RU10219U1 - REGENERATIVE INSTALLATION OF HEAT STEAM TURBINE - Google Patents

Abstract

1. A regenerative installation of a cogeneration steam turbine, comprising coolers of the main ejectors and ejector of the end seals of the turbine cylinders sequentially installed in the main condensate path, a stuffing box heater and low pressure heaters equipped with bypass pipelines, a recirculation pipeline connected to the condenser, shut-off and regulating bodies, characterized in that on the bypass pipelines of the ejector cooler end seals and stuffing box heater set main condensate flow rate generators interacting with pressure sensors installed in the steam space of these devices, and the main condensate recirculation pipeline is connected to the feed line of chemically desalinated make-up water into the condenser, which is introduced into the lower part of the condenser through a water distribution device installed under the condenser tube bundle this recirculation valve is configured to let water pass in a volume that provides a given level of deaeration in the condenser. 2. The installation according to claim 1, characterized in that it is equipped with an additional raw (process) or chemically desalinated water heater installed in the main condensate recirculation circuit in front of the condenser and equipped with a bypass pipe through a heated medium with a flow controller installed on it, interacting with a hot temperature sensor coolant at the outlet of the heater and a pressure sensor in the condenser.

Description

Steam turbine regenerative installation

The utility model relates to the power system and can be used both in the creation of new regenerative plants and in the modernization of those already in operation at thermal power plants.

A known regenerative and network installation of a cogeneration steam turbine, comprising sequentially installed in the main condensate path coolers of the main ejectors and ejectors of the end seals of the turbine cylinders, stuffing box heater and low pressure heaters (PND), a recirculation pipe connected to the condenser, network heaters with heating condensate drain pipelines steam, locking and regulatory bodies 1.

The heat contained in the steam coming from the end seals of the turbine cylinders to the stuffing box heater and gasket ejector, and the heat contained in the air-air mixture, sucked from the condenser by the main ejectors, as well as the heat of the working vapor of the ejectors is transferred to the apparatus of these three types flowing through their pipe systems condensate, which then goes into the regeneration system.

Steam suction and condensation with preset pressure values will occur only if a certain minimum amount of basic condensate flows through the apparatus. However, when working with closed rotary control diaphragms of the low-pressure part (NPP), the amount of steam entering the condenser is small and the amount of condensate entering the regeneration system is insufficient for the normal operation of the apparatus. Therefore, under such conditions, the recirculation valve opens, through which an additional stream of the main condensate begins to flow, returning to the condenser and forming a recirculation loop.

During the operation of this recirculation scheme, the flow of the main condensate of the turbine, heated in the heat exchangers of the main ejectors, ejectors of the end seals and the stuffing box heater, enters the condenser through the recirculation valve, where it transfers the received heat to the circulation water and then to the atmosphere.

In the turbine cycle, only a small amount of tenlot is saved, which enters through the valve of the level regulator with part of the main condensate into the low-pressure regeneration system.

FOl to 13/00

As a prototype of the claimed utility model, the regenerative and network installation of a cogeneration steam turbine 2 is considered. The known installation is more economical in comparison with the analogue by solving the problem of heat conservation. The considered regenerative and network installation of a cogeneration steam turbine, contains successively installed coolers of the main ejectors and end seal ejectors (OECU) of the turbine cylinders, stuffing box heater and HDPE, a recirculation pipe connected to the condenser, network heaters with heating condensate drain pipelines, locking and regulatory bodies. The main condensate path at the outlet of the main ejector cooler and the end seal ejector cooler is additionally connected to the condenser and to the condensate drain pipe of the heating steam of the network heater, while in the main condensate path between the ejector coolers there is an additional shut-off element equipped with a bypass pipeline with a control body. In addition, all heat exchangers installed on the regenerative heating line are equipped with bypass piping with shut-off and control valves installed on them.

The proposed scheme of the known installation has several disadvantages.

