RU2797086C1 - Steam turbine plant with main condensate recirculation system and lubrication system - Google Patents

Abstract

FIELD: thermal power engineering.

SUBSTANCE: invention relates can be used in the design of new STPs and modernization of existing STPs. The present invention is intended to provide heating of the oil of the TU lubrication system and lowering the temperature of the main condensate entering as a cooling medium for condensing the working steam of the basic ejector and steam from the end seals of the turbine in the sealing ejector and sealing heater, thereby ensuring their normal operation. This is achieved by the claimed STP, which includes a turbine with a condenser connected to its exhaust part with a main bundle of cooling pipes with cooling water passing through them, a condensate trap with a connected condensate pump pumping the main condensate formed from the steam entering the condenser vapor space, depending from interconnected control valves of the main condensate and recirculation through the coolers of basic ejector, sealing ejector, sealing heater to the heaters of the regenerative system. A surface water-oil heat exchanger is connected to the main condensate line of the turbine regenerative system by its inlet on the water side, and to the return line of the recirculation flow to the vapor space of the condenser by its outlet on the water side. A distinctive feature of the claimed STP is that on the oil side, the surface water-oil heat exchanger is connected by a pipeline to the zone of cold oil of the oil tank by its inlet pipe, and to the heated oil zone of the oil tank of the lubrication system of the steam turbine plant by its outlet pipe.

EFFECT: eliminating the disadvantages of equivalents.

1 cl, 1 dwg

Description

The invention relates to thermal power engineering and can be used in the design of new and modernization of existing steam turbine plants (STU).

Known PTU, including condensing or heating turbines operating on the condenser (K), regenerative system, recirculation system of the main condensate.

The recirculation system of the main condensate is used at the stages of preparation for operation and at a number of operating modes of the STU, when steam from the turbine, as well as steam and water from other sources, may not come to the K at all or come at a limited cost. As a result, the condensate formed in the C from these steam and water flows is not enough for the normal operation of the condensate pumps (CP), the main ejector (EO), the seal ejector (ES), the stuffing box heater (PS).

In this case, to maintain the normal operation of the specified equipment, this limited flow of condensate through the recirculation line returns to K. Details on the operation of the main condensate recirculation system (G.D. Barinberg, Yu.M. Brodov, A.A. Goldberg et al., Steam Turbine turbines of the Ural Turbine Plant, under the general editorship of Doctor of Technical Sciences Yu.M. Brodov and Ph.D. V.V. Kortenko, 2nd ed. 488 pp., pp. 64-66, 417-420 [1]).

In condensing turbines, the main condensate recirculation system operates in starting modes, in modes with a minimum condensate load. The condensate recirculation flow gives off the heat received in the EC, EC and PS to the circulating water and for the STP cycle with condensing turbines it is lost. For cogeneration turbines, regimes with large thermal loads and low steam flow rates in K can last for a long time (p. 419 [1]). At the same time, heat losses with the recirculation flow in this case may not occur, because some cogeneration turbines operate on K, equipped with built-in bundles (IP), through which network or make-up water is passed (Fig. 7.3, p. 360 [1]). Heating in the VP, for example, network water, is the first stage of its heating. For further heating, the network water is directed to the network heater(s). In this case, the heat of the recirculation flow is utilized in the HPC. The disadvantage of the known solution is that for STP with condensing-type turbines, as well as with cogeneration turbines, in which there is no HP, the heat recovery of the main condensate recirculation stream is not possible.

