KR102136693B1 - Exergy Power Generation System - Google Patents

Abstract

The present invention relates to an exergy power generation system, including: a tank (100) for storing a cooling medium; a first heat exchanger (200) to which a cooling medium is transferred from the tank (100) and a first medium is transferred from a first heat source (210), so that the cooling medium and the first medium is heat-exchanged with each other; and a turbine (400) which receives the heat-exchanged cooling medium and is driven by the cooling medium. The cooling medium passing through the turbine (400) is transferred to a customer through a transport line (500).

Description

Exergy Power Generation System

The present invention relates to an exergy power generation system.

LNG (Liquefied Natural Gas) is a gas that is removed from nitrogen, carbon dioxide, and impurities from natural gas, which is a gas for convenience in transportation in overseas gas fields, and then liquefied at low temperature and high pressure.It is methane, propane, butane, etc. Consists of. LNG storage density is about 430 to 470 kg/m ^{3, which} is more than 625 times that of standard gas, and is a cryogenic liquid with a temperature of -162℃. LNG is imported from an offshore gas field through an LNG vessel, and then unloaded and stored in an LNG storage tank at an LNG terminal. Thereafter, LNG is transported to homes, but there is a problem in that it is impossible to specifically utilize the energy possessed by LNG during the transportation process.

KR 10-2018-0126717 A

The present invention is to solve the problems of the above-described prior art, one aspect of the present invention relates to an exergy power generation system capable of generating power by increasing the enthalpy of the cold heat medium and then driving the turbine with the cold heat medium.

In the exergy power generation system according to an embodiment of the present invention, a tank that stores a cold heat medium, the cold heat medium is transferred from the tank, and a first medium is transferred from a first heat source, so that the cold heat medium and the first medium exchange heat The first heat exchanger, and the heat-exchanged cold-heat medium are transferred, and include a turbine driven by the cold-heat medium, and the cold-heat medium that has passed through the turbine is transported to a customer through a transport line.

In addition, in the exergy power generation system according to an embodiment of the present invention, the cold heat medium is transferred from the first heat exchanger, the second medium is transferred from a second heat source, and the cold heat medium and the second medium are heat exchanged. It further includes a second heat exchanger.

In addition, in the exergy power generation system according to the embodiment of the present invention, the first heat source is an ORC (Organic Rankine Cycle) system.

In addition, in the exergy power generation system according to the embodiment of the present invention, the first medium receives heat from at least one of seawater, waste heat from a waste treatment plant, waste heat from a factory, and waste heat from a data center.

In addition, in the exergy power generation system according to the embodiment of the present invention, the second heat source is at least one of a fuel cell system and a boiler.

In addition, in the exergy power generation system according to the embodiment of the present invention, the second medium receives heat from waste heat of the fuel cell system or heat of the boiler.

In addition, in the exergy power generation system according to the embodiment of the present invention, the temperature of the second medium is higher than the temperature of the first medium.

In addition, in the exergy power generation system according to an embodiment of the present invention, the cold heat medium is stored as a liquid in the tank, and is changed from liquid to gas in the first heat exchanger.

In addition, in the exergy power generation system according to an embodiment of the present invention, it is provided between the tank and the first heat exchanger, further comprising a pressure pump to pressurize the cold heat medium.

In addition, in the exergy power generation system according to the embodiment of the present invention, the pressure pump pressurizes the cold heat medium to 100 to 250 bar.

In addition, in the exergy power generation system according to the embodiment of the present invention, the enthalpy increases while the cold heat medium passes through the first heat exchanger and decreases enthalpy while passing through the turbine.

In addition, in the exergy power generation system according to an embodiment of the present invention, it is provided between the tank and the first heat exchanger, the pressure pump to pressurize the cold heat medium, and the cold heat medium is transferred from the first heat exchanger And, the second medium is transferred from the second heat source, and further includes a second heat exchanger in which the cold heat medium and the second medium exchange heat, and the cold heat medium increases the enthalpy while passing through the pressure pump, and the first Enthalpy increases as it passes through the heat exchanger, enthalpy increases as it passes through the second heat exchanger, and enthalpy decreases as it passes through the turbine.

In addition, in the exergy power generation system according to an embodiment of the present invention, it is provided between the tank and the first heat exchanger, the pressure pump to pressurize the cold heat medium, and the cold heat medium is transferred from the first heat exchanger And, the second medium is transferred from the second heat source, and further includes a second heat exchanger in which the cold heat medium and the second medium exchange heat, and the cold heat medium increases in pressure while passing through the pressure pump, and the first The temperature increases as it passes through the heat exchanger, the temperature increases as it passes through the second heat exchanger, and the temperature and pressure decrease as it passes through the turbine.