Firstly, the dependence of the relevance of the operation of the end seals of the cylinders on the operating mode of the network water heating installation, even in the presence of a special scheme of self-sealing of the turbine cylinders. When operating the known installation, significant pressure limitations in the lower network heater lead to a decrease in the efficiency and maneuverability of the turbine unit as a whole. For example, the manufacturer of the T-100-130 turbine installation, the maximum temperature of the condensate in front of the cooler of the ejector of the end condensation is reached no more than 90 ° C. Corresponding to this temperature, the pressure in the lower network heater is 75-85 kPa, while the pressure in the lower heating system up to 200 kPa is allowed by the manufacturer.

An additional flow rate of chemically demineralized water (HOB) to the condenser for the temperature of the condensate entering the cooler of the end seal electoral cooler is not always possible. Exceeding the specified temperature leads to the soaring of the end seals of the turbine cylinders from the extreme chambers to the turbine hall and to the flooding of the oil lubricating the bearings. Further, if the condensate temperature limit before the OECS is met, then in this case the pressure in the network heater even at the estimated steam flow from the Molset seals will be higher than atmospheric (for example, with a reduced condensate flow), which will lead to a partial transition of the end seals to arbitrary self-sealing, to increase the relative elongations of the turbine rotors and the appearance of thermal shocks on them when changing the relays of the turbine installation.

Thus, the aforementioned dependence of the operation of terminal packings on the operation of the network heater leads to a decrease in the maneuverability and reliability of the turbine unit as a whole. The heat saving declared by the authors of the well-known installation can result in its losses due to restrictions on the operation of the network water heating installation.

Secondly, the presence of a significant amount of additional shut-off and control equipment in the nototype (shut-off and control valves on the recirculation line, on the bypass pipe, on the additional condensate line from the network heaters) significantly complicates the operation of the turbine unit and reduces its maneuverability.

For example, if you need a quick set of condensing power, additional switching and adjustments are required.

Thirdly, the discharge of colder condensate than the conventional scheme and an increased amount of additional CWD into the condenser using a standard input circuit under conditions of small passes of steam into the condenser, as is known, leads to a decrease in the deaerating capacity of the condenser, which, in turn, reduces reliability of the turbine and steam generator.

The inventive utility model solves the problem of eliminating the dependence of the operation of the end seals on the operating mode of the network heater at any operating conditions of the turbine by providing an adjustable supply of main condensate through the cooler of the ejector of the end seals and the stuffing box heater.

In this way, reliable operation of the installation is achieved, maneuverability without any switching, which determines the efficiency of the proposed regenerative installation scheme.

This goal is achieved by the fact that in the regenerative installation of a cogeneration steam turbine, which contains successively installed coolers of the main ejectors and the end seal of the turbine cylinders (OE and OECU), stuffing box heater and low pressure heaters (SP and PPD) equipped with bypass pipelines , a recirculation pipeline connected to the condenser, a pipeline for supplying make-up water to the condenser, shut-off and regulatory bodies, on OECU bypass pipelines the main condensate flow controllers are installed and the joint venture is installed, which interact with pressure sensors installed in the steam spaces of the OECU and the joint venture, and the main condensate recirculation pipeline is connected to the feed water line to the condenser, which is introduced into the lower part of the condenser through a water distribution device (ASU) located under a tube bundle of a capacitor, while the recirculation valve is configured to let water through in a volume that provides a given level of deaeration in the condenser. In addition, the installation

It can be equipped with an additional raw (process) or chemically desalinated water heater installed in the main condensate recirculation circuit on the supply line of the underflow condensate extractor in front of the condenser. The additional heater for the heated medium is equipped with a bypass pipe with a flow regulator installed on it, which interacts with the temperature sensor of the hot coolant at the outlet of the heater and the pressure sensor in the condenser.

The claimed combination of features provides the following technical effects aimed at increasing the reliability and efficiency of the installation.

