RU2711724C1 - Method for estimating position of gas turbine exhaust gas thermal field epicenter - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to the field of engineering, and more specifically - to the gas turbine exhaust gas thermal field epicenter position evaluation method. Present invention can be used in creation, operation, control and monitoring of systems for various purposes, including complex technical systems, in which gas turbine units are integrated, used in power engineering, machine building, municipal services and other industries. Increase in inhomogeneity leads to burnout of guide vanes of the first stage of gas turbine and reduction of its efficiency.EFFECT: disclosed method has high universality and flexibility and enables to achieve better results, in particular, based on obtained data, objective opinion on variation of degree of non-uniformity of temperature field.1 cl

Description

The invention relates to the field of technology, and more specifically to a method for assessing the position of the epicenter of the thermal field of the exhaust of a gas turbine installation.

The present invention can find application in the creation, operation, management and monitoring of systems for various purposes, including complex technical systems that integrate gas turbine plants used in energy, engineering, utilities and other industries. The task of assessing the position of the epicenter of the exhaust thermal field is very relevant, since an increase in heterogeneity leads to burning out of the guide vanes of the first stage of the gas turbine and a decrease in its efficiency.

The basis of the present invention is the creation of such a method for assessing the position of the epicenter of the thermal field of the exhaust gas turbine installation, which would allow to accumulate and use data on the position of the epicenter of the thermal field of the exhaust gas turbine installation at any time for controlled gas turbine installations, as well as to calculate the average temperature at the outlet of gas turbine installation and maximum deviations from the average temperature and form an objective opinion on the basis of the obtained data regarding the change in the degree of temperature field non-uniformity.

Closest to this invention is a method of leveling the temperature field in gas turbine devices (RF patent No. 2522146), which can be taken as a prototype. This invention can be used in the energy sector, namely in gas pumping units of material pipelines, autonomous power plants and other power plants containing a gas turbine drive running on natural gas. In this method, fuel is supplied to individual burners with critical flow parameters in channels whose flow sections are identical. The longitudinal profiles of all channels are made to coincide with the profile of any arbitrarily taken channel, preferably made first, with an accuracy determined by the manufacturing error, and the channel walls are made with the same surface roughness, while the fuel consumption entering the input part of each channel is evenly ensured by execution in the input part of the channel of the tuning element, mainly in the form of a chamfer, with the ability to change its geometric dimensions when configured channel channel for a given flow rate. The technical result of the invention is the uniformity of the temperature field in front of the turbine of a gas turbine installation.

The meaning of the prototype is a method of equalizing the temperature field in gas turbine plants, based on ensuring the equality of the flow of fuel components through separate burner devices of the combustion chamber and consisting in the supply of fuel components to separate burner devices through channels in which critical flow parameters are provided, and consisting of input and output parts interconnected by a minimum passage section, while the passage sections of these channels are identical characterized in that the longitudinal profiles of all channels are made to coincide with the profile of any arbitrarily taken channel, preferably made first, with an accuracy determined by the manufacturing error, moreover, the channel walls are made with the same surface roughness, with equal fuel consumption entering the input part of each channel, additionally provide due to the implementation in the input part of the channel tuning element, mainly in the form of a chamfer, with the possibility of changing its geometric Sgiach sizes when setting up a channel on the preset flow

However, the prototype considered has the following disadvantages:

- is not universal for various types of gas turbines;

- does not allow the use of data on the position of the epicenter of the thermal field of the exhaust of a gas turbine installation at any time, and also to calculate the average temperature at the outlet of the gas turbine installation and the maximum deviations from the average temperature;

- it does not allow forming an objective opinion on the basis of the data obtained regarding the change in the degree of unevenness of the temperature field.

The objectives of the invention are solved and the disadvantages of the prototype are eliminated in the method according to the present invention for assessing the position of the epicenter of the heat field of the exhaust of a gas turbine installation, comprising the following stages:

1) accumulate data on the position of the epicenter of the thermal field of the exhaust of the gas turbine installation at each time point for controlled gas turbine installations;

2) calculate the average temperature at the outlet of the gas turbine unit and the maximum deviations from the average temperature and accumulate these data;

3) the expert receives data on the position of the epicenter of the heat field of the exhaust of the gas turbine installation at each moment of time, as well as the average temperature at the exit of the gas turbine installation and maximum deviations from the average temperature and forms an opinion on the basis of the data obtained regarding the change in the degree of unevenness of the temperature field;

4) according to the results of step 3, the operation parameters of the gas turbine installation are automatically adjusted;

5) the obtained indicators and conditions in stages 2, 3 and 4 are optionally stored and used as signaling and / or control actions, which allow to achieve safe and optimal functioning of the gas turbine unit.

Due to the implementation of the claimed method, the following technical results are achieved:

- it is universal for various types of gas turbines;

- allows you to use data about the position of the epicenter of the thermal field of the exhaust of a gas turbine installation at each time point, and also to calculate the average temperature at the outlet of the gas turbine installation and the maximum deviations from the average temperature;

- allows you to form an objective opinion on the basis of the data obtained regarding changes in the degree of unevenness of the temperature field.