In addition, in the exergy power generation system according to an embodiment of the present invention, a first supply line for supplying the cold heat medium passing through the turbine to at least one of the fuel cell system and the boiler as a fuel is further included.

In addition, in the exergy power generation system according to an embodiment of the present invention, the agent for supplying boil-off gas of the cold heat medium generated from the tank as fuel to at least one of the fuel cell system and the boiler. 2 The supply line is further included.

In addition, in the exergy power generation system according to the embodiment of the present invention, the cold heat medium is LNG (Liquefied Natural Gas) or CNG (Compressed Natural Gas).

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, the terms or words used in the specification and claims should not be interpreted in a conventional and lexical sense, and the inventor may appropriately define the concept of terms in order to best describe his or her invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of being there.

According to the present invention, after increasing the enthalpy of the cold heat medium, by driving the turbine with the heat medium to generate power, there is an advantage that the cold heat medium to be transported can be used efficiently.

1 is a view showing an exergy power generation system according to a first embodiment of the present invention, and
2 is a view showing an exergy power generation system according to a second embodiment of the present invention.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments that are associated with the accompanying drawings. In addition, it should be noted that, in addition to reference numerals to the components of each drawing in the present specification, the same components have the same numbers as possible, even if they are displayed on different drawings. Also, terms such as “first” and “second” are used to distinguish one component from other components, and the component is not limited by the terms. Hereinafter, in describing the present invention, detailed descriptions of related well-known technologies that may unnecessarily obscure the subject matter of the present invention are omitted.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing an exergy power generation system according to a first embodiment of the present invention.

As illustrated in FIG. 1, in the exergy power generation system according to the present exemplary embodiment, the first medium from the first heat source 210 is transferred from the tank 100 and the tank 100 to store the cold medium. The first heat exchanger 200 through which the cold heat medium and the first medium are exchanged is transferred, and the heat exchanged cold heat medium is transmitted, and includes a turbine 400 driven by the cold heat medium, and cold heat passing through the turbine 400. The medium is transported to the consumer through the transport line 500.

The tank 100 serves to store the cold heat medium. For example, the tank 100 may be to store the cold heat medium transported through the ship before transporting it to a consumer such as a home. Here, the tank 100 maintains low temperature/high pressure so that the cold heat medium maintains a liquid state. At this time, the cooling medium may be LNG (Liquefied Natural Gas), CNG (Compressed Natural Gas), and the like, and the cooling medium stored in the tank 100 may maintain a pressure of about 70 bar and a temperature of about -163°C. Specifically, the cold heat medium stored in the tank 100 may be delivered in a pressurized state (pressure in the tank of the LNG transfer base) at a pressure of about 1 to 2 bar, and then pressurized to a pressure of about 70 bar again. However, the tank 100 does not necessarily mean a separate tank for the exergy power generation system according to the present embodiment, but may mean a tank of an LNG transfer base. In this case, the cold heat medium stored in the tank 100 can maintain a pressure of about 1 to 2 bar and a temperature of about -163°C.

The cold/heat medium stored in the tank 100 at low/high pressure may be delivered to the first heat exchanger 200 through the pressure pump 150. Specifically, the pressure pump 150 is provided between the tank 100 and the first heat exchanger 200, and pressurizes the cold heat medium to a predetermined pressure or more. For example, the pressure pump 150 may pressurize the cold heat medium to 100 to 250 bar.

The first heat exchanger 200 serves to increase the temperature of the cold heat medium. The cold heat medium is transferred from the tank 100 to the first heat exchanger 200, the first medium is transferred to the first heat source 210, and the cold heat medium and the first medium are exchanged with each other. At this time, since the temperature of the first medium is higher than that of the cold heat medium, the temperature of the cold heat medium is increased through heat exchange. The cold heat medium changes phase from liquid to gas as the temperature increases in the first heat exchanger 200. Meanwhile, the first heat source 210 may be, for example, an ORC (Organic Rankine Cycle) system. Here, the ORC system is a power generation system using a relatively low-temperature, eco-friendly energy source. Specifically, the ORC system includes a heat recovery unit (HRU) 213, a turbine 215, a pump 217, and the like, and the first medium circulates them. Here, the first medium receives heat from the heat recovery unit 213 from at least one of a predetermined energy source of seawater, waste heat from a waste treatment plant, waste heat from a factory, and waste heat from a data center to increase the temperature. The first medium having a high temperature is supplied to the turbine 215 to produce electric power, and then flows into the pump 217. In addition, the first medium having a high temperature while passing through the heat recovery unit 213 passes through the first heat exchanger 200 and heat-exchanges with the cold heat medium as described above, thereby raising the temperature of the cold heat medium.

