KR101859085B1 - Water Power System by Using Steam Boiler - Google Patents

Abstract

The hydroelectric power generation system using the steam boiler according to the present invention comprises a steam boiler for generating steam, a steam distributor for distributing the steam generated in the steam boiler, and a steam generator for supplying steam, which is supplied from the water recovery storage tank, A steam diaphragm pump for generating a high water pressure and transferring the water to a water storage tank and a high pressure water supply unit for supplying high pressure water from the steam diaphragm pump to the water stored in the water storage tank, A water storage tank, a hydro-electric generator for receiving water of high water pressure from the water storage tank and rotating the turbine to generate electricity, and a controller for receiving and storing the water discharged from the hydro-electric generator, And a water recovery and storage tank for supplying water in a falling-flow manner All.

Description

Water Power System using Steam Boiler "

The present invention relates to the construction of hydroelectric power generation systems using existing steam boilers in homes, buildings or factories. Conventional steam boilers can generate steam by using wood, gas, or light oil. The present invention can generate steam by applying pressure to circulating water using a turbine of a hydroelectric power generator.

The prior art related to the present invention is disclosed in Korean Patent No. 10-1542885 (published on October 22, 2014). FIG. 1 is a view of a solar energy generation system using the conventional biomass boiler as an auxiliary heating source. 1, a solar energy generation system using a conventional biomass boiler as an auxiliary heating source includes an electric generator 1, a turbine 2 connected to the electric generator 1, a condenser 5 connected to the turbine 2, And a turntable unit. Here, the turbine 2 has a high-pressure cylinder 3 and a low-pressure cylinder 4. In addition, the system of this embodiment includes a turbo-