Useful use of this heat in STP with heat-extraction turbines, where there is no VP in K, is carried out in a well-known installation, adopted as a prototype (Invention "Heating steam turbine plant with a cooler of the main condensate on its recirculation line", patent No. 2714020, publ. 11.02.2020, [2-prototype]). A surface cooler of the recirculating condensate is installed on the recirculation line, connected on the cooling side to the network water line to the bypass to the network pump, which allows, on the one hand, to return the excess heat of the main condensate recirculation flow to the heating cycle, and on the other hand, to reduce the temperature of the main condensate , which enters as a cooling medium for condensing the exhaust steam of the steam ejector and steam from the end seals of the turbine, thereby ensuring their normal operation. However, it is known that the start-up of the STP with a heating turbine is carried out in the condensing mode, when circulating water is passed through the K, and the connection of the extraction for heating and the start-up of the network installation occurs with a delay in time (Benenson E.I., Ioffe L.S., Heating steam turbines, edited by D.P. Buzin, 2nd ed., revised and supplemented, M.: Energoatomizdat, 1986, 272 p., p. 259, [3]). Thus, the disadvantage of this solution [2] is that during this period it is not possible to utilize the heat of the recirculation flow of the main condensate in the STP with cogeneration turbines. It is also not possible to use this solution with condensing type turbines, which do not have an installation for heating network water.

The technical problem to be solved by the claimed invention is the inability to utilize the heat of the recirculation flow of the main condensate in the STP with condensing-type turbines and with cogeneration turbines, to which there are no VP, during their start-up in the condensing mode.

It is proposed to use the heat of the recirculation flow of the main condensate in the STP in the lubrication system, which provides the supply of turbine oil to the bearings of the turbine and generator (HA). The supply of oil to the TA bearings is one of the initial start-up operations. The temperature of the oil for lubrication must be within certain limits. As a rule, when mineral oils are used, this is 40°С - 45°С (RD 34.30.508-93, Standard operating instructions for oil systems of turbine plants with a capacity of 100-800 MW, operating on mineral oil, clause 5.4.1 [4]) . Oil coolers are used to lower the oil temperature. Moreover, starting the turbine at a low oil temperature, below the limit set by the manufacturer, is also not allowed (SO 153-34.20.501-03, Rules for the technical operation of power plants and networks of the Russian Federation, clause 4.4.24 [5]). To increase it, additional time is required for idle oil pumping during the period of preparatory work for the launch of the TA, or electric oil heaters are used. In the first case, the total time of launch operations increases, in the second - although slightly, but the costs for the station's own needs increase, the implementation of the rules for ensuring electrical safety is required. For example, for a Tp-115 / 130-12.8 turbine with a TF-125-2U3 generator, an ETMA NTM-70E U1 unit with a power of 70 kW and a voltage of 400 V is used as an electric heater.

The technical result of the present invention is, on the one hand, the provision of heating of the HE oil using the heat of the recirculation flow of the main condensate in the STP with heating turbines without HP in the K during their start-up and in the STP with condensing-type turbines, and, on the other hand, lowering the temperature the main condensate coming as a cooling medium for condensing the working steam of the EO and steam from the end seals of the turbine in the power plant and PS, thereby ensuring their normal operation.

The technical result is achieved by the claimed PTU, which includes a heating turbine without VP in K, or a condensing-type turbine with K connected to its exhaust part with a main bundle of cooling pipes with cooling (circulating) water passing through them, a condensate collector K with a connected HP pumping the main condensate formed from steam entering the steam space K, depending on the interconnected control valves of the main condensate and recirculation through the EO, EI, PS coolers to the heaters of the regenerative system. A surface water-to-oil heat exchanger is connected to the main condensate line of the turbine regenerative system with its inlet on the water side, and with its outlet on the water side to the return line of the recirculation flow of the main condensate to the steam space K. its inlet pipe is connected by a pipeline to the cold oil zone of the oil tank, its outlet pipe is connected by a pipeline to the heated oil zone of the oil tank of the PTU lubrication system.

In the course of the patent information search, no information was identified that became publicly available in the world before the priority date, which contains a combination of essential features specified in the independent claim of the claimed invention. Therefore, the claimed invention meets the criterion of patentability "novelty".

After an additional analysis of all found analogues, it was found that as a result of using the claimed PTU, characterized by the features indicated in the claims, a technical result that was not obvious to a specialist was obtained, which confirms compliance with the "inventive step" criterion.