Meanwhile, the cold heat medium that has passed through the first heat exchanger 200 may be transferred to the second heat exchanger 300. Here, the second heat exchanger 300 serves to increase the temperature of the cold heat medium similar to the first heat exchanger 200. The cold heat medium is transferred from the first heat exchanger 200 to the second heat exchanger 300, and the second medium is transferred from the second heat source 320 to exchange heat between the cold heat medium and the second medium. At this time, since the temperature of the second medium is higher than that of the cold heat medium, the temperature of the cold heat medium becomes higher through heat exchange. Meanwhile, the second heat source 320 may be, for example, a fuel cell system 320a. Here, the fuel cell system 320a is a power generation system that generates electricity by reacting fuel and an oxidant electrochemically. In this fuel cell system 320a, considerable waste heat is generated, and the second medium receives heat from the waste heat of the fuel cell system 320a, thereby increasing its temperature. The second medium having a higher temperature is transported by the pump 327 and passes through the second heat exchanger 300, and heat-exchanged with the cold heat medium as described above, thereby raising the temperature of the cold heat medium. At this time, the second medium circulates between the second heat exchanger 300 and the fuel cell system 320a.

As a result, the temperature of the cold heat medium is sequentially increased while passing through the first heat exchanger 200 and the second heat exchanger 300. For example, the cold heat medium is a temperature of about -163°C before passing through the first heat exchanger 200, a temperature of about 0°C after passing through the first heat exchanger 200, and a second heat exchanger After passing through the (300) it may be a temperature of about 53 ℃. As such, in order to sequentially increase the temperature of the cold heat medium, the temperature of the second medium heat exchanged with the cold heat medium in the second heat exchanger 300 is higher than the temperature of the first medium heat exchanged with the cold heat medium in the first heat exchanger 200. Can be high.

The turbine 400 generates power by transferring and driving a cold heat medium. Here, the cold heat medium is pressurized at a high pressure by the pressure pump 150, and the temperature is increased in the first and second heat exchangers 200 and 300. Therefore, the cold heat medium transferred to the turbine 400 has a high enthalpy, and the turbine 400 can be effectively driven by the high enthalpy cold heat medium.

Overall, looking at the pressure and temperature changes of the cold heat medium, the cold heat medium increases in pressure as it passes through the pressure pump 150, and increases in temperature as it passes through the first heat exchanger 200, and the second heat exchanger 300 The temperature increases while passing through, and the temperature and pressure decrease while passing through turbine 400.

In addition, looking at the change in the enthalpy of the cold heat medium, the enthalpy increases as the cold heat medium passes through the pressure pump 150, and increases the enthalpy as it passes through the first heat exchanger 200, and passes through the second heat exchanger 300. While the enthalpy increases, the enthalpy decreases while passing through the turbine 400.

Specifically, the pressure and temperature of the cold heat medium is 70 bar (or 1 to 2 bar) in the tank 100, -163°C, 140 bar, -163°C after passing through the pressure pump 150, and the first heat exchanger 200 After passing through) is 140bar, 0℃, after passing through the second heat exchanger 300 is 140bar, 53℃, and after passing through the turbine 400 may be 70bar, 6.5℃.

In addition, the enthalpy of the cold heat medium is -905.9 kJ/kg in the tank 100, -895.1 kJ/kg after passing through the pressure pump 150, and -227.9 kJ/ after passing through the first heat exchanger 200. kg, -49.5 kJ/kg after passing through the second heat exchanger 300, and -122.6 kJ/kg after passing through the turbine 400. At this time, the output of the turbine 400 is 304.1kW.

The aforementioned pressure, temperature, and enthalpy changes of the cold heat medium may be, for example, as follows.

The pressure and temperature of the cold heat medium is 70 bar (or 1 to 2 bar) in the tank 100, -163°C, 140 bar, -163°C after passing through the pressure pump 150, and passing through the first heat exchanger 200 After 140 bar, 0 ℃, after passing through the second heat exchanger 300, 140 bar, 47 ℃, after passing through the turbine 400 may be 70 bar, 0 ℃.

In addition, the enthalpy of the cold heat medium is -905.9 kJ/kg in the tank 100, -895.1 kJ/kg after passing through the pressure pump 150, and -227.9 kJ/ after passing through the first heat exchanger 200. kg, -68.1 kJ/kg after passing through the second heat exchanger 300, and -141.4 kJ/kg after passing through the turbine 400. At this time, the output of the turbine 400 is 305kW.