An auxiliary heater 7 disposed inside the flue 6b of the biomass boiler 6, a steam heater disposed within the flue 6b of the biomass boiler 6, (8), and a steam superheater (9) disposed inside the flue (6b) of the biomass boiler (6). On the other hand, the system of this embodiment has a solar concentrator that is in communication with the biomass boiler 6. The solar concentrator has a solar collector tube 13 and a parabolic trough mirror 14 (n solar collector tubes 13 and m parabolic trough mirrors are assembled to form a solar collector field) N and m are integers). Reference numeral 10 denotes a first water pump, reference numeral 11 denotes a second water pump of the biomass boiler 6, reference numeral 12 denotes a desalted water tank provided with a heat insulating layer for storing the soft water discharged from the chemical water treatment apparatus, Reference numerals 19, 20, 21 and 22 denote switching valves (pneumatic valves, electric valves, hydraulic valves or electromagnetic valves, pneumatic valves), respectively, and these switching valves control the operating mode of the entire power generation system . Reference numerals 24, 25 and 26 denote control valves (pneumatic, electric and hydraulic), of which reference numerals 23 and 24 can control the steam flow entering the turbine, And reference numeral 26 can control the flow of water in the main water of the solar concentrating collector. L 1 represents the level gauge of the biomass boiler drum, P 1 represents the vapor pressure gauge at the outlet of the biomass boiler (the detected pressure value is denoted by p 1), T 1 represents the pressure of the biomass boiler (The detected temperature value is indicated by t1), and T3 represents the water temperature sensor at the main water outlet of the solar concentrating collector (the detected temperature value is indicated by t3). A solar power generation system using the biomass boiler (6) as an auxiliary heating source includes a solar concentrating collector, a biomass boiler (6), and a turbo-sensor unit. The solar concentrator and the biomass boiler (6) use water as the working medium for heat absorption and heat storage. The solar concentrator uses a matrix in which the intermediate pressure vacuum solar collector tubes 13 are combined in series and in parallel. The outlet of the solar concentrator is connected to the bottom of the drum 6a of the biomass boiler 6 via the second control valve 22. The steam outlet of the drum 6a of the biomass boiler 6 is connected to the cylinder of the turbine. The solar concentrator and the biomass boiler 6 simultaneously heat the water directly to generate water vapor to drive the turbine 2 to drive the electric generator 1. The water inlet pipe of the solar concentrating collector is connected in series to the deaerator 28 and the first water pump 10. The steam superheater 9 is connected in series between the steam outlet of the biomass boiler drum 6a and the pipe connected to the high pressure sealer 3 of the turbine 2. [ The steam superheater 9 is connected to the inlet of the high-pressure cylinder 3 of the turbine. The steam superheater 9 is located inside the flue 6b of the biomass boiler. The flue gas from a biomass boiler converts water vapor into dry steam by heating the steam. The outlet of the high-pressure cylinder (3) is connected to the reheater (8) via a pipe. The steam reheater (8) is connected to the outlet of the low-pressure cylinder (4) of the turbine (2). A steam reheater (8) is disposed inside the flue (6b) of the biomass boiler (6). The flue gas of the biomass boiler (6) heats the steam. The condenser 5 is connected to the outlet of the low-pressure cylinder 4 of the turbine 2. [ The water outlet of the condenser (5) communicates with the deaerator (28). The water outlet of the condenser 5 communicates with the water inlet of the solar collector tube 13 and / or the biomass boiler 6 via the deaerator 28 and the first water pump 10 to circulate the water . The auxiliary heater 7 is connected in series with the water inlet pipe of the biomass boiler 6 and the auxiliary heater 7 is arranged inside the flue 6b of the biomass boiler 6. [ The flue gas of the biomass boiler preheats the water of the biomass boiler. The water replenishment tank of the solar concentrator and the biomass boiler is a desalination tank 12 having a thermal insulation layer. The demineralized water tank 12 is connected to the deaerator 28 through the second water pump 11 and is connected to the solar collector tube 13 and the biomass boiler 12 via the deaerator 28 and the first water pump 10. [ Lt; / RTI > The desalted water tank 12 is connected to the outlet of the solar concentrating collector through the first control valve 21. The temperature sensor T3 is disposed in the pipe between the water outlet of the solar concentrating collector and the second control valve 22 and the first control valve 21. [ The control point displayed by the temperature sensor T3 is finally outputted to the control loop of the second control valve 22 and the first control valve 21. [ The operating temperature of the temperature sensor T3 can be preset within the temperature range for the safe operation of the biomass boiler.

The conventional solar energy generation system using the conventional biomass boiler as an auxiliary heating source uses a biomass boiler as an auxiliary heat source at a timing when the solar energy generation system such as rain or night can not develop, There is a problem that the supplementary heating source must be enlarged in order to generate electricity even on rainy days and at night. In addition, the conventional technology as described above has a problem that the biomass boiler is used as an auxiliary heating source, but the auxiliary heating source can not be used for hydroelectric power generation. In order to solve the above-mentioned problems, the hydro-power generation system using the steam boiler according to the present invention generally comprises a boiler for forming a water pressure corresponding to a drop of a power generation system using a river, And to develop it.

In order to solve the above problems, the hydro-power generation system using the steam boiler according to the present invention includes a steam boiler for generating steam, a steam distributor for distributing the steam generated in the steam boiler, A steam diaphragm pump unit for generating a high water pressure in the water supplied from the water recovery tank and transferring the water to the water storage tank, A hydrostatic generator for receiving water of high water pressure from the water storage tank and rotating the turbine to generate electricity, and a water supply unit for supplying water discharged from the hydrostatic generator to the water storage tank And stores the stored water in the steam diaphragm pump unit 300 in a natural flow manner. To that consisting of the water recovery storage tank according to claim.

The hydroelectric power generation system using the steam boiler according to the present invention can be easily installed in a home or office. In addition, if the fuel of the steam boiler is made of biofuels such as wood, it is possible to use the wood that is naturally discarded in the houses of the rural areas. In addition, the hydroelectric power generation system using the steam boiler according to the present invention has a small size, a small installation area, a small number of components, low construction cost, and easy operation.

