CN103901068A - Method for monitoring steam turbine low-pressure cylinder exhaust steam enthalpy value online - Google Patents

Abstract

The invention relates to a method for monitoring a steam turbine low-pressure cylinder exhaust steam enthalpy value online. The method comprises the following steps: acquiring real-time operating data of a needed unit; recoding the received transmission data; obtaining a hydrophobic enthalpy value of a lower-pressure heater group, and transmitting a calculation result to a steam turbine low-pressure cylinder exhaust steam enthalpy value calculation module and a data storage server; obtaining the steam turbine low-pressure cylinder exhaust steam enthalpy value, and transmitting the calculation result to a master display screen of the system and the data storage server; classifying and storing the data through the data storage server; and simultaneously presenting the steam turbine low-pressure cylinder exhaust steam enthalpy value and a historical operating cleaning coefficient in a table and curve form on the master display screen of the system. According to the method, important operating monitoring parameters of the steam turbine and the steam turbine low-pressure cylinder exhaust steam enthalpy value are calculated in real time and are presented to the operating crew in the forms of graphs and historical curves, and the operating crew are helped to master the real-time operating state of the steam turbine.

Description

The on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value

Technical field

The invention belongs to thermal power generation field of energy-saving technology, especially a kind of on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value.

Background technology

Turbine low pressure cylinder steam discharge is in wet-steam region, its enthalpy can not calculate by the temperature and pressure of measuring low pressure (LP) cylinder steam discharge according to conventional computing method, and at present ripe and can be applied to the method for engineering field and instrument for testing wet steam humidity without comparison, but exhaust enthalpy of low pressure cylinder of steam turbine value is an important parameter in steam turbine operation process, larger to unit operation economic influence.

Summary of the invention

The object of the invention is for the deficiencies in the prior art, and propose a kind of on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value.

The present invention solves its technical matters and takes following technical scheme to realize:

An on-line monitoring method for exhaust enthalpy of low pressure cylinder of steam turbine value, method step comprises:

(1) data unit operation acquisition module is from the required unit real-time running data of operating unit scattered control system collection of server, and real-time running data is sent to real-time data acquisition net;

(2) real-time data acquisition net carries out recompile to the transmission data that receive, isolation contacts with outside other data transmission network, and recompile result is sent to the hydrophobic enthalpy computing module of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value computing module and data storage server;

(3) the hydrophobic enthalpy computing module of low-pressure heater group calculates Heater group water inlet enthalpy H to receiving data _din, Heater group water outlet enthalpy H _dout, the 1st to the n section enthalpy H that draws gas ₁to H _n, and then draw the hydrophobic enthalpy of low-pressure heater group, and result of calculation is sent to exhaust enthalpy of low pressure cylinder of steam turbine value computing module and data storage server;

(4) exhaust enthalpy of low pressure cylinder of steam turbine value computing module is to receiving data computation cycles chilled water water inlet H _in, recirculated cooling water water outlet H _out, condensate water enthalpy H _w, and then draw exhaust enthalpy of low pressure cylinder of steam turbine value, and result of calculation is sent to exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display and data storage server;

(5) data storage server receives the data that come from real-time data acquisition net, the hydrophobic enthalpy computing module of low-pressure heater group and exhaust enthalpy of low pressure cylinder of steam turbine value computing module simultaneously, and complete classification and the storage of data, the transferring and subsequent treatment historical data for user of service;

(6) exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display presents exhaust enthalpy of low pressure cylinder of steam turbine value and history run cleanliness factor with the form of form and curve simultaneously.

And the unit real-time running data in described step (1) specifically comprises: condenser pressure, condenser hotwell coolant-temperature gage, recirculated cooling water intake pressure and temperature, recirculated cooling water discharge pressure and temperature, Heater group intake pressure, temperature and flow, Heater group discharge pressure and temperature, the 1st are to n section extraction pressure, temperature and flow.