In summary, the cold heat medium increases the enthalpy while passing through the pressurized pump 150, the first heat exchanger 200, and the second heat exchanger 300, drives the turbine 400 by the increased enthalpy, and the turbine ( The enthalpy is reduced by the energy used to drive 400).

On the other hand, the numerical values of the above-described pressure, temperature, and enthalpy are described by way of illustration, and of course, the scope of the present invention is not limited thereto.

Additionally, the cold heat medium that has passed through the turbine 400 may be transported to the demand destination through the transport line 500. However, not all of the cold and heat media that have passed through the turbine 400 need to be transported to the customer, and can be supplied as fuel to the fuel cell system 320a through the first supply line 600. Specifically, the first supply line 600 may be branched from the transport line 500 and connected to the fuel cell system 320a. At this time, the cold heat medium may be delivered to the reformer 323 through the first supply line 600 and then supplied to the fuel cell 325 after being reformed in the reformer 323. That is, the fuel cell system 320a may be driven by a cold heat medium, and the fuel cell system 320a driven by the cold heat medium may be a cold heat medium in the second heat exchanger 300 as the second heat source 320 as described above. It can be used to increase the temperature.

Meanwhile, the pressurization pump 150 pressurizes the cold heat medium before the first heat exchanger 200 in which the cold heat medium is changed from liquid to gas. Therefore, the pressurization pump 150 pressurizes the liquid heat medium. If the cold heat medium in the gas state is pressurized, there is a problem that the efficiency of the turbine 400 is reduced because the cold heat medium is transferred in the form of a pulse wave. However, the exergy power generation system according to the present embodiment pressurizes the liquid heat medium, so that the heat medium is continuously transferred, and thus the efficiency of the turbine 400 is excellent.

2 is a view showing an exergy power generation system according to a second embodiment of the present invention. The exergy power generation system according to the second embodiment is similar to the exergy power generation system according to the first embodiment.

Basically, in the exergy power generation system according to the second embodiment, the pressure of the cold heat medium stored in the tank 100 increases while passing through the pressure pump 150, and the first heat exchanger 200 and the second heat exchanger 300 ), the temperature increases, and the temperature and pressure decrease in the process of driving the turbine 400 while passing through the turbine 400. At this time, the first heat exchanger 200, the first medium is transferred from the first heat source (210, ORC system) to increase the temperature of the cold heat medium, the second heat exchanger 300, the second heat source (320, fuel cell system) The second medium is transferred from the 320a and the boiler 320b to increase the temperature of the cold heat medium.

The exergy power generation system according to the second embodiment uses a point in which a boiler 320b is added and boil-off gas of a cold heat medium as fuel such as a fuel cell system 320a or a boiler 320b. The point is different from the exergy power generation system according to the first embodiment. Thus, the exergy power generation system according to the second embodiment omits the overlapping content with the exergy power generation system according to the first embodiment, and is described mainly using the boiler gas of the boiler 320b and the cold heat medium.

In the exergy power generation system according to the second embodiment, a boiler 320b performing a similar function to the fuel cell system 320a is added as the second heat source 320. Specifically, when the cold heat medium and the second medium transferred from the second heat source 320 are heat-exchanged in the second heat exchanger 300, the boiler 320b includes the fuel cell system 320a and the second heat source 320. Can be configured. That is, the second medium receives heat from the heat of the boiler 320b, and the temperature increases, and the second medium with the increased temperature is transported by the pump 329 and passes through the second heat exchanger 300. At this time, since the second medium is heat exchanged with the cold heat medium, the temperature of the cold heat medium is increased. As a result, the boiler 320b provides heat to increase the temperature of the cold heat medium in the second heat exchanger 300.

Meanwhile, the cold heat medium that has passed through the turbine 400 may not only be supplied as fuel to the fuel cell system 320a through the first supply line 600, but also may be supplied as fuel to the boiler 320b. Specifically, the first supply line 600 is branched from the transport line 500 and is again branched to the first-first supply line 610 and the first-second supply line 620, and the first-first supply line ( 610) may be connected to the fuel cell system 320a, and the 1-2 feed line 620 may be connected to the boiler 320b. At this time, the cold heat medium is transferred to the reformer 323 through the first-first supply line 610, and is reformed in the reformer 323, supplied to the fuel cell 325, and the first-2 supply line 620. Through it can be supplied to the boiler (320b). That is, the fuel cell system 320a and the boiler 320b may be driven by a cold heat medium that has passed through the turbine 400.

