperature t_2j, discharge pressure P_2c, leaving water temperature t_2c, initial steam pressure P₂, enter Stripping temperature t₂, hydrophobic pressure P_s2, drain temperature t_s2Etc. parameter, and it is high by water and vapor quality computation software package to calculate second Add water enthalpy h_2j, water outlet enthalpy h_2c, steam admission enthalpy value h₂, hydrophobic enthalpy h_s2, substituted into formula (5) and calculate 2 sections of extraction flows F₂, wherein the second high discharge pressure P added_2c, leaving water temperature t_2cWith the first high intake pressure P added_1j, inflow temperature t_1jTake same The numerical value of sample；

In formula：F_wFor main feedwater flow, unit t/h；h_2jWater enthalpy, unit kJ/kg are added for the second height；h_2cFor second Height plus water outlet enthalpy, unit kJ/kg；h_s1For the first HP heater drainage enthalpy, unit kJ/kg；h_s2For the second HP heater drainage enthalpy Value, unit kJ/kg；

(6) by the main steam flow F of gained calculated above_m, 1 section of extraction flow F₁, 2 sections of extraction flow F₂, and door rod steam loss D_m, gap bridge steam loss D_g, high pressure cylinder rear shaft seal steam loss D_zThe cold reheated steam flow F of formula (6) calculating is substituted into etc. parameter_cr

F_cr=F_m-F₁-F₂-D_m-D_g-D_zFormula (6)

Wherein, door rod steam loss D_mWith high pressure cylinder rear shaft seal steam loss D_zHandled according to design load；

(6) by gathering the pressure P before reheating attemperator_zqWith temperature t_zq, pressure P after reheating attemperator_zhWith temperature t_zh, again The pressure P of hot desuperheating water_rhsWith temperature t_rhs, before calculating reheating attemperator by water and vapor quality computation software package respectively Steam enthalpy h_zq, steam enthalpy h after reheating attemperator_zh, reheating desuperheating water enthalpy h_rhs, and substitute into formula (7) and calculate again Hot spray water flux F_rhs

In formula：F_crFor cold reheated steam flow, unit t/h；h_zhFor the steam enthalpy after reheating attemperator, unit kJ/ kg； h_zqFor the steam enthalpy before reheating attemperator, unit kJ/kg；h_rhsFor reheating desuperheating water enthalpy, unit kJ/kg；

The cold steam flow F again that formula (6) is calculated_cr, formula (7) calculate reheating spray water flux F_rhs, substitute into formula (8) reheated steam flow F is calculated_r

F_r=F_cr+F_rhsFormula (8)

(7) the main steam pressure P for collecting acquisition system_m, main steam temperature t_m, reheated steam pressure P_r, reheat steam temperature t_r, final feed pressure P_w, final feed temperature t_w, cold steam pressure P again_cr, cold vapor (steam) temperature t again_cr, reheating pressure of desuperheating water P_rhs, reheating desuperheat coolant-temperature gage t_rhs, heat supply extraction pressure P_cq, heat supply extraction temperature t_cq, heat supply draws gas pressure of return water P_hs, heat supply Backwater temperature of drawing gas t_hsThe parameters such as degree are input to water and steam property computation software package and calculate main steam enthalpy h respectively_m, reheating Steam enthalpy h_r, final Enthalpy of Feed Water h_fw, cold steam enthalpy h again_cr, reheating desuperheating water enthalpy h_rhs, heat supply draws gas enthalpy h_cq, supply Heat is drawn gas backwater enthalpy h_hs；Then by water supply pump motor power W_f, solidifying pump motor power W_n, heat supply extraction flow F_cq, calculate institute Primary steam flow F_m, formula (3) calculate winner of institute feedwater flow F_w, formula (8) calculate gained reheated steam flow F_r, formula (6) the cold steam flow F again of gained is calculated_cr, formula (7) calculate gained reheating attemperation water flow F_rhsAnd the ginseng such as corresponding enthalpy Number substitutes into formula (9) and calculates the heat Q that the turbine system under the current operating condition of unit obtains₀

Q₀=F_mh_m+F_rh_r-F_wh_w-F_crh_cr-F_rhsh_rhs-F_cq(h_cq-h_hs)+3600(W_f+W_n)η_TFormula (9)

In formula：Q₀The heat obtained for turbine system, unit kJ/h, W_fFor water supply pump motor power, unit kW； W_nFor Solidifying pump motor power, unit kW；η_TFor work(thermal conversion efficiency, constant, unit % are taken；

(9) principle according to system capacity conservation calculates condenser duty according to formula (10)

In formula：Q_nThe heat obtained for turbine system, unit kJ/h；W_cFor generator power, unit t/h；η_gTo generate electricity Engine efficiency, unit %；η_mIt is empirical value for mechanical efficiency, as constant processing, unit %.