FIG. 1 is a view showing a solar energy generation system using a biomass boiler as an auxiliary heating source,
FIG. 2 is a view showing the construction of the first embodiment of the hydroelectric power generation system using the steam boiler according to the present invention,
3 is a block diagram of a second embodiment of a hydroelectric power generation system using a steam boiler according to the present invention.

The hydro-power generation system using the steam boiler according to the present invention having the above-described objects will be described with reference to the drawings.

FIG. 2 is a block diagram of a first embodiment of a hydroelectric power generation system using a steam boiler according to the present invention. 2, the first embodiment of the hydro-power generation system using the steam boiler according to the present invention includes a steam boiler 100 for generating steam, a steam distributor 200 for distributing the steam generated in the steam boiler 100, A steam diaphragm pump unit 300 in which two units are connected in parallel to each other by forming a high water pressure in the water of fresh pressure supplied from the water recovery storage tank using the steam supplied from the distributor and transferring it to the water storage tank, A water storage tank 600 for receiving high pressure water from the steam diaphragm pump unit 300 to apply pressure to the water stored therein to transfer high pressure water to the hydroelectric power generator, A hydro-electric generator (400) for generating electricity by rotating the turbine by receiving water of a water pressure; and a controller (400) for receiving and storing the water discharged from the hydro- Diamond is composed of the diaphragm, characterized in that the pump unit 300, the water recovery storage tank 500 for supplying the natural flow down manner. In this case, the steam distributor 200 is required when a plurality of steam diaphragm pump units 300 are constructed. In this case, the steam distributor 200 distributes steam to each steam diaphragm pump unit, A second valve 220 for controlling the supply of water to the respective steam diaphragm pump sections from the rear end of the steam distributor and a third valve for discharging water or sludge accumulated in the steam distributor 230, and the second valve 220 may be composed of two or more. In addition, the hydro-electric generator and the plurality of valves can be controlled by the controller 700. The two diaphragm pumps are arranged in parallel so that one diaphragm pump can be operated at the same time in order to cope with a failure of one diaphragm pump. The steam distributor may include a plurality of diaphragm pump units.

3 is a block diagram of a second embodiment of a hydroelectric power generation system using a steam boiler according to the present invention. 3, the hydroelectric power generation system using the steam boiler according to the second embodiment of the present invention includes a steam boiler 100-1 for generating steam, a steam distributor 200-1 for distributing the steam generated in the steam boiler, The steam supplied from the steam distributor is used to form a high water pressure in the water supplied from the water recovery storage tank 500-1 and then sent back to the water recovery storage tank 500-1 through the hydroelectric power generator, A hydrostatic generator 400-1 for generating electricity by receiving water having a high water pressure from the water pressure generator 300-1 and rotating the turbine, And a water recovery and storage tank 500-1 for supplying and storing the water discharged from the hydro-electric generator and supplying the stored water to the water pressure generating unit in a natural flow down manner. In this case, the steam distributor 200-1 distributes the steam to the respective water pressure generating units, and the first and second valves 210-1 and 210-2 are disposed at the upstream side of the steam distributor. A second valve 220-1 for controlling the supply of water from the rear end of the steam distributor to each water pressure generating unit, and a third valve 230-1 for discharging water or sludge from the steam dispenser The second valve 220-1 may include two or more valves. In addition, the water pressure generating unit 300-1 stores water having a predetermined height. The plastic ball 310-1 of the heat insulating material is filled at the top of the water in the tank 300-5, A fourth valve 320-1 formed at the front end of the water pressure generating unit, and a third valve 320-1 formed at the water pressure generating unit for safety of the water pressure generating unit. A safety valve 330-1 for allowing the pressure to be discharged to the outside when an abnormal pressure is generated, a fifth valve 340-1 for controlling the transfer of the high-pressure water generated by the water pressure generator to the hydro- , And a sixth valve (350-1) for regulating the water to be recovered in order to recover the water in the water recovery tank (500-1) to the water pressure generator (300-1) It is characterized by. Also, the hydraulic power generator and the plurality of valves can be controlled by the controller 700-1. In addition, the filling of the plastic ball in the above is to prevent heat exchange between steam and water, thereby preventing the pressure from being reduced due to the conversion of steam into water.

