PL60054B1 - - Google Patents

Description

Published: 30.V.1970 60054 IC. 14 h, 1/14 MKP F 01 kf / 3f UKD Inventor and Zbyszko Jaroszewicz, Warsaw (Poland) Patent owner: Turbine set with serial heating of network water in heat exchangers The subject of the invention is a turbine set with series heating of network water in exchangers heat exchangers are supplied from controlled vents of the turbine, in which the pressure is set to a given value by means of rotary diaphragms installed between the stages of the turbine and throttling the steam flow . These diaphragms are completely open during the operation of a condensation turbine, but nevertheless they are then also a source of additional losses of flow resistance and cause that the efficiency of such a turbine in operation with condensation is significantly lower than the efficiency of a condensation-only turbine for the same steam parameters. and of the same power. The apparatus according to the invention does not suffer from these drawbacks. Its essence lies in the fact that the turbine set with serial heating of the network water in the seed heat exchangers, the heating surface of the heating plant built in the condenser is the first stage of heating the network water and the unregulated steam outlet supplying the heat exchanger which is the second stage of heating the network water. and possibly further unregulated discounts for feeding heat exchangers. Unregulated discharge and counterpressure pressures are set on a self-regulating basis without intervention by the regulatory body. Thanks to this, the turbine set can work either on condensation and then the pressure in the condenser is within the range of 0.04-0.07 at, or on heat generation and then the pressure in the condenser is 0.25-0.85 The turbo set according to the invention has a bypass line on the main water main of the CHP plant, which serves to bypass one or two first stages of heating the network water. This enables simultaneous operation of the turbine set for heating and condensation. In this case, the network water is heated in heat exchangers fed from the turbine's vents with a higher pressure. According to the invention, the turbine set in accordance with the invention also has a built-in throttle valve in the passage supplying steam to the low-pressure turbine body, which serves to set the set pressure value of the steam consumed. before the flap to the peak heat exchanger. In this way, the high temperature of the district water supplying the municipal consumers with heat is obtained, required during periods of heat peak. The device of the invention is exemplified in a schematic drawing. The turbine 1 has a condenser 2 equipped with a normal cooling water circuit with a cooling tower 3 and a cooling water pump 4. This circuit is connected by a cooling water line 5 to the condensation area 6 in the condenser. The turbine set also has a heating surface 7 built into the condenser, which constitutes the first stage of heating the network water. The unregulated discharge 8 of the turbine supplies the heat exchanger 9, which is the second stage of heating the network water. The heat exchanger 10, the feed steam from the sink 11, is a further stage of district heating and is a peak heat exchanger, working essentially during periods of peak heat load when the district heat consumers 12 receive the mains water from the outlet main 13 with the highest temperature. . The heating cycle also includes a network water pump 14, a return heat main 15 and a bypass line 16 on the heat main in the heat and power plant. The turbine set has in the passage 17, which leads some steam to the body of the low-pressure turbine, a choke 18 By setting the damper at the right angle, the required value of steam pressure in front of the damper can be obtained. This steam is drawn to the top heat exchanger 10. In cases where the set temperature of the network water can be achieved by self-regulation or when the turbine set works exclusively for condensation, the throttle valve is in a position parallel to the axis of the passage in the turbine and practically Then it does not give any loss of flow resistance. The turbine according to the invention can be built as a high-efficiency unit with steam reheating, with efficiency in condensing operation not lower than the efficiency of normal condensing turbine sets for the same steam parameters and for the same During basic heating operation, the efficiency of the last stages of the turbine will decrease, but for the whole turbine it will also be very high. A significant decrease in the efficiency of the turbine will occur only during the heating peak, which lasts on average about 500 hours. per year and there is no major impact on the economic operation of the power plant. Due to its ease of converting the turbine from heating to condensing operation and vice versa, it can be used to generate electrical peak power equal to the rated power by converting the turbine to condensation. The missing amount of heat in the district heating network can in this case be supplemented by overheating the water in the network during the hours of low electrical loads. 15 PL

Claims (3)

Claims 1. Turbine set with serial heating of network water in heat exchangers, characterized by the fact that it comprises a heating surface (7) built in the condenser (2). constituting the first stage of heating the network water and the unregulated steam bleed (8), feeding the heat exchanger (9), constituting the second stage of heating the network water, which enables the turbine to work for condensation or heating. 2. Turbine set according to claim A bypass line (16) which serves to bridge the heating surface (7) or heat exchanger (9) installed in the condenser with an active network on the main water main of the heat and power plant. heating, which enables simultaneous operation of the turbine set for heating and condensation. 35 3. Turbine set according to claim A throttle valve (18) is installed in the passage (17) supplying steam to the low-pressure turbine body (.1), which serves to set the desired value of the pressure of the steam taken upstream of the flap to the heat exchanger (10). KI. 14 h, 1/14 60054 MKP F 01 k PL