And it is that the condenser pressure of reception, condenser hotwell coolant-temperature gage, recirculated cooling water intake pressure and temperature, recirculated cooling water discharge pressure and temperature, Heater group intake pressure, temperature and flow, Heater group discharge pressure and temperature, the 1st are combined to П system data encoding with time data bag again to n section extraction pressure, temperature and traffic transport data that the transmission data to receiving in described step (2) are carried out recompile.

And the circular of the hydrophobic enthalpy of low-pressure heater group in described step (3) is:

1. Heater group intake pressure P _din, temperature T _din, flow Q _d; Well heater discharge pressure P _dout, T _dout; The 1st to n section extraction pressure P _n, temperature T _n, flow Q _nbe DCS system Real-Time Monitoring amount, gathered by unit real-time running data acquisition module;

2. all can calculate the enthalpy under corresponding states by pressure and temperature according to " the international formulistic council industrial IFC equation in 1967 " for saturated vapour, superheated vapor, saturation water, subcooled water, with formula H=f (P, T) represent, can calculate successively accordingly H _din, H _dout, H ₁to H _n;

3. the hydrophobic enthalpy H of low-pressure heater group _scircular be:

$H_s=\frac{Q_d\·(H_{\mathrm{dout}}-H_{\mathrm{din}})-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i\·H_i}{\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i}.$

And the circular of the exhaust enthalpy of low pressure cylinder of steam turbine value in described step (4) is:

1. condenser pressure P ₀, condenser hotwell coolant-temperature gage T ₀; Recirculated cooling water intake pressure P _in, temperature T _in, flow Q; Recirculated cooling water discharge pressure P _out, T _outbe DCS system Real-Time Monitoring amount, gathered by unit real-time running data acquisition module;

2. calculate the enthalpy under corresponding states according to " the international formulistic council industrial IFC equation in 1967 " by pressure and temperature, with formula H=f (P, T) expression, can calculate successively accordingly H _in, H _out, condensate water enthalpy H _w;

3. exhaust enthalpy of low pressure cylinder of steam turbine value H ₀circular be:

$H_0=\frac{Q\·(H_{\mathrm{out}}-H_{\mathrm{in}})+H_w\·Q_d-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i\·H_s}{Q_d-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i}.$

And the concrete sorting technique of Data classification is described in described step (5):

1. data are divided into unit real-time running data and calculation result data, and wherein unit real-time running data comprises: condenser pressure, condenser hotwell coolant-temperature gage, enter/pressure of return water of condenser recirculated cooling water, temperature flow, Heater group inlet/outlet pressure, temperature, flow unit vacuum, each section of pressure drawing gas, temperature and flow; Calculation result data comprises: the hydrophobic enthalpy of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value;

2. because unit real-time running data gathers self-operating unit scattered control system (DCS) server, in notebook data storage server, no longer preserve, only complete calculation result data with time packet stores synchronized.

And, form described in described step (6) specifically comprises condenser pressure, condenser hotwell coolant-temperature gage, enter/pressure of return water of condenser recirculated cooling water, temperature and flow, the hydrophobic enthalpy of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value, and described curve specifically comprises the time dependent curve of exhaust enthalpy of low pressure cylinder of steam turbine value.

Advantage of the present invention and good effect are:

The present invention links together unit real-time running data acquisition module, real-time data acquisition net, the hydrophobic enthalpy computing module of low-pressure heater group, data storage server, exhaust enthalpy of low pressure cylinder of steam turbine value computing module and exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system key frame, forms the on-line monitoring system of exhaust enthalpy of low pressure cylinder of steam turbine value.This system is by calculating in real time the important operation monitoring parameter of steam turbine: exhaust enthalpy of low pressure cylinder of steam turbine value, and present to operations staff with the form of chart and history curve, help operations staff to grasp steam turbine real-time running state.