100, 100-1: steam boiler, 200, 200-1: steam distributor,
300: diaphragm pump unit, 300-1: hydraulic pressure generating unit,
400, 400-1: hydroelectric generator, 500: water recovery storage tank

Claims (8)

delete delete In a hydroelectric power generation system using a building or factory steam boiler,
The hydroelectric power generation system using the steam boiler of the building or factory,
A steam boiler (100) for generating steam;
The steam supplied from the steam boiler is used to form a high water pressure in the water supplied from the water recovery storage tank 500 and transferred to the water storage tank 600 so that two diaphragm pumps are arranged in parallel, (300);
A water storage tank 600 for receiving water having a high water pressure from the steam diaphragm pump unit 300 to apply pressure to the water stored therein to transfer water having a high water pressure to the hydroelectric power generator;
A steam distributor (200) configured between the steam boiler and the steam diaphragm pump unit;
A first valve (210) arranged in front of the steam distributor;
A second valve (220) for controlling the supply of water to the respective steam diaphragm pump section at the rear end of the steam distributor;
A third valve (230) for discharging water or sludge accumulated in the steam distributor;
A controller (700) for controlling the first valve, the second valve, and the third valve;
A hydraulic power generator 400 receiving water of high water pressure from the water storage tank and generating power by rotating the turbine;
And a water recovery and storage tank (500) for receiving and storing the water discharged from the hydro-electric generator and supplying the stored water to the steam diaphragm pump unit (300) in a natural flow down manner. Hydroelectric power generation system using boiler.
delete delete delete In a hydroelectric power generation system using a building or factory steam boiler,
The hydroelectric power generation system using the steam boiler of the building or factory,
A steam boiler 100-1 for generating steam;
A high water pressure is formed in the water supplied from the water recovery storage tank 500-1 by using the steam supplied from the steam boiler and is transmitted to the hydroelectric power generator 400-1, 300-5 is a tank 300-5 filled with a plastic ball 310-1 of a heat insulating material at the uppermost part of the water and forming a high water pressure in the water stored by the steam pressure, A valve 320-1 and a safety valve 330-1 for discharging the pressure to the outside when an abnormal pressure is generated in the water pressure generating unit for the safety of the water pressure generating unit, A fifth valve (340-1) for controlling the transfer of the hydraulic power to the hydraulic power generator, and a control unit for controlling the water recovered to recover the water in the water recovery storage tank (500-1) The tank 300 (300) in which the sixth valve -5; < / RTI >
A steam distributor (200-1) for distributing the steam generated in the steam boiler to the water pressure generating section;
A first valve (210-1) configured at the front end of the steam distributor by distributing steam to the tank (300-5) of the water pressure generating portion;
A second valve (220-1) for controlling the supply of water to the water pressure generating unit from the rear end of the steam distributor;
A third valve (230-1) for discharging water or sludge accumulated in the steam distributor;
The first valve 210-1, the second valve 220-1, the third valve 230-1, the fourth valve 320-1, the fifth valve 340-1, and the sixth valve A controller 700-1 for controlling the controller 350-1;
A hydro-electric generator (400-1) receiving water having a high water pressure from the water pressure generator (300-1) and rotating the turbine to generate electricity;
And a water recovery and storage tank (500-1) for receiving and storing the water discharged from the hydro-electric generator and supplying the stored water to the water pressure generating part (300-1) in a natural flow manner. Hydropower system using steam boiler.
8. The method of claim 7,
The hydraulic pressure generating unit 300-1 includes:
And two tanks (300-5) are formed in parallel. The hydroelectric power generation system using the steam boiler of a building or factory.

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