JPH03264711A - Midnight regenerative power generator - Google Patents

Abstract

PURPOSE:To enhance power generating efficiency by generating steam with heat energy stored by use of midnight electric power so as to drive a steam engine and a generator by utilization of the steam, and recovering heat energy at the time of water condensing for the purpose of utilizing it as a heat source of steam. CONSTITUTION:Heat is stored in a heat storage tank 1 by use of midnight electric power. In the daytime, the heat in the heat storage tank 1 is taken out. Water stored in a container 10 is heated by a heater 6 so that steam is generated from a steam generator 9. The heat in the heat storage tank 1 is transmitted to a superheater 5 through a heat pipe 2, and the steam from the steam generator 9 is superheated so that the superheated steam is supplied into the water 11 stored in the container 10. Furthermore, the superheated steam is supplied to a steam turbine 14, to thus drive a generator 17 connected to a drive shaft 16. Meanwhile, steam exhausted from the steam turbine 14 is condensed into water by a condenser 15, and then, is supplied to a heat exchanger 19. Condensed latent heat in the condenser 15 is pumped up by a heat pump 24 and supplied to another heater 34, where water supplied to the heat exchanger 19 is heated.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a late-night thermal storage power generation device that stores heat using late-night electric power and uses this as a heat source to drive a steam engine to generate electricity.

(Conventional technology) General electricity consumers such as factories and buildings store heat using late-night electricity, where electricity rates are low, and perform cooling or heating during the day. A power generation device that generates electricity has not yet been developed.

[Problems to be Solved by the Invention] If it is possible to generate electricity using heat stored in late-night electricity as a heat source, it will be possible for general electricity consumers to generate electricity during peak hours during the day to level the load.

In addition, in factories, etc., if the heat generated by the combustion of industrial waste or the intermittent heat generated can be stored and used as a heat source to generate electricity, the generated heat can be used effectively.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a late-night thermal storage power generation device that is a combination of a heat storage device and a power generation device using a steam engine as a drive source.

[Means to solve the problem]

The late-night thermal storage power generation device of the first invention includes a heat storage tank that stores heat using late-night electricity, etc., and a steam generator that generates steam by applying heat extracted from the heat storage tank to a liquid filled in a container. , a superheater that applies the heat extracted from the heat storage tank to the steam generated by the steam generator to produce a superheated lath; and supplying the superheated steam generated by the superheater to the steam generator as a heat source. a steam engine driven by superheated steam generated in the superheater; a generator that generates electricity using the steam engine as a driving source; A water device, a heat pump that pumps up the heat in the cooling water discharged from the condenser, a heater that supplies the heat pumped up by the heat pump, and a heat exchanger between the heat storage tank and the heat storage tank. The steam generator includes an exchanger and means for heating the liquid condensed in the condenser through the heat exchanger and the heater and supplying the heated liquid to the steam generator.

The late-night thermal storage power generation device of the second invention includes a heat storage tank that stores heat using late-night electricity, etc., and a steam generator that generates steam by applying the heat extracted from the heat storage tank to a liquid filled in a container. a steam compressor for compressing the steam generated by the steam generator; a means for supplying the steam compressed by the steam compressor to the steam generator; and steam driven by the steam compressed by the steam compressor. An engine, a generator that uses the steam engine as a driving source to generate electricity, a condenser that cools the steam discharged from the steam engine and turns it into a liquid, and a condenser that converts heat in the cooling water discharged from the condenser. A heat pump that pumps up, a heater that supplies the heat pumped up by the heat pump, a heat exchanger that exchanges heat with the heat storage tank, and a liquid that is condensed in the condenser. It has a heat exchanger and means for heating through the heater and supplying it to the steam generator.

In the late-night thermal storage power generation devices of the first and second inventions, a vacuum pump may be provided to reduce the pressure within the steam generator.

[Effect]

The late-night thermal storage power generation device of the present invention stores heat in a heat storage tank using late-night electricity, and uses this heat to generate steam to drive a steam engine and operate a generator.

