RU2266479C1 - Heat supplying method - Google Patents

Abstract

FIELD: power engineering, in particular, centralized heat supplying systems.

SUBSTANCE: method includes heating grid water in grid heaters of heating energy plants, feeding hot water via feeding water main to heating and hot water providing systems, cooling of reversed grid water by heat pump plants, positioned at heat stations, returning of cooled water via reverse water main to grid heaters, while heat pump plant is made cascading with finalizing water loop, in upper branch of cascade, positioned at heat station, secondary heating of water of heating system is performed due to additional cooling of reverse water of heating system, by water loop of grid water and heating system upper and lower cascades of thermal pump plant is closed, and in lower branch of cascade, positioned at thermal power station, heating of cooled reversed grid water is performed due to heat of condensation of steam processed in turbine.

EFFECT: higher efficiency of heat power station and heat supplying grid, increased heat productiveness of heat supplying system.

1 cl, 1 ex, 1 dwg

Description

The invention relates to a power system, in particular to district heating systems.

A known installation of heating and hot water supply (as RU RU 2155302 C1. Installation of heating and hot water supply. IPC F 24 D 17/02, 3/18, 2000), including a low potential heat source, a circulation circuit, a heat pump with an evaporator and a condenser, a heating system, as a heat source of low potential, contains a sewage well of a sewage network with a heat exchanger and vibrator located in it. The installation will provide an individual residential building with heat and hot water, however, it is impossible to heat a multi-storey residential building in a city with such an installation due to the insufficient heat of a low potential heat source. On the other hand, the advantages of district heating are also not used when one heat source serves the heat-consuming devices of a number of consumers located separately (Tikhomirov K.V., Sergeenko E.S. Heat engineering, heat supply and ventilation. - M.: Stroyizdat, 1991. - S. 346-347).

As a prototype, we take A.S. RU 2095581 C1. Heat supply system. IPC 6 F 01 K 17/02, 1997. The heat supply system, consisting of a heating installation including a main steam power circuit, a cooling water circuit, a primary network water circuit with hot water and heating water heaters, and a heating system circuit with an elevator, is equipped with a heat pump installation located at heating points, and the heat pump installation is connected via the return circuit water of the primary circuit to the input / output of the evaporator, and via the return circuit of the heating system to the condenser input / output from Novki control valves on the respective paths. The output of the heat pump installation along the evaporator path is connected to the return mains water pipe, through which the cooled mains water is transported and fed to the turbine condenser inlet, and the input of the heat pump installation along the evaporator path is connected to the return mains water pipe behind the primary water mains circulation pump. The return network water after the turbine condenser enters the network heater and then into the main pipeline of direct network water.

The main disadvantage of the prototype is that the chilled reverse network water enters the turbine condenser, at the outlet of which the water temperature does not exceed an average of 20 ° C. For example, for a steam turbine T-100-130 (Heat engineering reference book / Ed. By V.N. Yurenev and P.D. Lebedev. T.1 - M.: Energy, 1975. - S.372-373) the pressure of the exhaust steam is 0.054 MPa, and the cooling water temperature (calculated) is respectively 20 ° C. Therefore, water with such a temperature must be heated to a standard temperature (the existing average value of the temperature of the water leaving the heating devices in the return pipe of the heating system is 70 ° C (Tikhomirov K.V., Sergeenko E.S. Heat engineering, heat supply and ventilation. - M .: Stroyizdat, 1991. - P.194)), for which it is necessary to install an additional network heater and carry out additional steam extraction, thereby reducing the generation of electricity by steam and reducing the absolute efficiency of the turbine (Ryzhkin V.Ya. Those electric power stations. - M.: Energoatomizdat, 1987. - P.26-27).

The purpose of the invention is to increase the efficiency of the thermal power station and heat supply network, to increase the heat output of the heat supply system.

