RU2532639C2 - Mini district heating plant to balance load schedule in electric mains - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: mini district heating plant comprises working medium closed circuit consisting of a heat exchanger, a turbine, a capacitor and a circulating pump, at that to the heat exchanger is coupled to a hydraulic heat accumulator equipped with tubular electric heater (TEH), in-line heater and two heat exchangers, one the latter is coupled through an eclectic valve to the mains system while the second is coupled to a source of thermal energy, for example, to outlet of a boiler operated with any kind of fuel or a pipe for discharge of process waste heat. Depending on the time valid for chip night tariff the unit of automatics switches on one TEH for the purpose of heat accumulator charging with heat energy. Its discharge with electric energy production takes place during day time.

EFFECT: invention allows balancing of load schedule in the electric mains.

3 cl, 1 dwg

Description

The alleged invention relates to devices for generating electricity for peak modes of its consumption from low-temperature sources of heat created by electric heating at minimum tariffs for payment for electricity, as well as from other technological sources of waste heat.

Various heat sources are known, for example, from geothermal fluid [1] according to USSR author's certificate No. 1548619 (analogue).

In the device implemented by this method, the fluid is accumulated in the accumulator-collector, heated by solar or wind energy and fed to a steam generator.

The main disadvantage of the devices according to this method is that they are not operable with the simultaneous absence of wind and sun. In addition, they do not affect the alignment of the load schedule of electric networks. The peaks of daily electricity consumption in networks are 1.4 ... 1.8 times more than nightly “failing” needs. Thermal and nuclear power plants do not have the technological ability to reduce the generation of electric energy, therefore, a significant part of it is produced at night “idle”, i.e. not used.

To increase the efficiency of the combined heat and power plant, a heat accumulator is installed between it and the network [2]. If production exceeds consumption, the heat accumulator is charged and gives off heat (discharges) as needed. It is proposed to use such batteries in stand-alone mode with water heating in them from the "failed" night electricity.

Known geothermal power plants (GeoTES) operating with a binary cycle on a low-boiling working agent [3] A.B. Alkhasov. Renewable energy, M, 2010, p. 106, fig. 1.24, c (prototype).

Such stations contain a heat exchanger connected to a geothermal well and an isolated circuit of a low-boiling working fluid (freon 12 or isobutane). The heat exchanger, a rotary engine, for example, a turbine connected to a generator, a condenser, a circulation pump and a receiver, are directly included in the working fluid circuit.

In one of the first such GeoTPS, Paratunskaya, [4] a power of 750 kW was achieved. At present, JSC RusHydro has installed new equipment. The installation of a new binary power unit will increase power up to 2.5 MW due to the use of heat from the waste separator [5].

The main disadvantage of the prototype is that it slightly affects the alignment of the network load schedule, and also does not use “night” failure energy to turn it into “day” energy to smooth out consumption peaks.

The task of the invention is to remedy these disadvantages.

The technical advantages of the claimed object in comparison with the known device are the following distinguishing features.

A newly introduced hydraulic thermal battery with a heating element is connected to the closed-circuit heat exchanger of the low-boiling working fluid, which is turned on by the timer of the automation unit during the operation of the cheap night tariff, which allows accumulating low-cost thermal energy in the battery. In addition, a powerful flow heater or several flow heaters, for example, EVAN EPVN with an electric power of up to 120 kW [7] and more, is included in the hydraulic thermal accumulator. The input and output of the flow heater are connected at different levels of the battery, respectively - at its bottom and in the upper part of the structure, which allows you to evenly mix and heat water with low thermal conductivity in the battery in the short time of the cheap night tariff. In addition, the first water heat exchanger is introduced into the hydraulic heat accumulator, which is connected via an electric valve to the main heat supply networks, which allows the use of excess heat energy in the networks and turns it into electrical energy at the right time, and a second additional heat exchanger connected to the heat energy source, for example, to the exhaust chimney of a boiler using any type of fuel, which will allow for cogeneration, i.e. generation of additional electrical energy at the same time due to waste heat energy.

The next distinguishing feature is the solution to the problem of reducing leakage through leaks in the constructions of an expensive working fluid (freon or isobutane) by enclosing a rotary engine with a generator in a sealed housing, the suction from the inner cavity of which leaked working fluid is carried out by a newly introduced ejector with the return of the working fluid in a closed loop. This is due to the fact that one input of the ejector is connected to the internal cavity of the housing, the other input is to the atmosphere, and its output is connected to the output of the rotary engine on the outside of the sealed housing.