The claimed invention is illustrated by the attached figure, which shows a diagram of the proposed PTU, consisting of a heating or condensing turbine 1 with a K 2 connected to its exhaust part with a condensate collector 3, the main bundle of cooling pipes 4 with cooling (circulating) water passed through them to condense the outgoing turbines 1 pair. A main condensate line 5 is connected to the condensate collector 3, which is directed by the CV 6 to the regenerative system, which includes EO 7, PU 8, PS 9 and heaters of the regenerative system located behind the control valve of the main condensate RK 10. On the recirculation line 11, passing through the water side of the surface water-oil heat exchanger 12, a recirculation control valve RK 13 is installed. Through line 14, the condensate cooled in the surface water-oil heat exchanger 12 returns to the steam space K 2. The lubrication system includes bearings 15 of the turbine 1, connected by pressure lines 16 with oil coolers (conditionally not shown) and drain lines 17 connected to zone 18 of heated oil of oil tank 19. Oil tank 19 is connected via line 20 to the suction of oil pump MN 21, which is connected by line 22 with zone 23 of cold oil in oil tank 19 with its pressure pipe. This zone is connected by an oil supply line 24 with a shut-off element 25 to the inlet pipe on the oil side of the surface water-oil heat exchanger 12, which is connected by its outlet pipe on the oil side with an oil supply line 26 to the shut-off body 27 with the zone 18 of the heated oil of the oil tank 19.

Declared PTU works as follows.

When the PTU is started from a cold state, especially after a long period of inactivity, the oil in the lubrication system may be below the permissible temperature. For PTU manufactured by JSC "Ural Turbine Works" the minimum allowable oil temperature supplied to the lubrication of bearings THAT is 40°C. the oil supply lines 26 to the zone 18 of the heated oil of the oil tank 19 from the surface oil-water heat exchanger 12 are open. MN 21 of the turbine lubrication system pumps oil through the surface water-oil heat exchanger 12.

During the same operating modes of the PTU, K 2 receives a limited steam flow and the flow rate of condensate formed in K 2 from this steam, pumped out by KN 6 from condensate collector 3, directed through RK 10 to the heaters of the regenerative system, is not enough to maintain the required level in KN 6 and flow through EC 7, EC 8, PS 9 to ensure a reliable process of condensation of working steam in EC 7 and steam from the seals in EC 8, PS 9. In this case, RC 10 is covered (closed), while RC 13 is opened (opened) at the same time. Accordingly, part or all of the flow of the main condensate is sent through the recirculation line 11 to the inlet of the surface water-oil heat exchanger 12, heating the oil in it to the required temperature.

Thus, the above information testifies to the fulfillment of the following set of conditions when using the invention:

- PTU, embodying the claimed invention in its implementation, is used in turbine building,

- PTU, embodying the claimed invention, is able to achieve the technical result perceived by the applicant.

Therefore, the proposed technical solution meets the criterion of patentability "industrial applicability".

Claims (1)

A steam turbine plant, which includes a heating turbine 1 without built-in bundles in the condenser 2 or a condensation-type turbine with a condenser 2 connected to its exhaust part with a main bundle of cooling pipes 4 with cooling water passing through them, a condensate collector 3 of the condenser 2 with a connected condensate pump 6, pumping the main condensate formed from the steam entering the steam space of the condenser 2, depending on the interconnected control valves of the main condensate 10 and recirculation 13 through the coolers of the main ejector 7, seal ejector 8, stuffing box heater 9 into the heaters of the regenerative system, and to the line of the main condensate 5 of the turbine regenerative system, its inlet on the water side is connected to the surface water-oil heat exchanger 12, and its outlet on the water side is connected to the line 14 of the return flow of the main condensate recirculation to the vapor space of the condenser, characterized in that the surface oil-to-water heat exchanger 12 is connected to the oil side with its inlet pipe is connected by a pipeline to the zone 23 of the cold oil of the oil tank 19, by its outlet pipe to the zone 18 of the heated oil of the oil tank 19 of the lubrication system of the steam turbine plant.

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