JP2018200029A - Power generation system - Google Patents

Abstract

To improve heat efficiency in a case of combusting ammonia as fuel of a boiler.SOLUTION: A power generation system for driving a steam turbine with steam generated in a boiler, comprises an ammonia evaporation facility configured to evaporate liquid ammonia with heat of exhaust steam discharged from the stream turbine, and is configured to supply gaseous ammonia to the boiler to combust it as fuel, wherein the gaseous ammonia is acquired in the ammonia evaporation facility.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power generation system.

  There is a thermal power plant as a power generation system equipped with a boiler. As is well known, this thermal power plant generates power by driving a steam turbine using steam (steam) generated by a boiler as a driving fluid. For example, Patent Document 1 below discloses an exhaust heat recovery system for steam turbine equipment that obtains warm water for heating by using exhaust heat of a condenser of a steam turbine in such a thermal power plant.

  On the other hand, Patent Document 2 below discloses a composite energy system that burns fuel containing ammonia. This composite energy system reduces the amount of carbon dioxide emissions by burning a fuel obtained by adding ammonia to natural gas in a gas turbine.

JP 05-296209 A JP 2006-032391 A

  By the way, it is conceivable to burn ammonia as fuel in a boiler of a thermal power plant (power generation system) shown in Patent Document 1 as shown in Patent Document 2. In such a power generation system that burns ammonia as fuel, the overall thermal efficiency should be improved as much as possible, but no effective technology has been developed at present.

  This invention is made | formed in view of the situation mentioned above, and aims at the improvement of the thermal efficiency in the case of making ammonia burn as fuel of a boiler.

  In order to achieve the above object, according to the present invention, as a first solving means related to a power generation system, a power generation system that drives a steam turbine using steam generated in a boiler, which is discharged from the steam turbine. An ammonia vaporization facility that vaporizes liquid ammonia using the heat of exhaust steam is provided, and gaseous ammonia obtained by the ammonia vaporization facility is supplied to the boiler and burned as fuel.

  In the present invention, as a second solving means relating to the power generation system, in the first solving means, the ammonia vaporization facility includes a condenser for condensing the exhaust steam using a predetermined cooling water, and the condensate. A means is provided that includes a vaporizer that generates heat by exchanging heat between the cooling water heated by a vessel and the liquid ammonia.

  In the present invention, as a third solving means relating to the power generation system, a means is adopted in which a plurality of the vaporizers are provided in parallel in the second solving means.

  In the present invention, as a fourth solving means relating to the power generation system, a means is adopted in which the cooling water is water or seawater in the second or third solving means.

  According to the present invention, liquid ammonia is vaporized using the heat of the exhaust steam discharged from the steam turbine, so there is no need to prepare heat for vaporizing liquid ammonia, and therefore ammonia is burned as boiler fuel. The thermal efficiency can be improved.

It is a system configuration figure showing the functional composition of the power generation system concerning one embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, the power generation system according to this embodiment includes a boiler 1, a steam turbine 2, a generator 3, a condenser 4, a supply pump 5, an ammonia supply device 6, a vaporizer 7, and a main fuel supply device 8. It has. Of these components, the condenser 4 and the vaporizer 7 constitute the ammonia vaporization facility K in the present embodiment.

  The boiler 1 is a steam generator that generates high-temperature exhaust gas by burning fuel injected from a burner into a furnace, and generates steam (water vapor) by heating water with the exhaust gas. The fuel is, for example, main fuel such as pulverized coal, natural gas or heavy oil, and gaseous ammonia (sub fuel). This boiler 1 generates a predetermined amount of water vapor by burning such main fuel and sub fuel simultaneously or alternatively.

  The steam turbine 2 is a power generation device that generates rotational power by using the above-mentioned supplied from the boiler 1 as a driving fluid. That is, the steam turbine 2 is an energy conversion device that converts thermal energy of high-temperature exhaust gas into rotational power, and generates rotational power with a predetermined output. Such a steam turbine 2 is axially coupled to the generator 3 and functions as a power source for operating the generator 3.