The next distinguishing feature is the use of a rotary vane machine as a rotary engine, which has higher efficiency and high accuracy due to very small losses, not participating in the selection of energy from the fluid flow. This is due to the fact that the rollers are synchronized by gears with movement in a circle of the blades and practically exclude free passage of liquid in the opposite direction.

As a result of a search by sources of patent and scientific and technical information, a set of features characterizing the described “Mini-electric center for load balancing in electric networks” was not found, thus, the proposed technical solution meets the “new” criterion.

Based on a comparative analysis of the proposed solution with the prior art according to the sources of patent and scientific and technical information, it can be argued that between the set of distinctive features, their functions and the task achieved, the proposed technical solution does not follow explicitly from the prior art, therefore, meets the eligibility criterion "Inventive step".

The proposed technical solution can find application in the energy sector for balancing the load schedule of electric networks, as well as for autonomous consumers with excess or waste heat energy to generate electricity from it.

The proposed "Mini-electric center for balancing the load curve in electrical networks" is shown in the drawing.

This device in a closed circuit of a low-boiling working fluid sequentially contains a heat exchanger 1 of the working fluid, a rotational engine 2, a generator 3, a condenser 4, a circulation pump 5 and a receiver 6.

The rotary engine and generator are enclosed in a sealed housing 7, in which the input and output of the rotary engine 2 are sealed, the outlet from the inner cavity of the housing 7 is connected to the ejector input, its other input is connected to the atmosphere (not shown in the drawing), and the ejector output to the output of the rotary engine on the outside of the housing. A hydraulic thermal accumulator 9 is connected to the heat exchanger 1 of the working fluid with a heating element 10 connected to a timer of the automation unit 11 (not shown in the drawing), which determines the time for switching on and off the heating element.

To quickly heat up water in a short time of the action of a cheap night electric tariff between the lower and upper water levels in the accumulator, an additional flow-through heat heater 12 is also used, which is also connected to the timer of the automation unit 11. The first water heat exchanger 13 of the heat accumulator is connected through the electric valve 14 to the main heat networks 15, and the second additional heat exchanger 16 - to any hot source of waste process heat, for example, to the outlet pipe of the boiler (not shown in the drawing).

The mini-electric center for balancing the load curve in electric networks works as follows. The timer of the automation unit 11 (program hours) at a predetermined time when the cheapest rate of payment for electricity is in effect, connects the heater 10 to the network to heat water in the heat accumulator 9.

Hot water enters the heat exchanger 1 of the closed circuit of a low-boiling working fluid by analogy with the Paratunskaya Geothermal Power Plant at a temperature of about 80 ° C. In the heat exchanger 1, the working fluid (freon or isobutane) is evaporated and the resulting vapor at a pressure of 1.4 MPa is supplied to a rotary engine 2, which rotates the generator 3, which generates electrical energy. From the output of the rotary engine, the working fluid enters the condenser 4, then to the circulation pump 5, the receiver 6 and returns to the heat exchanger for heating.

In multi-tariff payment systems for electricity, the time of the cheapest tariff is limited, therefore, for quick heating and mixing of water in the battery, the timer of the automation unit 11 includes a flow-through heat heater 12.

The receiver 6 is necessary due to the high fluidity of the working fluid, as well as due to the fact that in all circuit elements the pressure is higher than atmospheric, and when repairing any unit, it is collected in the receiver to avoid losses of the working fluid. To reduce losses of the working fluid during leakage by the ejector 8, the leaked part of the working fluid is sucked out through the leaks of the rotating units of the rotary engine 2 and generator 3 from the internal cavity of the sealed housing 7 and returned to the circuit. The operation of the ejector is provided by a higher pressure of the working fluid coming from the output of the rotary engine 2 to the capacitor 4.

The working fluid (freon, isobutane) has a high density, therefore, it is advisable to use roller-blade machines [6, 8, 11, 12] as a rotary engine, which practically exclude the span of the flow and, therefore, have a higher efficiency.

The district heating networks are very inertial and, as a rule, have excess heat capacity calculated for the coldest time of the year. Thermal power plants also do not provide the ability to quickly influence the heat capacity of networks, for example, in the case of warming outside air.

In this regard, it is proposed that the unused thermal energy of the heating networks 15 be directed through the electrovalve 14 controlled from the automation unit to the first water heat exchanger 13 of the thermal accumulator 9. The thermal parameters of the networks 15 are close to the thermal parameters of the low-boiling working fluid circuit by analogy with the Paratunskaya GeoES. In this case, from unused thermal energy is given the opportunity to receive electrical energy.

