KR100965715B1 - Hybrid Power Plant System using Fuel Cell Generation and Thermoelectric Generation - Google Patents

Abstract

The present invention relates to a combined cycle power plant using fuel cell power generation and thermoelectric power generation, which includes a fuel cell, a fuel supply pipe for supplying fuel to the fuel cell, and an exhaust gas pipe for transporting high temperature exhaust gas generated from the fuel cell. Fuel cell power generation equipment comprising a; And a first thermoelectric power module including the fuel supply pipe as a low heat source absorbing unit and the exhaust gas pipe as a high heat source absorbing unit, and a flue gas discharged through the exhaust gas pipe as a high heat source absorbing unit, and low heat. The thermoelectric power generation unit including a second thermoelectric power generation module as a raw absorption unit; according to the present invention, by generating the power through thermoelectric power generation using waste heat of the fuel cell power generation facility of conventional fuel cell power generation facilities and district heating equipment It has the effect of maximizing thermal efficiency and achieving eco-friendly power generation facilities.

Complex power plant, fuel cell, thermoelectric power generation, power system

Description

Hybrid power plant system using fuel cell generation and thermoelectric generation

The present invention relates to a complex power plant using fuel cell power generation and thermoelectric power generation. More specifically, power is generated through thermoelectric power generation using waste heat of fuel cell power generation facilities, thereby maximizing thermal efficiency of conventional fuel cell power generation facilities and district heating facilities, and combining fuel cell power generation and thermoelectric power generation to achieve eco-friendly power generation facilities. It relates to a power generation facility.

In general, thermal power generation refers to the development of a method of converting thermal energy obtained by burning fossil fuels such as coal, oil, and gas into mechanical energy and converting it into electrical energy.

In the thermal power generation method, the water generated by burning fuel is heated to make steam, and then the steam is used to drive a steam turbine connected to the generator, and the generator is driven by an internal combustion engine such as a diesel engine. System and power generation system using a gas turbine as a prime mover.

In recent years, regulations on carbon dioxide emissions have been tightened to prevent natural disasters caused by global warming and extreme weather. Moreover, as demand for clean energy increases, fuel cell power generation and thermoelectric power generation have been introduced.

Thermoelectric power generation converts heat into electricity using integrated thermoelectric semiconductors, which can directly generate electric power from natural heat such as waste heat, solar heat, geothermal heat, and river water generated from incinerators and various industrial facilities.

Such thermoelectric power generation has recently been in the spotlight as a clean electricity generating device that not only emits no environmentally harmful gas in the process of producing electricity, but also generates no noise and has a long lifetime.

On the other hand, a fuel cell power generation facility is a power generation facility that directly converts chemical energy of hydrogen and oxygen into electrical energy, and generates electricity by an electrochemical reaction, thereby greatly reducing the environmentally harmful gas compared to conventional thermal power generation. It has recently been an issue with facilities.

1 is a configuration diagram schematically showing a conventional fuel cell power generation facility.

As shown in FIG. 1, a conventional fuel cell power generation facility includes a fuel cell 110 that generates electricity by an electrochemical reaction between hydrogen and oxygen, an exhaust gas pipe 120 that discharges high temperature exhaust gas, and A storage battery 130 storing the direct current produced by the fuel cell 110, an inverter 140 converting the direct current produced by the fuel cell 110 into alternating current, and transforming the electricity converted into alternating current by the inverter 140. It is composed of a transformer 150 to transmit the generated electricity to the power system 160 or the like.

Such fuel cell power generation facilities generate waste heat of high temperature as well as electricity due to chemical reaction of fuel. Therefore, a separate energy recovery facility should be constructed, but the high-temperature exhaust gas must be discharged as a flue or cooled by a cooling facility. In addition, the energy supply and demand efficiency due to the operation discharge or cooling of the facility is low, resulting in many inefficient problems.