Meanwhile, in the cold heat medium stored in the tank 100, evaporation gas is generated while evaporating or vaporizing naturally. After the boil-off gas is collected in the buffer tank (170), the fuel cell system (320a) and the boiler (320b) through the 2-1 supply line 180 and the 2-2 supply line 190 It can be fueled. Specifically, the evaporated gas is delivered to the reformer 323 through the 2-1 supply line 180 and is reformed in the reformer 323 and then supplied to the fuel cell 325, and the 2-2 supply line 190 Through it may be supplied to the boiler (320b). That is, the fuel cell system 320a and the boiler 320b may be driven by the evaporation gas of the cold heat medium generated from the tank 100. In the end, the exergy power generation system according to the second embodiment uses evaporation gas that evaporates or vaporizes naturally as fuel for the fuel cell system 320a and the boiler 320b, thereby preventing explosion due to evaporation gas, The use efficiency of the cold heat medium can be further improved.

Although the present invention has been described in detail through specific embodiments, the present invention is specifically for describing the present invention, and the present invention is not limited to this, and by those skilled in the art within the technical spirit of the present invention. It is clear that modification and improvement are possible.

All simple modifications or changes of the present invention belong to the scope of the present invention, and the specific protection scope of the present invention will be clarified by the appended claims.

100: tank 150: pressurized pump
170: buffer tank 180: 2-1 supply line
190: 2-2 supply line 200: first heat exchanger
210: first heat source 213: heat recovery unit
215: turbine 217: pump
300: second heat exchanger 320: second heat source
320a: fuel cell system 323: reformer
325: fuel cell 320b: boiler
400: turbine 500: transport line
600: first supply line 610: first-1 supply line
620: 1-2 supply line

Claims (16)

A tank for storing cold heat medium;
A first heat exchanger in which the cold heat medium is transferred from the tank, the first medium is transferred from a first heat source, and the cold heat medium and the first medium are exchanged; And
A turbine in which the heat-exchanged cold-heat medium is transferred and driven by the cold-heat medium;
Including,
The cold heat medium that has passed through the turbine is transported to a customer through a transport line,
A second heat exchanger in which the cold heat medium is transferred from the first heat exchanger, and a second medium is transferred from a second heat source to exchange heat between the cold heat medium and the second medium;
Further comprising,
The first heat source is an ORC (Organic Rankine Cycle) system including a heat recovery unit,
The first medium receives heat from at least one of seawater, waste heat from a waste treatment plant, waste heat from a factory, and waste heat from a data center, and the temperature increases.
The second heat source is a fuel cell system,
The second medium receives heat from the waste heat of the fuel cell system,
The second medium circulates between the second heat exchanger and the fuel cell system,
The cold heat medium is stored as a liquid in the tank, and is changed from liquid to gas in the first heat exchanger,
A pressure pump provided between the tank and the first heat exchanger to pressurize the cold heat medium;
Further comprising,
The pressure pump pressurizes the cold heat medium to 100 to 250 bar,
The pressurized pump pressurizes the cold heat medium before the first heat exchanger where the cold heat medium is phase shifted from liquid to gas,
The pressure of the cold heat medium after passing through the pressure pump is twice the pressure of the cold heat medium in the tank,
The pressure of the cold heat medium after passing through the turbine is the same as the pressure of the cold heat medium in the exergy power generation system.
delete delete delete delete delete The method according to claim 1,
The exergy power generation system in which the temperature of the second medium is higher than the temperature of the first medium.
delete delete delete The method according to claim 1,
The cold heat medium is an exergy power generation system that increases the enthalpy as it passes through the first heat exchanger and decreases as it passes through the turbine.
The method according to claim 1,
The cold heat medium has an enthalpy that increases as it passes through the pressure pump, an enthalpy increases as it passes through the first heat exchanger, an enthalpy increases as it passes through the second heat exchanger, and an enthalpy decreases as it passes through the turbine. Power generation system.
The method according to claim 1,
The cold heat medium increases in pressure as it passes through the pressure pump, increases in temperature as it passes through the first heat exchanger, increases in temperature as it passes through the second heat exchanger, and decreases in temperature and pressure as it passes through the turbine. Exergy power system.
The method according to claim 1,
A first supply line for supplying the cold heat medium passing through the turbine as fuel to the fuel cell system;
Exergy generation system further comprising a.
The method according to claim 1,
A second supply line supplying boil-off gas of the cold heat medium generated from the tank as fuel to the fuel cell system;
Exergy generation system further comprising a.
The method according to claim 1,
The cold heat medium is LNG (Liquefied Natural Gas) or CNG (Compressed Natural Gas) exergy power generation system.

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