The condenser of a steam engine releases latent heat of condensation to the cooling water, and if the heat released in the condenser is not recovered, 50%
This results in a loss of heat amount, resulting in extremely poor thermal efficiency. Therefore, in the present invention, heat is recovered from the cooling water discharged from the condenser, pumped up using a heat pump, and the pumped up heat is further utilized as a heat source for the steam generator. Therefore, it is possible to realize a late-night thermal storage power generation device with good thermal efficiency.

When water is used as the liquid to be filled in a steam generator, the water boils at 100°C under 1 atm and generates steam, but if the amount of heat is insufficient and it does not boil, the pressure inside the steam generator will increase. If you lower the temperature, you can boil at a lower temperature.

Further, the liquid to be filled in the steam generator is not limited to water, and may be other liquids. For example, when using Freon, it can be boiled at a low temperature.

〔Example〕

FIG. 1 is a diagram showing a first embodiment of the present invention.

Note that this embodiment shows an example in which a steam turbine is used as the steam engine.

The heat storage tank 1 has a structure in which it can store heat from late-night electricity, and can also store heat generated intermittently from the combustion of industrial waste. The heat storage tank is not a feature of the present invention, and a conventionally known one can be used.

Heat is transferred from the heat storage tank 1 to a superheater 5 via a heat pipe 2, to a heater 6 provided in a steam generator 9 via a heat pipe 3, and to a heat exchanger 19 via a heat pipe 4. There is. Note that when using a conduit for circulating the heat transfer medium without using a heat pipe, it is necessary to provide a pump in the conduit.

The steam generator 9 is configured to heat water 11 filled inside a container 10 and generate steam.

Inside the container 10, the heater 6 is provided as described above to heat the water 11, and furthermore, the space between the steam outlet at the top of the container 10 and the steam inlet at the bottom of the container 10 is provided. are connected by a conduit 13 that passes through a superheater 5 and has a valve 8, and water 11 is heated with steam superheated by the superheater 5.

Steam sent out from the heater 5 is sent to a steam turbine 14 through a branched pipe line 13.

The steam turbine 14 has a condenser 15 connected to its exhaust side, and cools the steam discharged from the steam turbine 14 to create a vacuum state, so that the superheated steam supplied to the steam turbine 14 is continuously and sufficiently maintained. A generator 17 is connected to the drive shaft 16 of the steam turbine 14, and the generator 17 generates electricity by driving the steam turbine 14. It has become. The steam discharged from the steam turbine 14 and sent into the condenser 15 comes into contact with the cooling channel 18 provided in the condenser 15 and condenses, becoming water and collecting in the condenser 15. It has become.

A pump 2 is installed between the condenser 15 and the heat exchanger 19.
A conduit 21 with 0 is provided, and water in the condenser 15 can be sent to the heat exchanger 19 by driving the pump 20. The line 21 extends from the heat exchanger 11 further to the vessel 10 of the steam generator 9.

Further, the cooling water channel 18 provided in the condenser 15 is connected to a cold water tank 22 that functions as a heat exchanger, and a pump 23 is provided in the middle. Cooling water is produced by a heat pump 24.

The heat pump 24 includes a compressor 25, a motor 26 that drives the compressor, an evaporator 27, and a condenser 28.
It is composed of. Evaporator 27 of heat pump 24
and the cold water tank 22 are connected by a conduit 30 with a pump 29 provided in the middle. Also, heat pump 2
The condenser 28 of No. 4 and the hot water tank 31 are connected through a conduit 33 having a pump 32 provided therebetween. Furthermore,
The hot water tank 31 and a heater 34 provided in the pipe line 21 are connected by a pipe line 36 having a pump 35 provided therebetween. Water supplied to the container 10 of the steam generator 9 through the pipe line 21 is heated by a heat exchanger 19 and a heater 34.

The method of operating the late-night thermal storage power generation device configured as described above is as follows.

The heat storage tank 1 stores heat using late-night electricity, and stores heat generated intermittently by combustion of industrial waste.

Heat from the heat storage tank 1 is taken out during the day, and a steam generator 9 generates steam using this heat. Although not shown in the figure, the container 10 of the steam generator 9 is provided with a valve for taking in and out the water 11 inside.
1 is reduced by the above-mentioned valve, the water in the container 10 of the steam generator 9 is heated by the heater 6, and the water is heated to 100°.
Bring to a boil at C. The generated steam is sent to superheater 5.