Accompanying drawing explanation

Fig. 1 is the computing method principle schematic of exhaust enthalpy of low pressure cylinder of steam turbine value of the present invention;

Fig. 2 is the system connection diagram of the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value of the present invention.

Embodiment

Below in conjunction with accompanying drawing, the invention process is further described, following examples are descriptive, are not determinate, can not limit protection scope of the present invention with this.

A kind of on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value, Method And Principle as shown in Figure 1, system connects as shown in Figure 2, the hardware system that the method is used comprises: unit real-time running data acquisition module, real-time data acquisition net, the hydrophobic enthalpy computing module of low-pressure heater group, data storage server, exhaust enthalpy of low pressure cylinder of steam turbine value computing module, exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display and operating unit scattered control system (DCS) server, and the step of the method is as follows:

(1) data unit operation acquisition module is from the required unit real-time running data of operating unit scattered control system (DCS) collection of server, and real-time running data is sent to real-time data acquisition net;

Wherein, unit real-time running data specifically comprises: condenser pressure, condenser hotwell coolant-temperature gage, recirculated cooling water intake pressure and temperature, recirculated cooling water discharge pressure and temperature, Heater group intake pressure, temperature and flow, Heater group discharge pressure and temperature, the 1st are to n section extraction pressure, temperature and flow;

(2) real-time data acquisition net carries out recompile to the transmission data that receive, isolation contacts with outside other data transmission network, and recompile result is sent to the hydrophobic enthalpy computing module of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value computing module and data storage server;

Wherein, the transmission data that receive being carried out to recompile is that the condenser pressure of reception, condenser hotwell coolant-temperature gage, recirculated cooling water intake pressure and temperature, recirculated cooling water discharge pressure and temperature, Heater group intake pressure, temperature and flow, Heater group discharge pressure and temperature, the 1st are combined to П system data encoding with time data bag again to n section extraction pressure, temperature and traffic transport data;

(3) the hydrophobic enthalpy computing module of low-pressure heater group calculates Heater group water inlet enthalpy H to receiving data _din, Heater group water outlet enthalpy H _dout, the 1st to the n section enthalpy H that draws gas ₁to H _n, and then draw the hydrophobic enthalpy of low-pressure heater group, and result of calculation is sent to exhaust enthalpy of low pressure cylinder of steam turbine value computing module and data storage server;

Wherein, the circular of the hydrophobic enthalpy of low-pressure heater group is:

1. Heater group intake pressure P _din, temperature T _din, flow Q _d; Well heater discharge pressure P _dout, T _dout; The 1st to n section extraction pressure P _n, temperature T _n, flow Q _nbe DCS system Real-Time Monitoring amount, gathered by unit real-time running data acquisition module;

2. all can calculate the enthalpy under corresponding states by pressure and temperature according to " the international formulistic council industrial IFC equation in 1967 " for saturated vapour, superheated vapor, saturation water, subcooled water, with formula H=f (P, T) represent, can calculate successively accordingly H _din, H _dout, H ₁to H _n;

3. the hydrophobic enthalpy H of low-pressure heater group _scircular be:

$H_s=\frac{Q_d\·(H_{\mathrm{dout}}-H_{\mathrm{din}})-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i\·H_i}{\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i}$

(4) exhaust enthalpy of low pressure cylinder of steam turbine value computing module is to receiving data computation cycles chilled water water inlet H _in, recirculated cooling water water outlet H _out, condensate water enthalpy H _w, and then draw exhaust enthalpy of low pressure cylinder of steam turbine value, and result of calculation is sent to exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display and data storage server,

Wherein, the circular of exhaust enthalpy of low pressure cylinder of steam turbine value is:

1. condenser pressure P ₀, condenser hotwell coolant-temperature gage T ₀; Recirculated cooling water intake pressure P _in, temperature T _in, flow Q; Recirculated cooling water discharge pressure P _out, T _outbe DCS system Real-Time Monitoring amount, gathered by unit real-time running data acquisition module;

