LT5853B - Modified condensing steam turbine plant - Google Patents

Abstract

The invention relates to condensing steam turbines and can be used in power plants. Modified steam turbine plant with a steam turbine with high, medium and low pressure cylinders, which is mounted on a common shaft with a generator, steam boiler, high and low pressure steam heaters, condenser is connected to condensate pump, further have installed steam - water heater (10), a steam circuit of which is connected with turbine (1) medium-pressure cylinder (3) medium-pressure zone (4), and the water circuit is connected with thermofication networks, on the output of a medium-pressure cylinder low-pressure zone (5) to capacitor (11) and to the low pressure cylinder (6) is mounted plug (21), while on the low-pressure cylinder (6) outputs and inputs equipped with closing valves (22). In addition, medium-pressure cylinder (3) low-pressure zone (5) and low-pressure cylinder (6) arranged without work wheels.

Description

The invention relates to condensing steam turbines and is used in power plants. Known technical solution for increasing steam supply by multi-stage heaters from uncontrolled turbine removals by installing two-valve adjustable valves controlled by servo motors offered by LMZ turbine manufacturer K-300-240-1 and used in Greek power plants Agios Dimitrios, Amindeor ", Meliti Achlada."

The disadvantage of this method is that only about 70 MW of heat is available, and the fuel utilization rate increases by only 47%, i.e. the turbine generates up to 293 MW of electricity (instead of 300 MW at nominal) and 70 MW of heat suitable for cogeneration.

A known technical solution is the removal of controlled steam from the turbine by installing special controlled valves on steam pipes connecting medium and low pressure cylinders. Such solution is proposed by LMZ turbine manufacturer K-300-240-1 and is used in Russian power plants in Sredneuralsk and Surgutsk. This technical solution allows up to 360 t / h of turbine removal. steam or 232.6 MW of cogeneration heat, while reducing electric capacity to 277 MW.

This technical solution increases the fuel utilization rate up to 66%, but the turbine modified in this way is less economical than Kaunas and Vilnius cogeneration turbines (fuel utilization rate is about 80%).

The closest analogue to the proposed technical solution is the K-300-240-1 condensing steam turbine unit, which is also used in the Lithuanian Power Plant and is mentioned in the book A.D. 7.16. (A.J. TpyxHnfi, C.M.JIoceB CTauHOHapHue napoBbie Typ6nHbi, MocKBa, 3Hepron3ąaT, 1981, pnc. 7.16). This steam turbine unit consists of a steam boiler, high and low pressure steam heaters, condenser, generator, condensate pump, steam turbine with high, medium and low pressure cylinders. 975.0 tonnes of steam from the boiler are fed to a high pressure cylinder and, after part of the energy is transferred to the impellers, returned to the boiler for overheating and fed to a medium pressure cylinder with medium to low pressure zones. 458.5 tons of steam is fed into the low pressure cylinder after the medium pressure zone and the remaining steam into the low pressure part of the medium pressure cylinder. After working, the steam, after the low pressure impellers, enters the condenser, where it releases heat to the cooling water, condenses and returns to the boiler in the form of water.

The disadvantage of such a condensing steam turbine unit is that up to 54% of unused heat is emitted to the environment with cooling water.

The object of the present invention is to achieve the maximum fuel utilization rate by utilizing the thermal energy of steam condensation usefully for cogeneration.

The object is achieved by the state of the art being known as a condensing steam turbine unit having a steam turbine with high, medium and low pressure cylinders mounted on a generator shaft, a steam boiler, high and low pressure steam heaters, a condenser connected to condensate pumps, has a newly installed steam-water heater with a steam circuit connected to a turbine medium pressure cylinder medium pressure zone and a water circuit to the heating networks, a medium pressure cylinder low pressure zone outlet to the condenser and a low pressure cylinder mounted low-pressure cylinder outlets and inlets are fitted with shut-off valves and the medium-pressure cylinder's low-pressure zone and low-pressure cylinder are mounted without impellers.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is further explained in the accompanying drawings and in a specific description of the device. The drawing shows a block diagram of a steam turbine unit after modification.

The steam turbine unit comprises a turbine 1 consisting of a high pressure cylinder 2 mounted on a common shaft, a medium pressure cylinder 3 having a medium pressure zone 4 and a low pressure zone 5, and a low pressure cylinder 6 and a generator 7. The steam turbine 1 the inlet of cylinder 2 is connected to boiler 8 and the outlet through boiler superheater 9 is connected to the inlet of medium pressure zone 3 of medium pressure cylinder 3. The vapor circuit of the medium pressure zone 3 of the medium pressure cylinder 3 is connected to a steam-water heater with a condensate cooler 10, the water circuit of which is connected to the heating networks. The unit is provided with appropriately coupled capacitors 11, stage I condensate pump 12, stage II condensate pump 13, block desiccator 14, outlet pump 15, low pressure heaters 16, high pressure heaters 17, buster pump 18, turbo drive power pump 19, power supply the pump 20. The turbine 1 is connected to the low pressure heaters 16 and the high pressure heaters 17 respectively. 6. Shut-off fittings mounted on all inlets and inlets of the low pressure cylinder 22. In connection with the turbine modification, the low pressure cylinder 6 is disconnected, the low pressure zone 5 of the medium pressure cylinder 3 and the blades of the low pressure cylinder 6 are dismantled.

The steam turbine unit works this way.

From boiler 8 steam (volume 975.0 tons, pressure 240 bar and temperature 540 ° C) is fed to high pressure cylinder 2 and, after supplying part of the energy to the blades of said cylinder 2, is returned to boiler 8 at 290.6 ° C. a superheater 9, of which 790.0 tonnes of steam, having a pressure of 42.6 bar and a temperature of 539.7 ° C, are fed to the medium pressure zone 4 of the medium pressure cylinder 3. from the armature 22, the steam flow from the power pump turbocharger 19 is directed only to the low pressure heater 16. After supplying part of the energy to the 3 blades of this cylinder, all steam (582.6 tonnes / h, 2.28 bar, 190.3 ° C) is directed. to a steam-water heater with a condensate cooler 10, in which the steam condenses into the water and releases the heat of condensation to the cogeneration water by heating it to 120 ° C. The 120 ° C cogeneration water is supplied to the consumers and, after supplying their own heat at 60 ° C, returns to the steam-water heater 10 for heating, and the condensate returns to the boiler 8 via pumps 12, 13 via low pressure heaters 16 and high pressure heaters 17.

After the modification, the turbine produces 225 MW of electricity and 400 MW of heat (t =

120 ° C) and achieve a fuel efficiency ratio greater than 85%.

Claims (2)

DEFINITION OF INVENTION 1. A modified condensing steam turbine unit having a steam turbine with high, 5 medium and low pressure cylinders mounted on a generator shaft, a steam boiler, high and low pressure steam heaters, a condenser connected to condensate pumps, characterized in that: has a newly installed steam-water heater (10), the steam circuit of which is connected to the middle pressure zone (4) of the medium pressure cylinder (3) of the turbine (1), and the water circuit of the low pressure medium cylinder A pressure blind (21) is mounted on the outlet of the 10 pressure zones (5) to the condenser (11) and to the low pressure cylinder (6), and the closing fittings (22) are mounted on all the outlets and inputs of the low pressure cylinder (6). Modified condensing steam turbine unit according to claim 1, characterized in that the low pressure zone (5) and the low pressure cylinder (6) of the medium pressure cylinder (3) are mounted without impellers.