Flow regulators installed on the bypass pipelines of OEKU and SP and interacting with pressure sensors in the steam space of these devices provide a stable design pressure in the steam space of OEKU and SP regardless of the turbine unit operating mode, flow rate and condensate temperature at the pressure of the condensate pump, and also regardless of the heating mode of the mains water. Due to this, there is minimal suction of air through the end seals into the vacuum system of the turbine. As a result, the vacuum in the condenser is increased, the amount of steam supplied to the seals is maintained at the lowest possible level, the turbine turbine rotors operate in a stable temperature regime.

Thus, an increase in vacuum in the condenser is achieved, a reduction in ventilation losses in the last stages of the turbine is achieved with small steam passes in the NPP.

In addition, studies have shown that to ensure the standard level of oxygen in the condensate at the outlet of the condenser, the total amount of additional water and recirculation condensate supplied to the lower part of the condenser under its tube bundle should be at least 4-5 times higher than the amount condensate draining from the tube bundle. Moreover, all water supplied to the condenser must be superheated relative to the saturation temperature at a pressure in the condenser of 4-6 ° C.

With increased ventilation passages of steam into the condenser, this condition is achieved by setting the recirculation valve to the condensate flow rate, somewhat larger than is necessary for the normal operation of the coolers of the main ejectors and OECU. At the same time, the increased consumption of recirculation condensate ensures the normal operation of the regulators on the OECU and SP bypass pipelines with constant heat consumption in the main condensate path.

The supply of recirculation condensate to the cold (25-30 ° С) make-up HOV line allows it to overheat, set relative to the saturation temperature at the pressure in the condenser, and to partially utilize the excess heat of the recirculation condensate.

The supply of condensate to the lower part of the condenser, but its tube bundle through the water distribution device in the form of an unfolded surface of superheated water, allows reliable deaeration of this water and avoid its subsequent infection with oxygen on the tube bundle.

An additional raw (process) or HOV heater installed in the main condensate recirculation circuit on the feed line of the HOV in front of the condenser provides a mixture of condensate and HOV not heated at 4-5 ° C relative to the saturation temperature at the pressure in the condenser, which allows you to utilize the excess heat of recirculation the main condensate and, thereby, further improve the efficiency of the inventive regenerative installation.

The utility model is illustrated by the drawing, which depicts a schematic diagram of the installation.

The regenerative installation of the cogeneration steam turbine contains a condenser 1, to which the main condensate path 2 is connected. A condensate pump 3, a cooler 4 of the main ejectors (OE) and a cooler 5 of the ejector of the end seals of the turbine cylinders (OEKU), stuffing box heater 6 (SP) and low-pressure heater 7 are installed in series 2 in series. A recirculation pipe 8 is connected to the path 2 with a recirculation valve 9 and a level valve 10 in the condenser 1 installed on it. To ensure a given level of oxygen content of the condensate at the outlet of the condenser, the valve 9 is set to the flow rate of water passed through it, exceeding the amount of condensate 4-5 times flowing down from the tube bundle of the capacitor 1.

OECU 5 and SP 6 are equipped with bypass pipelines 11 and 12, on which the condensate flow controllers 13 and 14 are installed. These regulators provide the necessary flow of condensate through the bypass pipelines 11 and 12 depending on the pressure level in the steam spaces of OECU 5 and SP 6 and operate on the signals of pressure sensors 15 and 16 installed in the steam space of these devices.

The main condensate recirculation pipe 8 is connected to the line 17 for supplying chemically demineralized water (CHOW) to the condenser 1. The pipe 17 is connected to the lower part of the condenser 1 and is equipped with a water distribution device (ASU) 18 installed under the tube bundle of the condenser 1.

An additional preheater 19 of raw (process) water entering it through a pipe 20 or HOV supplied to the deaerator can be installed on the HOV pipeline 17. The heater 19 for heated water is equipped with a bypass pipe 21, on which a flow controller 22 is mounted, interacting with a temperature sensor 23 installed in the pipe 17 after the heater 19 and a pressure sensor 24 installed in the neck of the condenser 1.