2. calculate the enthalpy under corresponding states according to " the international formulistic council industrial IFC equation in 1967 " by pressure and temperature, with formula H=f (P, T) expression, can calculate successively accordingly H _in, H _out, condensate water enthalpy H _w;

3. exhaust enthalpy of low pressure cylinder of steam turbine value H ₀circular be:

$H_0=\frac{Q\·(H_{\mathrm{out}}-H_{\mathrm{in}})+H_w\·Q_d-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i\·H_s}{Q_d-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i}$

(5) data storage server receives the data that come from real-time data acquisition net, the hydrophobic enthalpy computing module of low-pressure heater group and exhaust enthalpy of low pressure cylinder of steam turbine value computing module simultaneously, and complete classification and the storage of data, the transferring and subsequent treatment historical data for user of service;

Wherein, the concrete sorting technique of described Data classification is:

1. data are divided into unit real-time running data and calculation result data, and wherein unit real-time running data comprises: condenser pressure, condenser hotwell coolant-temperature gage, enter/pressure of return water of condenser recirculated cooling water, temperature flow, Heater group inlet/outlet pressure, temperature, flow unit vacuum, each section of pressure drawing gas, temperature and flow; Calculation result data comprises: the hydrophobic enthalpy of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value;

2. because unit real-time running data gathers self-operating unit scattered control system (DCS) server, in notebook data storage server, no longer preserve, only complete calculation result data with time packet stores synchronized;

(6) exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display presents exhaust enthalpy of low pressure cylinder of steam turbine value and history run cleanliness factor with the form of form and curve simultaneously;

Wherein, described form specifically comprises condenser pressure, condenser hotwell coolant-temperature gage, enter/pressure of return water of condenser recirculated cooling water, temperature and flow, the hydrophobic enthalpy of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value,

Wherein, described curve specifically comprises the time dependent curve of exhaust enthalpy of low pressure cylinder of steam turbine value.

Claims (7)

1. an on-line monitoring method for exhaust enthalpy of low pressure cylinder of steam turbine value, is characterized in that method step comprises:

(1) data unit operation acquisition module is from the required unit real-time running data of operating unit scattered control system collection of server, and real-time running data is sent to real-time data acquisition net;

(2) real-time data acquisition net carries out recompile to the transmission data that receive, isolation contacts with outside other data transmission network, and recompile result is sent to the hydrophobic enthalpy computing module of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value computing module and data storage server;

(3) the hydrophobic enthalpy computing module of low-pressure heater group calculates Heater group water inlet enthalpy H to receiving data _din, Heater group water outlet enthalpy H _dout, the 1st to the n section enthalpy H that draws gas ₁to H _n, and then draw the hydrophobic enthalpy of low-pressure heater group, and result of calculation is sent to exhaust enthalpy of low pressure cylinder of steam turbine value computing module and data storage server;

(4) exhaust enthalpy of low pressure cylinder of steam turbine value computing module is to receiving data computation cycles chilled water water inlet H _in, recirculated cooling water water outlet H _out, condensate water enthalpy H _w, and then draw exhaust enthalpy of low pressure cylinder of steam turbine value, and result of calculation is sent to exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display and data storage server;

(5) data storage server receives the data that come from real-time data acquisition net, the hydrophobic enthalpy computing module of low-pressure heater group and exhaust enthalpy of low pressure cylinder of steam turbine value computing module simultaneously, and complete classification and the storage of data, the transferring and subsequent treatment historical data for user of service;

(6) exhaust enthalpy of low pressure cylinder of steam turbine value on-line monitoring system main display presents exhaust enthalpy of low pressure cylinder of steam turbine value and history run cleanliness factor with the form of form and curve simultaneously.