The essence of the invention lies in the fact that a heat supply method is implemented, including heating network water in network heaters of heating power plants, supplying hot water through a supply main pipe to heating and hot water systems, cooling the return network water using heat pump units located at heating stations, returning chilled water through a return main pipeline to network heaters, characterized in that the heat pump installation is performed in cascade with with a closing water loop, in the upper branch of the cascade located at the heat point, secondary heating of the heating system water is carried out by additional cooling of the return water of the heating system, the upper and lower stages of the heat pump installation are closed with a water loop of the heating water and the heating system, and in the lower branch of the cascade, located at the thermal power plant, they carry out the heating of the cooled return network water due to the heat of condensation of the steam spent in the turbine. An increase in thermal efficiency and an increase in the heat output of the heat supply system are achieved by the following: a decrease in the water temperature in the return main pipeline carried out by the upper branch of the cascade helps to reduce the consumption of network water and reduce the cost of pumping the coolant; when the temperature in the return pipe decreases, the average annual temperature of the coolant (network water) decreases, which helps to reduce the cost of heat losses (Sokolov E.Ya. Heat supply and heat networks. - M. - L: Gosenergoizdat, 1963. - S.325-327). In addition, the use of the condensation heat of the steam exhausted in the turbine in the first stage of the network heater (the lower branch of the cascade) increases the efficiency of the station, since the selected steam previously supplied to the network heater is sent to the turbine to generate additional electricity.

The drawing shows a device for implementing the proposed method. The device contains a cascade heat pump installation (HPU). The lower branch of the cascade, located at the thermal power plant, consists of a condenser 1, an evaporator 3, a compressor 2 and a heat pump choke 5 (VT). The upper branch of the cascade, located at the heat point, consists of a condenser 13, an evaporator 16, a compressor 15 and a heat pump choke 14. The water loop of the network water consists of a network heater of the lower stage (condenser 1 of the heat pump), a network heater of the upper stage 6, a peak water boiler 7, a heating pipe supplying network water 18, a water heater of the heating system 11, a return heating pipe of network water 19 and a network pump 17. Water the loop of the heating system consists of a water heater of the heating system 11, an expansion tank 8, heaters 9, a circulation pump 10, a water heater for the secondary heating of the heating system water ( heat pump condenser 13), heating devices 12, water cooler of the heating system (evaporator 16). A water loop of the network water and the water of the heating system closes the upper and lower branches of the cascade of the heat pump installation. When the device is operating, water is circulated by a circulation pump 10 into the elements of the heating system. In the water heater 11, the water of the heating system is heated by mains water, and in the heaters 9, heat is given to the consumer. Secondary heating of the water of the heating system is carried out in the condenser 13 TH due to cooling of the return water of the heating system in the evaporator 16 of the heat pump, while the additional heat is given to the consumer by the heating devices 12. The chilled water of the heating system, entering the water heater 11, draws more heat from the network water, significantly lowering the temperature of the return network water. The refrigerated return mains water along line 19 by the network pump 17 is supplied to the condenser 1 of the VT, where it is heated by the heat of condensation of the steam spent in the turbine 4. Steam condensation is carried out in a 3 volt evaporator. The network water heated in the first stage of the network heater (condenser 1 TH) is heated in the second stage of the network heater 6 with selected steam (if necessary, the network water can be additionally heated in the peak boiler 7). Further, the network water is supplied through the heat supply pipe 18 to the water heater 11. Lowering the water temperature in the return line 19 of the heat network reduces heat losses in the heat network, and also at the same flow rate increases the throughput of the heat load of the heat network. In addition, the use of the heat of condensation of the steam spent in the turbine in the lower branch of the cascade increases the efficiency of the station, since the selected steam previously supplied to the network heater is sent to the turbine to generate additional electricity.