On the other hand, heat from the heat storage tank 1 is transmitted to the superheater 5 via the heat pipe 2, and superheats the steam from the steam generator 9. The superheated steam is sent to line 13.

When the valve 8 provided in the pipe line 13 is gradually opened, the heated steam is introduced into the water 11 of the steam generator 9. Next, the amount of water 11 in the steam generator 9 is increased.

Further, superheated steam from the superheater 5 is sent to a steam turbine 14 through a pipe 13. The superheated steam supplied to the steam turbine 144 is continuously expanded to drive the turbine. The generator ii 17 connected to the drive shaft 16 of the turbine is
Start power generation. The steam discharged from the steam turbine 14 is cooled in the condenser 15 and condensed into water, which accumulates in the condenser 15. The water in the condenser 15 is sent to the heat exchanger 19 through a pipe 21 by a pump 20.

When the steam condenses in the condenser 15, latent heat of condensation is released to the cooling water. Heat released into cooling water, cold water tank 2
2 to the heat pump 24, and the heat pump 2
Bonbua knob by 4. For example, when the outside temperature is 0 to 10"C, four pumps can be pumped to 70 to 80C. The pumped heat is supplied to the heater 34 through the hot water tank 31.

Water sent from the condenser 15 to the container 10 of the steam generator 9 by the pump 20 is given heat as it passes through the heat exchanger 9, increasing its temperature, and is further heated by the heater 34, increasing its temperature.

The electric power obtained when operating the above-mentioned late-night thermal storage power generation device is the amount of power generated by the generator 17 connected to the steam turbine 14, but in the above-mentioned embodiment, the motor 26 is used to drive the heat pump 24. together with pump 20.2
3.29.32.35 Electricity is also used when operating the thermal storage power generation device late at night, so the electric power obtained when operating the late-night thermal storage power generation device is the amount of power generated by subtracting the power used by the motor 26 and these pumps from the above-mentioned power generation amount. becomes. The heat pump has a coefficient of performance of 2 to 3 (generates 2 to 3 times as much heat as the power used by the motor 26), and the motor 26 and pump 20.2
3.29.32°35 can be driven with a small amount of power used compared to the total power generation amount.

The late night thermal storage power generation device described above uses thermal energy extracted from the thermal storage fail and thermal energy discharged from the condenser to generate superheated steam, and this superheated steam is used to power the steam turbine.
Since the generator 17 connected to the steam turbine is configured to generate electricity, low-cost electric power can be obtained.

FIG. 2 is a diagram showing a second embodiment of the present invention. In the first embodiment described above, the heat of the heat storage tank 1 is supplied to the superheater 5, but this superheater 5 is replaced with a steam compressor 43.

In FIG. 2, the same components as in FIG. 1 are designated by the same reference numerals.

In this late-night thermal storage power generation device, water 11 in a steam generator 9 is heated and boiled by a heater 6 to generate steam. The steam at this time was approximately 100°C and 11 atmospheres. Next, the motor 44 connected to the steam compressor 43 is driven, and cooling water is passed through the cooling water channel 18 of the condenser 15. Steam generated in the steam generator 9 is sent to the steam generator 9 and the steam compressor 43 through the pipe 13. The steam entering the steam compressor 43 is compressed, and its temperature and pressure are increased due to the exothermic effect of adiabatic compression. Steam compressed by the steam compressor 43 is sent to the steam turbine 14 through the pipe 13.

The high pressure steam supplied to the steam turbine 14 is continuously expanded and drives the turbine.

Since the late-night thermal storage power generation device of the second embodiment drives the steam turbine 14 with high-temperature, high-pressure steam, it is possible to drive a turbine with a larger capacity than that of the first embodiment.

In the above first and second embodiments, when the thermal energy extracted from the heat storage tank 1 and the thermal energy discharged from the condenser 15 are insufficient to boil the water in the steam generator 9, , in the steam exhaust line 13 of the steam generator 9,
If a vacuum pump is provided to lower the pressure inside the container 10 of the steam generator 9, boiling can be achieved at a low temperature.