The present invention will be disclosed in the following description of a remote monitoring and forecasting system (SUMiP), including a set of expert modules, including a module for monitoring the position of the epicenter of the thermal field at the outlet of the gas turbine

SUMiP consists of lower and upper level systems. The task of the lower level is the collection, initial processing, buffering and data transfer to the upper level, where analytical tasks related to monitoring and forecasting the technical condition of objects are solved.

The process of collecting and transmitting data is implemented on the basis of a 2-server scheme. The server of the lower level system, for which a demilitarized zone is organized using firewalls, saves the data received from automated systems (ACS) for process control (TP) for further transmission via a secure channel through the global network to the server of the upper level system. The server of the lower level acts as a buffer of received data. Such a circuit isolates the operation of the automated process control system of the facility and the lower level system, and also ensures the safety of the received data in case of emergency. In addition, the receipt of data in full in the upper level system provides the possibility of a detailed analysis of changes in the technical condition of the facility by specialists working with the upper level system, which allows you to control the technical condition of all monitoring objects using these specialists.

Online analytical processing is automatically carried out in the upper level system by means of empirical modeling. Empirical models are constructed by statistical methods on the basis of a sample of the technological parameters of the object for the period of work, taken as a reference. The constructed model makes it possible to evaluate statistically significant deviations of the properties of the incoming current data from the properties of the sample points over the reference period online. This means assessing changes in the technical condition of the monitoring object. The applied modeling method is highly sensitive and allows detecting the slightest deviations in the technical condition and revealing the nucleation of a defect long before its significant manifestation.

In addition to fixing a possible deviation in behavior, modeling also indicates the degree of influence of various technological parameters on this deviation. Given the relationship of these parameters with the operating conditions of various units and parts of an object, a specialist can evaluate in which subsystem of the object changes have begun.

SUMiP is used for online monitoring 24/7 of the state of technical devices at hazardous production facilities and for preventive (predictive) diagnostics of possible failures and accidents. Monitoring of the state is carried out by monitoring the normal behavior of the objects under observation, including normal wear and tear (resource exhaustion), and identifying abnormal changes in the state, indicating an unexpected increase in the likelihood of adverse, including emergency, consequences.

The behavior of a turbine unit at different loads can vary significantly, therefore, to model its behavior, not only a single model is built, but a set of models corresponding to different operating modes. Switching between models is performed during online modeling automatically in accordance with the conditions of the change of mode. SUMiP created online models for the following operating modes:

• rated load;

• average load;

• low load;

• increase the load;

• load reduction;

• start-up;

• coasting;

• idle move;

• shaft rotation.

For each of these modes, models used in online modeling are built on the basis of samples from the reference period.

The module for controlling the position of the epicenter of the thermal field at the outlet of the gas turbine allows you to compare the state of the turbine at different points in time by the heterogeneity of the temperature distribution at the exhaust. The increase in heterogeneity leads to burnout of the guide vanes of the first stage of the gas turbine, to a decrease in its efficiency. In this case, the appropriate time for repair or maintenance is determined by the combination of factors of reliability and economic efficiency.

According to [1] and [2]:

- circumferential unevenness of the temperature field at the outlet of the combustion chamber should not be more than 10% of the average temperature;

- to accomplish this, the necessary accuracy of the flow cross sections of the air path of the combustion chamber and fuel distribution devices should be established in the technical documentation and controlled during manufacture and assembly;

- allowable circumferential and radial unevenness in the measurement plane and the choice of cross-section for temperature measurement is determined by the manufacturer of the gas turbine;

- monitoring of the operation of each flame tube should be provided, providing detection of an increase in the circumferential unevenness of the temperature field;

- vibration combustion or flame outages are not allowed during sudden changes in the operating mode of the gas turbine and atmospheric conditions (heavy rain, blizzard).

Compared with the methods known to the authors, the inventive method has high versatility and flexibility and allows you to achieve better results, in particular, to form an objective opinion on the basis of the data obtained regarding the change in the degree of temperature field non-uniformity.

Literature

1. STO 70238424.27.040.001-2008 Gas turbine units. Delivery conditions. Norms and requirements - M .: Standartinform, 2008

2. GOST R 52527-2006 Gas turbine units. Reliability, availability, operational manufacturability and safety - M .: Standartinform, 2006.

Claims (6)

A method for assessing the position of the epicenter of the thermal field of the exhaust of a gas turbine installation, comprising the following stages: 1) accumulate data on the position of the epicenter of the thermal field of the exhaust of a gas turbine installation for controlled gas turbine installations; 2) calculate the average temperature at the outlet of the gas turbine unit and the maximum deviations from the average temperature and accumulate these data; 3) obtain data on the position of the epicenter of the thermal field of the exhaust of the gas turbine installation, as well as the average temperature at the outlet of the gas turbine installation and the maximum deviations from the average temperature and form an opinion on the basis of the data obtained regarding the change in the degree of unevenness of the temperature field; 4) according to the results of step 3, the operation parameters of the gas turbine installation are automatically adjusted; 5) the obtained indicators and conditions in stages 2, 3 and 4 are stored and used as signaling and / or control actions, allowing to achieve safe and optimal functioning of a gas turbine installation or other similar gas turbine installations.