  The generator 3 is rotating electricity that is driven by the steam turbine 2 to generate electric power with a predetermined output. That is, the generator 3 is a load of the steam turbine 2, generates electric power with an output corresponding to the rotation state of the steam turbine 2, and transmits the generated electric power to an external power consumer.

  The condenser 4 is a condenser that condenses the exhaust steam discharged from the steam turbine 2 by cooling it with predetermined cooling water. The exhaust steam is steam after being supplied from the boiler 1 to the steam turbine 2 and power recovered by the steam turbine 2. The cooling water is, for example, water taken from a river or sea water taken from the sea, heated by heat exchange with exhaust steam, and then supplied to the vaporizer 7 as heated cooling water.

  The supply pump 5 is a fluid machine that supplies steam condensed water discharged from the condenser 4 to the boiler 1. That is, in addition to the supply pump 5, the boiler 1, the steam turbine 2, and the condenser 4 form a kind of Rankine cycle, and recover power while changing the phase of water as a heating medium. The supply pump 5 functions as a power source for circulating the heat medium in such a Rankine cycle.

  The ammonia supply device 6 is a device that supplies liquid ammonia to the vaporizer 7. The ammonia supply device 6 includes an ammonia tank that stores a predetermined amount of liquid ammonia, and an ammonia supply pump that pumps liquid ammonia from the ammonia tank and supplies it to the vaporizer 7. The ammonia supply pump can be omitted when the internal pressure of the ammonia tank is high to some extent.

  The vaporizer 7 is a device that vaporizes the liquid ammonia supplied from the ammonia supply device 6 using the heating / cooling water supplied from the condenser 4. This vaporizer 7 is a kind of heat exchanger, and vaporizes liquid ammonia by exchanging heat with heating and cooling water. A plurality of such vaporizers 7 are provided in parallel, and those selected as necessary are used for vaporizing liquid ammonia.

Moreover, the vaporizer 7 discharges the cooling water cooled by heat exchange with liquid ammonia to the sea or river as drainage. This drainage is provided with a temperature limit in consideration of the natural environment, and an allowable temperature rise ΔT with respect to the temperature of the cooling water (initial temperature T ₀ ) when taken into the condenser 4 from the sea or the like. It is set in advance. That is, in the power generation system according to the present embodiment, the temperature of the waste water in the vaporizer 7 is set to T ₀ + ΔT or less by adjusting the amount of cooling water taken into the condenser 4.

  The condenser 4 and the vaporizer 7 constitute the ammonia vaporization facility K as described above. The ammonia vaporization facility K is a facility for vaporizing liquid ammonia using heat of exhaust steam discharged from the steam turbine 2 in the power generation system according to the present embodiment. This power generation system generates steam by burning gaseous ammonia generated in the ammonia vaporization facility K as fuel in the boiler 1, and generates power by driving the steam turbine 2 using the steam.

  The main fuel supply device 8 is a device that supplies the above-described main fuel to the boiler 1. The main fuel supply device 8 includes a main fuel tank that stores a predetermined amount of main fuel and a main fuel supply pump that pumps and supplies main fuel from the main fuel tank when the main fuel is, for example, heavy oil.

  Next, the time series operation of such a power generation system will be described in detail. In addition, this power generation system supplies electric power continuously to consumers by being operated continuously regardless of day and night, and the operation in steady operation after the start of operation will be described below.

  In this power generation system, main fuel is always supplied from the main fuel supply device 8 to the boiler 1 and gaseous ammonia (sub fuel) is always supplied from the vaporizer 7 to the boiler 1. The boiler generates a high-temperature combustion gas by burning such main fuel and sub fuel in a furnace, and generates a predetermined amount of steam by exchanging heat with the combustion gas. The boiler 1 supplies the steam thus generated to the steam turbine 2.