For example, the pressure is 0.5kg/cm2.0.4kg/cm"
, 0.3kg/cm”, water is 80.8 respectively.
Boils at 6°C, 75, 41"C, 68, 67"C and generates steam.

3 shows a third embodiment in which a vacuum pump 45 is provided in the conduit 13 in the first embodiment shown in FIG. 1, and FIG. 4 shows a vacuum pump 45 in the conduit 13 in the embodiment shown in FIG. A fourth embodiment is shown below.

According to these embodiments, even when the thermal energy taken out from the heat storage tank 1 and the thermal energy recovered from the exhaust heat energy of the condenser 15 are smaller than those in the first and second embodiments, late-night heat storage It becomes possible to move the power generation device.

In each of the above-mentioned embodiments, a steam turbine 14 is provided as a steam engine driven by steam, but the steam engine is driven by expanding steam and generates electricity l! 17 may be configured to include another steam engine as long as it is capable of generating electricity.

Furthermore, although the motor 44 is provided as an electric power source for the steam compressor 43 that compresses steam, the structure may be provided with any other driving source as long as it can drive the steam compressor.

〔Effect of the invention〕

The late-night thermal storage power generation device according to the present invention stores heat in a heat storage tank using late-night electricity, generates steam using the thermal energy taken out from the heat storage tank, drives a steam engine with this steam, and generates electricity by connecting to the steam engine. The machine is configured to generate electricity, recover the thermal energy in the cooling water discharged by the condenser, pump it up with a heat pump, and add it as a heat source when producing the steam, increasing power generation efficiency. power can be improved and lower cost power can be obtained.

[Brief explanation of drawings]

Fig. 1 is a block diagram showing a first embodiment of the present invention, Fig. 2 is a block diagram showing a second embodiment, Fig. 3 is a block diagram showing a third embodiment, and Fig. 4 is a block diagram showing a third embodiment. FIG. 4 is a configuration diagram showing a fourth embodiment. 1... Heat storage tank 2.3.4... Heat pipe 5... Superheater 9... Steam generator 14... Steam turbine 19... Heat Exchanger 24... Heat pump 34... Heater 43... Steam compressor 45, 46... Vacuum pump

Claims (3)

[Claims] (1) A heat storage tank that stores heat using late-night electricity, etc.; a steam generator that generates steam by applying heat extracted from the heat storage tank to a liquid filled in a container; , a superheater that supplies the steam generated by the steam generator to superheated steam; means for supplying the superheated steam generated by the superheater to the steam generator as a heat source; A steam engine driven by superheated steam; a generator that uses the steam engine as a drive source to generate electricity; a condenser that cools the steam discharged from the steam engine to liquid; and a condenser that cools the steam discharged from the steam engine to liquid. a heat pump that pumps up the heat in the cooling water; a heater that supplies the heat pumped up by the heat pump; a heat exchanger that exchanges heat with the heat storage tank; A late-night thermal storage power generation device comprising: means for heating the water-containing liquid through the heat exchanger and the heater, and supplying the heated liquid to the steam generator. (2) A heat storage tank that stores heat using late-night electricity, etc.; and a steam generator that generates steam by giving the heat extracted from the heat storage tank to a liquid filled in a container; and the steam generator generates steam. a steam compressor for compressing the steam compressed by the steam compressor; a means for supplying the steam compressed by the steam compressor to the steam generator; a steam engine driven by the steam compressed by the steam compressor; and a steam engine for driving the steam engine. a generator that generates electricity as a source; a condenser that cools the steam discharged from the steam engine and turns it into liquid; a heat pump that pumps up the heat in the cooling water discharged from the condenser; a heater for supplying heat pumped up by the heat exchanger; a heat exchanger for exchanging heat between the heat storage tank; and a heat exchanger for exchanging heat between the heat storage tank and the liquid condensed in the condenser through the heat exchanger and the heater. and a means for heating and supplying the heat to the steam generator. (3) The late-night thermal storage power generation device according to claim 1 or 2, further comprising a vacuum pump for reducing the pressure within the steam generator.