Above-mentioned computational methods are demarcated main corresponding to different valve positions by the ASME performance tests on the basis of condensing water flow Vapour volume flow, based on this test data, therrmodynamic system is calculated by the subsidiary such as other pressure and temperatures data Main steam flow, main feedwater flow, the parameter such as reheated steam flow, and then obtain the gross energy into turbine system；According to According to system capacity law of conservation, obtained after generator power and every loss are deducted from the gross energy for entering turbine system Condenser duty, so that the thermic load data accuracy finally given is high, real-time is good, and is not influenceed by isolation of system.

A kind of condenser duty on-line detecting system and measuring method of the present invention is not limited to the various embodiments described above, all The technical scheme obtained using equivalent substitution mode is all fallen within the scope of protection of present invention.

Claims (10)

1. a kind of condenser duty on-line monitoring system, for monitoring the thermic load of condenser in thermal power generation unit on-line, It is characterized in that：Calculate and analyze including online data collection module, data preprocessing module, performance test demarcating module and data Module, the online data collection module are connected with data preprocessing module, data preprocessing module connection and performance test mark Cover half block is connected, and performance test demarcating module is connected with data computation analysis module, if the online data collection module includes The flow sensing on the electrodymamometer and heat supply extraction line at generator outlet that dry pressure-temperature sensor, unit carry Device, several pressure-temperature sensors are respectively arranged at major steam line, reheated steam pipeline, heat supply bleed steam pipework, heat supply are taken out Vapour water return pipeline, final supply line, cold steam pipework again, reheating desuperheat water lines, reheating attemperator entrance with outlet with And at the water inlet of high-pressure heater, delivery port, air intake and drain port；The thermal power generation unit mesohigh heater is provided with Three, respectively the first high-pressure heater, the second high-pressure heater and the 3rd high-pressure heater, the online data collection module For collecting online data, the data preprocessing module is used to pre-process online data, the performance test demarcation Module is used to store the reference data crossed by high-precision A SME Experimental Calibrations, and receives pretreated data, and according to pre- Data after processing obtain the reference datas such as main steam volume flow, the data computation analysis module be used for online data with Reference data carries out calculating analysis and obtains turbine condenser thermic load.

2. condenser duty on-line monitoring system according to claim 1, it is characterised in that：The data calculate analysis mould Block includes data conversion module and data computation module, and the data conversion module is used to pass through water and vapor quality software for calculation The pressure and temperature data that pressure-temperature sensor is collected are converted to the data such as density and enthalpy by bag.

3. condenser duty on-line monitoring system according to claim 2, it is characterised in that：Also include terminal and show mould Block, the terminal display module are connected with data computation analysis module, for receiving condenser duty data and being shown.

A kind of 4. condenser duty on-line measurement side using condenser duty on-line monitoring system described in claim 3 Method, it is characterised in that comprise the following steps：

Step 1, pass through the pressure and temperature of steam and water in each pipeline in pressure-temperature sensor collection thermal power generation unit Deng online data, and collect the online datas such as the generator power in thermal power generation unit DCS system and the heat supply amount of drawing gas；

Step 2, required reference data is calculated by ASME Experimental Calibrations；

Step 3, according to step 1 collect pressure and temperature data using water and vapor quality computation software package calculate steam with The density and enthalpy data of water；

The mass flow of steam and water in each pipeline in step 4, calculating thermal power generation unit；

Step 5, the heat that turbine system obtains in thermal power generation unit is calculated,

Q₀=F_mh_m+F_rh_r-F_wh_w-F_crh_cr-F_rhsh_rhs-F_cq(h_cq-h_hs)+3600(W_f+W_n)η_T

In formula：Q₀The heat obtained for turbine system, F_mFor main steam flow, h_mFor main steam enthalpy, F_rFor reheated steam stream Amount, h_rFor reheated steam enthalpy, F_wFor final feedwater flow, h_wFor final Enthalpy of Feed Water, F_crFor cold steam flow again, h_crTo be cold Steam enthalpy again, F_rhsFor reheating attemperation water flow, h_rhsFor reheating desuperheating water enthalpy, F_cqFor heat supply extraction flow, h_cqFor heat supply Draw gas enthalpy, h_hsDrawn gas backwater enthalpy for heat supply, W_fFor water supply pump motor power, kW；W_nFor solidifying pump motor power, η_TFor work(heat Conversion efficiency；