In order to solve this problem, the present invention produces electric power through thermoelectric power generation using waste heat of fuel cell power generation facilities, thereby maximizing thermal efficiency of conventional fuel cell power generation facilities and district heating facilities, and achieving complex power generation facilities that can achieve eco-friendly power generation facilities. It aims to provide.

In order to achieve the above object, the present invention provides a fuel cell for generating waste current of high current and high temperature by an electrochemical reaction between hydrogen or natural gas and oxygen, a low temperature fuel supply pipe for supplying fuel to the fuel cell, and the fuel. A fuel cell power generation facility including an exhaust gas pipe for transferring high temperature exhaust gas generated from a battery; And a first thermoelectric power module including the fuel supply pipe as a low heat source absorbing unit and the exhaust gas pipe as a high heat source absorbing unit, and a flue gas discharged through the exhaust gas pipe as a high heat source absorbing unit, and low heat. It provides a composite power generation facility using a fuel cell power generation and thermoelectric power generation; characterized in that it comprises a;

According to the present invention, power is produced through thermoelectric power generation using waste heat of a fuel cell power generation facility, thereby maximizing thermal efficiency of a conventional fuel cell power generation facility and district heating facility and achieving an eco-friendly power generation facility.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

2 is a schematic view showing a complex power generation facility using fuel cell power generation and thermoelectric power generation according to the present invention, and FIG. 3 is a schematic view showing a fuel cell power generation facility according to the present invention.

As shown in FIG. 2 and FIG. 3, a combined cycle power generation system using fuel cell power generation and thermoelectric power generation according to the present invention is a fuel cell 110 generating waste heat of current and high temperature by an electrochemical reaction between hydrogen or natural gas and oxygen. ), A fuel including a low temperature fuel supply pipe 215 for supplying fuel to the fuel cell 110, and an exhaust gas pipe 220 for transferring high temperature exhaust gas generated from the fuel cell 110. Battery power plant; And a first thermoelectric power module 230 having the fuel supply pipe 215 as a low heat absorber and the exhaust gas pipe 220 as a high heat absorber, and exhaust gas having passed through the exhaust gas pipe 220. And a thermoelectric generator including a second thermoelectric generator module 240 having the discharge flue 250 as a high heat source absorbing unit and an atmosphere as a low heat source absorbing unit.

The fuel cell power generation facility includes a fuel cell 110 that generates waste current at a high temperature and high temperature by an electrochemical reaction between hydrogen or natural gas and oxygen, and a low temperature fuel supply pipe 215 that supplies fuel to the fuel cell 110. And an exhaust gas pipe 220 for transferring the high temperature exhaust gas generated from the fuel cell 110.

The fuel cell 110 directly converts chemical energy of hydrogen and oxygen into electrical energy by using hydrogen included in liquefied natural gas used in a power plant, but is not necessarily limited thereto. Hydrogen-oxygen fuel cell, methanol A fuel cell may also be used, but will be described below based on liquefied natural gas used in power plants.

The fuel supply pipe 215 is a pipe for supplying natural gas, such as hydrogen, to the fuel cell 110 from the fuel tank 210 to promote a reaction with oxygen to a high heat source of the first thermoelectric power module 230. It is heated by receiving heat from the absorber.

That is, the first thermoelectric power generation module 230 of the first thermoelectric power generation module 230 is formed by using the exhaust gas pipe 220 for transferring the high temperature exhaust gas generated in the fuel power generation facility as the high heat source absorbing part and the fuel supply pipe 215 as the low heat source absorbing part. By heat-exchanging with the high heat source absorption unit, the liquefied natural gas is heated and vaporized.

The high temperature exhaust gas is discharged through the heat recovery device or the flue 250 of district heating through the exhaust gas pipe 220 and the first thermoelectric power generation module 230, and the generated electricity is an inverter 140 for converting direct current into alternating current. ), And the storage battery 130 for storing the generated electricity, and is converted into an alternating current in the inverter and then transmitted to the power system 160 through the transformer 150.