An additional second battery heat exchanger 16 can be connected to any other source of thermal energy of high potential: to the outlet pipe of a boiler operating on any type of fuel, to the waste pipe of industrial heat, etc.

The automation unit 11 according to the readings of temperature sensors inside the battery (not shown in the drawing) regulates the temperature in a predetermined range, controls the operation of the circulation pump 5, and, if necessary, switches on a flow-through heat heater 12 or an electric valve 14.

The proposed device, which uses cheap night-time electricity or thermal waste energy from any source to heat the coolant, can be widely used as a mini-power station for balancing the load curve in electric networks.

In the works “Method of heat supply” and “System of heat supply” [9, 10], the authors showed the expediency of having, in addition to basic heat sources, peak autonomous sources for each of the subscribers. Thus, by connecting these autonomous sources of thermal energy to heat exchangers 13 or 16, subscribers have the opportunity to have their own electricity in the right time period.

The technical result of the claimed invention according to the authors is "industrial applicability", because the components making up the device and the device as a whole can be implemented in the electric power industry for balancing the load schedule of networks, in housing and communal services, and also used by remote consumers in stand-alone mode.

INFORMATION SOURCES

1. Riger P.N., Brain A.G. The way the heat and power supply system works. Description to USSR copyright certificate No. 1548619, IPC class. F24J 3/00 (analog).

2. Mogens Kier Petersen, Jorgen Ogard. Thermal batteries. [Electronic resource]. Access mode: http://www.rosteplo.ru/tech_stat_shablon.php?id=844

3. Alkhasov A.B. Renewable Energy, M., 2010, p. 106, fig. 1.24, c. Scheme of a GeoES with a binary cycle on a low boiling working agent.

4. Ogurechnikov L.A., Petin Yu.M. The experience of creating and operating the Paratunka geothermal power station / Proceedings of the International Geothermal Seminar MGS-2003, Sochi, 2003, p. 56.

5. “A unique operation to install the main equipment of the binary unit has been completed at the Pauzhetskaya geothermal station.” JSC RusHydro, 2011. [Electronic resource]. Access Mode: http://www.invel.ru/invel/industrial_events/2011/07monitor_0807...

6. Domogatsky V.V., Levchenko I.V. Roller-blade machine. RF patent 2230194, cl. F01C 1/14.

7. Catalog of equipment of the TEPLOAS company. [Electronic resource]. Access Mode: http://energohit.ru/text/podbor/waterheater/

8. Flow meters, liquid and gas meters. Modification "Nord" LLC "West Metrology" [Electronic resource]. Access mode: www.west-metrology.ru.

9. Sharapov V.I. et al. Method of heat supply. Description of the invention to the patent of the Russian Federation No. 2235249, IPC class. F24D 3/08, 2004.

10. Sharapov V.I. et al. Method of heat supply. Description of the invention to the patent of the Russian Federation No. 2235250, IPC class. F24D 3/08, 2004.

11. Smirnov M.I., Domogatsky V.V., Trofimov V.S. Roller-blade hydraulic machine. USSR copyright certificate 992821, Cl. F04C 2/14.

12. Domogatsky V.V., Levchenko I.V. Roller vane machine. RF patent 2109141, cl. F01C 1/4, F04C 2/14.

Claims (3)

1. A mini-electric center for balancing the load curve in electric networks, containing a closed loop of a low-boiling working fluid, including a heat exchanger, a rotary engine, a generator, a condenser, a circulation pump, a receiver, characterized in that it is additionally introduced and a hydraulic heat accumulator with a heating element is connected to the heat exchanger, connected to the newly entered timer in the automation unit, a flow heater is connected between the lower and upper water levels in the heat accumulator, also interlocked with a timer, and the first heat exchanger is inserted into the heat accumulator, connected through an electric valve to the main heat supply networks, and the second additional heat exchanger connected to a heat source, for example, to the boiler outlet pipe for any type of fuel or to the waste process heat pipe. 2. The mini-electric center for balancing the load schedule in electric networks according to claim 1, characterized in that the rotary engine and generator are enclosed in a sealed enclosure, the internal cavity of which is connected to the input of the newly introduced ejector, the other input of which is connected to the atmosphere, and its output is connected to the output of the rotary engine on the outside of the sealed enclosure. 3. The mini-electric center for balancing the load schedule in electric networks according to claim 1, characterized in that a roller-blade machine is used as a rotary engine.

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