Step 6, calculate condenser duty；

Principle according to system capacity conservation calculates condenser duty；

In formula：Q_nFor condenser duty, W_cFor generator power, η_gFor generator efficiency, η_mFor mechanical efficiency.

5. condenser duty On-line Measuring Method according to claim 4, it is characterised in that：ASME is tried in the step 2 The content tested is：

1. main steam volume flow corresponding to different steam turbine comprehensive valve positions is tested by high-precision thermal performance test,

2. by becoming steam temperature experimental test high pressure cylinder and the gap bridge steam loss D of intermediate pressure cylinder conjunction cylinder junction_g。

6. condenser duty On-line Measuring Method according to claim 5, it is characterised in that：Calculated in the step 4 Mass flow includes main steam mass flow, final feedwater flow, cold steam flow again, reheating spray water flux and reheated steam stream Amount.

7. condenser duty On-line Measuring Method according to claim 6, it is characterised in that：The main steam mass flow Computational methods be：

1. gather steam turbine comprehensive valve place value ψ_i, current composite valve place value ψ is obtained according to the reference data of step 2_iCorresponding main steaming Vapour volume flow Q_i；

2. gather main steam pressure force value P_mWith main steam temperature value t_m, main steaming is calculated by water and vapor quality computation software package Vapour density ρ_m；

3. utilize main steam volume flow Q_iWith main steam density p_mCalculate main steam mass flow F_m；

The computational methods of the final feedwater flow are：

F_w=F_m+D₀

In above formula：D₀For furnace side carbonated drink working medium discharge rate.

8. condenser duty On-line Measuring Method according to claim 7, it is characterised in that：The cold steam flow again Computational methods are：

1. gather the intake pressure P of the first high-pressure heater_1j, inflow temperature t_1j, discharge pressure P_1c, leaving water temperature t_1c, enter vapour pressure Power P₁, throttle (steam) temperature t₁, hydrophobic pressure P_s1, drain temperature t_s1Etc. parameter；

The water inlet enthalpy h of high-pressure heater is calculated by water and vapor quality computation software package_1j, water outlet enthalpy h_1c, steam admission enthalpy Value h₁, hydrophobic enthalpy h_s1, calculate extraction flow F₁；

2. gathering the second height adds water pressure P_2j, inflow temperature t_2j, discharge pressure P_2c, leaving water temperature t_2c, initial steam pressure P₂, enter Stripping temperature t₂, hydrophobic pressure P_s2, drain temperature t_s2Etc. parameter；

#2 height is calculated by water and vapor quality computation software package and adds water enthalpy h_2j, water outlet enthalpy h_2c, steam admission enthalpy value h₂, dredge Water enthalpy h_s2, calculate 2 sections of extraction flow F₂, wherein the second high discharge pressure P added_2c, leaving water temperature t_2cEnter with what the first height added Water pressure P_1j, inflow temperature t_1jTake same numerical value.

3. calculate cold steam flow F again_cr,

F_cr=F_m-F₁-F₂-D_m-D_g-D_zIn above formula：D_gFor gap bridge air leakage, D_mFor door rod steam loss, D_zFor high pressure cylinder rear axle leak sealing Vapour amount.

9. condenser duty On-line Measuring Method according to claim 8, it is characterised in that：The reheating spray water flux Computational methods are：

1. gather the pressure P before reheating attemperator_zqWith temperature t_zq, pressure P after reheating attemperator_zhWith temperature t_zh, reheating desuperheat The pressure P of water_rhsWith temperature t_rhs；

2. the steam enthalpy h before reheating attemperator is calculated by water and vapor quality computation software package_zq, after reheating attemperator Steam enthalpy h_zh, reheating desuperheating water enthalpy h_rhs, calculate reheating spray water flux F_rhs；

10. condenser duty On-line Measuring Method according to claim 9, it is characterised in that：The reheated steam flow Calculation formula be：

F_r=F_cr+F_rhs。