The regenerative installation of a cogeneration steam turbine in modes of operation with small passes of steam into the condenser works as follows.

The main condensate from condenser I is fed through path 2 by a condensate pump 3 to the cooler 4 of the main ejectors and through it to OECU 5 and partially in addition to it through the bypass pipe 11 through the regulator 13, which, by the signal of the sensor 15, passes the condensate in the amount necessary to maintain the given pressure in the steam space of the cooler 5 (for example, 97-99 kPa). After the cooler 5 and the bypass pipe 11, the main condensate passes through the joint venture 6 and partly in addition to it through the bypass line 12 through the regulator 14, which, by the signal from the sensor 16, passes through itself in the volume necessary to maintain the given pressure in the steam space of the joint venture 6 (for example, 85-95 kPa).

Next, the main condensate is divided into two flows: the first through the recirculation valve 9 enters through the recirculation pipe 8 to the supply line 17 HOV, and then to the condenser 1;

The second through the level valve 10 in the condenser is fed to the RPM 7. The recirculation valve 9 is adjusted to the volume of water passed through it, including the water supplied to the HOV condenser, 4-5 times greater than the condensate flowing from the tube bundle of condenser 1, which ensures the normal operation of cooler 4 main ejectors and provides a sufficient level of deaeration of the condensate in the capacitor 1.

Through pipeline 17, the mixture of condensate and HOV enters the heater 19, where heated water arrives through pipe 20, part of which is bypassed through bypass pipe 21 through the flow controller 22, which operates according to the signals of sensors 23 and 24. The controller 22 passes water in the amount required for maintaining a given superheat (4-6 ° C) relative to the saturation temperature at a pressure in the condenser.

In the case of the execution of the regenerative installation scheme without a heater 19, the mixture of condensate and HOV through the pipe 17 enters the condenser 1. In either case, the mixture enters the lower part of the condenser 1 through the ASU 18 under its tube bundle, and is distributed in the form of boiling films, drops, jets and deaerated.

When the turbine unit is switched to the condensing mode of operation, the recirculation valve 9 is closed, the heat exchanger 19 is turned off, the supply of HOV is carried out by a corresponding pipeline (not shown) to the upper part of the condenser.

The advantage of the claimed utility model is that it provides reliability and cost-effectiveness in all operating modes of the turbine.

Sources of information taken into account when compiling

Descriptions of utility model “Regenerative installation

thermal steam turbine

1.Benenson E.I., Ioffe L.S. Heating steam turbines. M., "Energy, 1980, p. 11-15.

2.Antonov E.I., Bazilinsky V.N. A new recirculation scheme for the main condensate of the T-100-130 cogeneration turbine. - Optimization of the operating modes of low pressure cylinders of powerful heating turbines. Collection of scientific works / VTI, M., “Energoatomizdat, 1989, p.60-66.

Claims (2)

1. A regenerative installation of a cogeneration steam turbine, comprising coolers of the main ejectors and ejector of the end seals of the turbine cylinders sequentially installed in the main condensate path, a stuffing box heater and low pressure heaters equipped with bypass pipelines, a recirculation pipeline connected to the condenser, shut-off and regulating bodies, characterized in that on the bypass pipelines of the ejector cooler end seals and stuffing box heater set main condensate flow rate generators interacting with pressure sensors installed in the steam space of these devices, and the main condensate recirculation pipeline is connected to the feed line of chemically desalinated make-up water into the condenser, which is introduced into the lower part of the condenser through a water distribution device installed under the condenser tube bundle this recirculation valve is configured to let water pass in a volume that provides a given level of deaeration in the condenser. 2. The installation according to claim 1, characterized in that it is equipped with an additional raw (process) or chemically desalinated water heater installed in the main condensate recirculation circuit in front of the condenser and equipped with a bypass pipe with a flow regulator installed on it that interacts with the sensor temperature of the hot fluid at the outlet of the heater and a pressure sensor in the condenser.