The thermoelectric generator includes a first thermoelectric power module 230 having a fuel supply pipe 215 as a low heat absorber and an exhaust gas pipe 220 as a high heat absorber, and exhaust gas having passed through the exhaust gas pipe 220. And a second thermoelectric power module 240 having the flue gas discharged therein as a high heat source absorbing unit and an atmosphere as a low heat source absorbing unit.

In addition, the first valve 260 and the first valve 260 to set the path for sending the exhaust gas generated from the fuel cell 110 to the heat exchanger 280 of the district heating facility or discharged to the atmosphere from the first valve 260 to the atmosphere It may be configured to further include a second valve 270 for joining the exhaust gas discharged through the heat exchanger 280 to the flue (250).

In addition, it may be configured to further include a control panel for controlling the opening and closing of the first valve 260 and the second valve 270 of the thermoelectric generator according to the temperature and flow rate of the district heating equipment.

Thermoelectric power is used to connect two types of metals, one metal is a high temperature and the other metal is a low temperature, so that electromotive force is generated so that current flows in the two metals. The first thermoelectric module 230 The fuel supply pipe 215 is a low heat source absorption unit, the exhaust gas pipe 220 is a high heat source absorption unit, the second thermoelectric module 240 is the exhaust gas passing through the exhaust gas pipe 220 is discharged Electricity is generated by making the flue 250 a high heat source absorber and an atmosphere as a low heat source absorber.

According to the present invention having the configuration as described above, by generating electric power through thermoelectric power generation using waste heat of the fuel cell power generation facility, there is an effect of maximizing the thermal efficiency of the conventional fuel cell power generation facility and district heating facility and achieving an eco-friendly power generation facility.

The above description is merely illustrative of the present invention, and those skilled in the art will appreciate that various modifications and variations can be made without departing from the essential features of the present invention. Therefore, the embodiments disclosed in the present specification are not intended to limit the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the same scope should be interpreted as being included in the scope of the present invention.

1 is a configuration diagram schematically showing a conventional fuel cell power generation facility.

Figure 2 is a schematic view showing a complex power plant using fuel cell power generation and thermoelectric power generation according to the present invention.

3 is a configuration diagram schematically showing a fuel cell power generation facility according to the present invention.

<Description of the symbols for the main parts of the drawings>

110: fuel cell 160: power system

210: fuel tank 215: fuel supply piping

220: exhaust gas pipe 230: first thermoelectric power module

240: second thermoelectric module 250: the year

260: first valve 270: second valve

280: heat exchanger

Claims (4)

A fuel cell that generates waste heat of current and high temperature by an electrochemical reaction between hydrogen or natural gas and oxygen, a low temperature fuel supply pipe for supplying fuel to the fuel cell, and a high temperature exhaust gas generated from the fuel cell. A fuel cell power generation facility including an exhaust gas pipe to be transferred; The first thermoelectric power module comprising the fuel supply pipe as the low heat source absorbing part and the exhaust gas pipe as the high heat source absorbing part, and the flue gas discharged through the exhaust gas pipe as the high heat source absorbing part, and the atmosphere as a low heat source. A thermoelectric generator including a second thermoelectric module as an absorption unit; Complex power generation facilities using fuel cell power generation and thermoelectric power generation, characterized in that comprises a. The method of claim 1, The fuel supply pipe of the fuel cell power generation facility is heated by heat transferred from the high heat source absorbing part of the first thermoelectric power module and is supplied to the fuel cell. . The method of claim 1, A first valve configured to route exhaust gas generated from the fuel cell to a heat exchanger of a district heating facility or to be discharged to the atmosphere, exhaust gas discharged from the first valve to the atmosphere, and exhaust discharged through the heat exchanger A composite power plant using fuel cell power generation and thermoelectric power generation, characterized in that it further comprises a second valve for joining gas into the flue. The method of claim 3, wherein And a control panel for controlling the opening and closing of the first valve and the second valve of the thermoelectric generator according to the temperature and the flow rate of the district heating facility. Power generation equipment.

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