2. the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value according to claim 1, is characterized in that: the unit real-time running data in described step (1) specifically comprises: condenser pressure, condenser hotwell coolant-temperature gage, recirculated cooling water intake pressure and temperature, recirculated cooling water discharge pressure and temperature, Heater group intake pressure, temperature and flow, Heater group discharge pressure and temperature, the 1st are to n section extraction pressure, temperature and flow.

3. the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value according to claim 1, is characterized in that: it is that the condenser pressure of reception, condenser hotwell coolant-temperature gage, recirculated cooling water intake pressure and temperature, recirculated cooling water discharge pressure and temperature, Heater group intake pressure, temperature and flow, Heater group discharge pressure and temperature, the 1st are combined to П system data encoding with time data bag again to n section extraction pressure, temperature and traffic transport data that the transmission data to receiving in described step (2) are carried out recompile.

4. the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value according to claim 1, is characterized in that: the circular of the hydrophobic enthalpy of low-pressure heater group in described step (3) is:

1. Heater group intake pressure P _din, temperature T _din, flow Q _d; Well heater discharge pressure P _dout, T _dout; The 1st to n section extraction pressure P _n, temperature T _n, flow Q _nbe DCS system Real-Time Monitoring amount, gathered by unit real-time running data acquisition module;

2. all can calculate the enthalpy under corresponding states by pressure and temperature according to " the international formulistic council industrial IFC equation in 1967 " for saturated vapour, superheated vapor, saturation water, subcooled water, with formula H=f (P, T) represent, can calculate successively accordingly H _din, H _dout, H ₁to H _n;

3. the hydrophobic enthalpy H of low-pressure heater group _scircular be:

$H_s=\frac{Q_d\·(H_{\mathrm{dout}}-H_{\mathrm{din}})-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i\·H_i}{\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i}.$

5. the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value according to claim 1, is characterized in that: the circular of the exhaust enthalpy of low pressure cylinder of steam turbine value in described step (4) is:

1. condenser pressure P ₀, condenser hotwell coolant-temperature gage T ₀; Recirculated cooling water intake pressure P _in, temperature T _in, flow Q; Recirculated cooling water discharge pressure P _out, T _outbe DCS system Real-Time Monitoring amount, gathered by unit real-time running data acquisition module;

2. calculate the enthalpy under corresponding states according to " the international formulistic council industrial IFC equation in 1967 " by pressure and temperature, with formula H=f (P, T) expression, can calculate successively accordingly H _in, H _out, condensate water enthalpy H _w;

3. exhaust enthalpy of low pressure cylinder of steam turbine value H ₀circular be:

$H_0=\frac{Q\·(H_{\mathrm{out}}-H_{\mathrm{in}})+H_w\·Q_d-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i\·H_s}{Q_d-\underset{i=1}{\overset{i=n}{\mathrm{\Σ}}}{Q}_i}.$

6. the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value according to claim 1, is characterized in that: described in described step (5), the concrete sorting technique of Data classification is:

1. data are divided into unit real-time running data and calculation result data, and wherein unit real-time running data comprises: condenser pressure, condenser hotwell coolant-temperature gage, enter/pressure of return water of condenser recirculated cooling water, temperature flow, Heater group inlet/outlet pressure, temperature, flow unit vacuum, each section of pressure drawing gas, temperature and flow; Calculation result data comprises: the hydrophobic enthalpy of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value;

2. because unit real-time running data gathers self-operating unit scattered control system (DCS) server, in notebook data storage server, no longer preserve, only complete calculation result data with time packet stores synchronized.

7. the on-line monitoring method of exhaust enthalpy of low pressure cylinder of steam turbine value according to claim 1, it is characterized in that: form described in described step (6) specifically comprises condenser pressure, condenser hotwell coolant-temperature gage, enter/pressure of return water of condenser recirculated cooling water, temperature and flow, the hydrophobic enthalpy of low-pressure heater group, exhaust enthalpy of low pressure cylinder of steam turbine value, and described curve specifically comprises the time dependent curve of exhaust enthalpy of low pressure cylinder of steam turbine value.

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