  In the steam turbine 2, rotational power is generated by taking in the steam supplied from the boiler 1 as a driving fluid, thereby driving the generator 3 as a load. As a result, the generator 3 outputs electric power with an output corresponding to the driving state of the steam turbine 2 to the consumer.

  On the other hand, in the steam turbine 2, steam after being used for power recovery, that is, exhaust steam, is discharged to the condenser 4. The exhaust steam is condensed by heat exchange with the cooling water in the condenser 4 to be condensed water. Then, this condensed water is returned to the boiler 1 by the supply pump 5 and reheated to become steam.

  In this power generation system, power is generated in the steam turbine 2 in a process in which water circulates while undergoing phase transition between liquid (water) and gas (steam), and the generator 3 is driven by this power. Electricity is generated by this, but in the boiler 1 which is a device for phase transition of water to steam, gaseous ammonia is used as a secondary fuel. The gaseous ammonia is generated by the vaporizer 7 using the heat of the cooling water discharged from the condenser 4, that is, the exhaust heat of the exhaust steam discharged from the steam turbine 2.

  That is, in this power generation system, the liquid ammonia is converted into gaseous ammonia by reusing the heat of the exhaust steam discarded through the condenser 4, and this gaseous ammonia is used as a secondary fuel. Therefore, according to this embodiment, since it is not necessary to provide a separate heat source for generating gaseous ammonia (sub fuel), the thermal efficiency of the entire system in the case of burning gaseous ammonia as the sub fuel of the boiler 1 is improved. be able to.

In addition, this invention is not limited to the said embodiment, For example, the following modifications can be considered.
(1) In the above embodiment, the exhaust water of the steam turbine 2 is heat-exchanged with the cooling water by the condenser 4 to heat the cooling water, and the heated cooling water (heating cooling water) and liquid ammonia are heated. The gaseous ammonia was generated by exchanging heat with the vaporizer 7, but since the boiling point of ammonia is relatively low at minus 33 ° C., the liquid ammonia can be sufficiently vaporized by the heating / cooling water.

  However, the present invention is not limited to this. For example, gaseous ammonia may be generated by directly exchanging exhaust steam having a temperature higher than that of heating and cooling water with liquid ammonia. However, in this case, the temperature difference between the exhaust steam and liquid ammonia is much larger than the temperature difference between the heating / cooling water and liquid ammonia, so it is necessary to consider the balance of the flow rate ratio between the exhaust steam and liquid ammonia. Is concerned.

(2) In the above embodiment, gaseous ammonia is used as a secondary fuel for the boiler 1, but the present invention is not limited to this. For example, gaseous ammonia may be used as the main fuel of the boiler 1, or the gaseous ammonia may be burned in the boiler 1 as the sole fuel.

(3) Although the plurality of vaporizers 7 are provided in the above embodiment, the present invention is not limited to this. The number of vaporizers 7 may be appropriately set according to the redundancy and usability of the power generation system, and may be, for example, one.

DESCRIPTION OF SYMBOLS 1 Boiler 2 Steam turbine 3 Generator 4 Condenser 5 Supply pump 6 Ammonia supply device 7 Vaporizer 8 Main fuel supply device K Ammonia vaporization equipment

Claims (4)

A power generation system that drives a steam turbine using steam generated in a boiler,
Equipped with an ammonia vaporization facility for vaporizing liquid ammonia using the heat of exhaust steam exhausted from the steam turbine;
A power generation system, wherein gaseous ammonia obtained by the ammonia vaporization facility is supplied to the boiler and burned as fuel. The ammonia vaporization equipment is
A condenser for condensing the exhaust steam using predetermined cooling water;
The power generation system according to claim 1, further comprising: a vaporizer configured to heat-exchange the cooling water heated by the condenser and the liquid ammonia to generate the gaseous ammonia.   The power generation system according to claim 2, wherein a plurality of the vaporizers are provided in parallel. The power generation system according to claim 2 or 3, wherein the cooling water is water or seawater.

Images