Example. The heat supply method is implemented by installing a heat pump with a working fluid R11 in the heating system, for which the temperatures and evaporation pressures and condensations are respectively equal: t _n = 34 ° C, t _k = 85 ° C, P _n = 0.146 MPa, P _k = 0.56MPa (Dobrovolsky A.P. Tables and diagrams of working fluids used in ship refrigeration units. - L .: Sudostroenie, 1966. - 87 s). The degree of pressure increase P _k / P _n = 3.82 allows you to get the efficiency values of the heat pump η = 0.7, and the conversion coefficient of the heat pump φ = 5. The initial parameters of the heat carriers in the heating network and the heating system are as follows: the water temperature in the direct and reverse heating mains is t ₁ = 110 ° C, t ₂ = 65 ° C, respectively; hot water temperature in the heating system t _Г = 95 ° С; return temperature of the heating system t ₀ = 70 ° С. After installing the heat pump: t ₁ = 110 ° С, t ₂ = 46 ° С, t _Г = 95 ° С, t _П = 80 ° С, t ₀ = 41 ° С, where t _П = 80 ° С - secondary temperature water heating system heating. The consumption of network water for heating in this case decreases by 1.42 times.

We implement the heat supply method (install a heat pump at a thermal power plant) on a 250 MW unit with a T-250-240 turbine. In accordance with the basic characteristics of the unit, the proportion of heat spent on generating electricity is 64%, and the heat supply for heating is 36% (Heat Engineering Guide / Edited by V.N. Yurenev and P.D. Lebedev. T.1 - M. : Energy, 1975 .-- P.482). For such units, the average value of the efficiency for the supply of electricity is 45%, and the efficiency for the supply of thermal energy is 90% (Reference energetics of industrial enterprises. T.3. Heat power engineering / Edited by V.N. Yurenev. - M. - L .: Energy, 1965. - P.312). In general, the efficiency of a thermal power plant η _s (Kirillin V.A. Technical Thermodynamics. - M.: Energoatomizdat, 1983. - P.325) is determined by the formula:

where η _with - the efficiency of the station with combined heat and power;

l _e - useful work spent on generating electricity;

l _t - useful work spent on the generation and transfer of heat to the consumer;

q ₁ - the amount of supplied heat released during the combustion of fuel;

x is the proportion of heat supplied to generate electricity;

η _e - the efficiency of the thermal power plant for the supply of electricity;

y - the proportion of heat supplied, aimed at generating thermal energy;

η _t - the efficiency of the thermal power plant for the release of thermal energy.

The conversion coefficient of the heat pump (Yantovsky EI. Steam compression heat pump units. - M .: Energoizdat, 1982. - P.13) φ is determined by the equation:

where φ is the conversion coefficient of the heat pump;

q _TH - thermal performance of the heat pump;

l _TH - operation of the heat pump compressor drive.

, с учетом зависимостей (1) и (2), определится уравнением:Since when implementing the proposed method, part of the additionally generated electricity is expended on the operation of the heat pump compressor drive, then the efficiency of the thermal power plant in this case

, taking into account dependencies (1) and (2), is determined by the equation:

- КПД тепловой электростанции при реализации предлагаемого способа;Where

- The efficiency of the thermal power plant when implementing the proposed method;

m is the fraction of the supplied heat lost in the turbine condenser, but when implementing the proposed method returned to the cycle by the heat pump and aimed at generating additional electricity.

, при этом выработка электроэнергии увеличивается на 2,3%. Условие повышение КПД станции: φ>1/η_э.For the T-250-240 block, x = 0.64, y = 0.36, η _e = 0.45, η _T = 0.9. For the first stage of the network heater, the fraction m = 0.2, and the conversion coefficient of the cascade heat pump in this case can be taken φ = 3. According to the formula (1), the efficiency of a plant with combined heat and power generation will be η _C = 0.612, and the efficiency of a thermal power plant when implementing the proposed method

while electricity generation is increasing by 2.3%. The condition for increasing the efficiency of the station: φ> 1 / η _e .

Claims (1)

A heat supply method, including heating network water in network heaters of heating power plants, supplying hot water through a supply main pipe to heating and hot water supply systems, cooling return network water using heat pump units located at heating stations, returning chilled water through a return main pipeline to network heaters, characterized in that the heat pump installation is performed in cascade with a closing water loop, in the upper branch of the helmet hell, located at the heat point, carry out secondary heating of the heating system water due to additional cooling of the return water of the heating system with a water loop of the network water and the heating system, close the upper and lower stages of the heat pump installation, and in the lower branch of the cascade located at the thermal power station, they carry out the cooling return network water due to the heat of condensation of the steam exhausted in the turbine.