KR20200131030A - Fusion system and method of simultaneous supplying fresh water and electric power linked with HCPVT - Google Patents

Abstract

According to the present invention, provided are a convergence system capable of simultaneously supplying fresh water and electric power in connection with a concentration photo voltaic thermal complex system and an operating method thereof. The convergence system capable of simultaneously supplying fresh water and electric power in connection with a concentration photo voltaic thermal complex system can variously control/configure an operating state of a fresh water/electric power system in accordance with various required amounts of electricity and fresh water required in various regions in connection with the concentration photo voltaic thermal complex system, thereby flexibly responding to and easily supplying the required amounts of electricity and fresh water.

Description

Convergence system and method of simultaneous supplying fresh water and electric power linked with HCPVT}

The present invention relates to a convergence system capable of simultaneously supplying fresh water and electric power while flexibly responding to a required amount of electricity and a required amount of fresh water that may vary according to seasons, regions, etc. in connection with a condensing solar thermal hybrid system, and an operating method thereof.

Desalination refers to a water treatment process in which high-purity drinking water, household water, and industrial water are obtained by removing dissolved substances including salts from water (mainly seawater) that is difficult to use directly as domestic or industrial water.Seawater is produced as fresh water. The facility used for this is called a seawater desalination plant or a seawater desalination plant.

The basic principle of this seawater desalination method is the evaporation method to obtain fresh water by heating seawater using a heat source and condensing the generated vapor, and the reverse osmosis method (RO, Reverse Osmosis), which produces fresh water by passing the seawater through a semipermeable membrane using reverse osmosis. Osmosis) is a representative method, and in addition to this, there is a membrane distillation method (MD, Membrane Distillation).

The evaporation method using a heat source is classified into a multi-stage evaporation method (MSF) and a multiple effect distillation method (MED) according to the flow pattern of the fluid.

Currently, there are three methods of seawater desalination that are widely commercialized: MSF, MED and RO, and there are cases where a hybrid method of producing freshwater by mixing MSF or MED and RO is applied.

Specifically, MSF is a method of producing fresh water by converting seawater into steam using a flashing phenomenon that instantly releases vapor, and then condensing it to produce fresh water.The heat source used to heat seawater is mainly steam. (steam), and this steam is mainly supplied from a steam turbine or a heat recovery boiler of a power plant, so in the case of a seawater desalination facility including MSF, it is generally constructed together with a power plant.

Like MSF, fresh water is produced through evaporation and condensation. MD is a technology capable of operating at low pressure by installing a hydrophobic membrane between the evaporator and the condenser so that only steam passes through it. In the case of such a seawater desalination facility including MD, it can be utilized as a low-temperature heat source such as solar heat, and power consumption is lower than that of a seawater desalination facility including RO, and thus, research has been actively conducted in recent years.

The desalination process takes place in a series of containers called effects similar to the MSF stage, and it reduces the pressure in the container by evaporation by heat exchange between the water vapor condensing in the tube and the concentrated salt water flowing outside the tube. Use the principle.

RO is a technology to obtain high-purity fresh water by removing solutes dissolved in seawater using a semi-permeable membrane and osmotic pressure. The desalination technology most applied along with MSF and MED in seawater desalination facilities currently commercialized to be.

As described above, the reverse osmosis method requires electric energy to pressurize seawater at high pressure, so in the case of seawater desalination facilities including almost all ROs, electric energy is supplied from the power grid.

Therefore, when a seawater desalination facility including a small amount of RO is configured, a limitation/problem that greatly increases the water production unit cost and power consumption is inevitable.

In addition, as described above, the evaporation method using a heat source mainly receives the heat source from a steam turbine or a heat recovery boiler of a power plant, so there is a problem that there is a risk of environmental destruction.

In this regard, in Korean Patent Registration No. 10-0905944 ("Seawater desalination device using solar thermal composite module", prior art 1), seawater is heated using sunlight collected from the solar thermal composite module, and electricity is produced. Thus, a device used in a seawater desalination device is disclosed. However, in Prior Art 1, all of the energy produced by the solar thermal composite module is used only in the seawater desalination system, so only fresh water can be supplied, and no additional use of the produced electrical energy is mentioned at all. In addition, the RO produced water is introduced in series into the still, so that the final fresh water is produced in the still.

Korean Patent Registration No. 10-0905944 (Registration Date 2009.06.26.)

Therefore, the present invention has been devised to solve the above-described problems, and the object of the present invention is to flexibly respond to the required amount of electricity and the amount of fresh water required in various regions (seasons, special days, etc.). It is intended to provide a fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal hybrid system that can constitute a freshwater/electric power system and an operation method thereof.

The convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to the present invention to solve the above problems is a highly condensing solar system that simultaneously produces electric energy and thermal energy using solar energy. The energy production unit 100 comprising a photothermal module (HCPVT, High Concentration Photo Voltaic Thermal), according to control, the power consumption unit 200 receiving electric energy produced by the energy production unit 100, according to the control , The desalination unit 300 and the energy production unit 100, the power consumption unit 200 and the desalination unit 300 receiving electric energy or thermal energy produced by the energy production unit 100 and performing desalination of the supplied seawater. ) Is connected to a wireless or wired network to manage the operation state of the power consuming unit 200 and the desalination unit 300, and using the energy request information or fresh water request information from the outside, the power consumption unit 200 or the It is preferable to include a management unit 400 including an EMS (Energy Management System) that controls the energy produced by the energy production unit 100 supplied for the operation of the desalination unit 300.

Further, the power consumption unit 200 is preferably configured to include an energy storage system (ESS) or a power system (Grid).

Further, it is preferable that the desalination unit 300 is configured to include a reverse osmosis module (RO) or an evaporative module.

Further, when the desalination unit includes the reverse osmosis module, it is preferable to further include a heat exchange module (HX, Heat Exchanger) for preheating the seawater supplied to the reverse osmosis module.

Furthermore, when the energy request information exists and the freshwater request information is higher than a preset reference value, the electric energy produced by the energy production unit 100 is transmitted to the energy storage system and the power system of the power consumption unit 200. And, the electric energy or thermal energy produced by the energy production unit 100 is transmitted to the reverse osmosis pressure module and the evaporation module of the desalination unit 300, and the heat energy produced by the energy generation unit 100 is operated by the heat exchange module. It is desirable to transfer it by energy.

Alternatively, when the energy request information exists and the freshwater request information is lower than a preset reference value, the management unit 400 produces the energy by the energy storage system and the power system of the power consumption unit 200 by the energy production unit 100 It is preferable to transmit one electric energy, and to transmit thermal energy produced by the energy production unit 100 to an evaporative module of the desalination unit 300.

Alternatively, when the energy request information does not exist and the freshwater request information is higher than a preset reference value, the management unit 400 uses the energy storage system of the power consumption unit 200 to generate electricity generated by the energy generation unit 100. It transmits energy, and transmits the electric energy produced by the energy production unit 100 to the reverse osmosis module of the desalination unit 300, and transmits the thermal energy produced by the energy production unit 100 to the operating energy of the heat exchange module. It is desirable to do.

Alternatively, when the energy request information does not exist and the freshwater request information is lower than a preset reference value, the management unit 400 uses the energy storage system of the power consumption unit 200 to generate electricity generated by the energy generation unit 100. It is preferable to transmit energy, and to transmit thermal energy produced by the energy production unit 100 to an evaporative module of the desalination unit 300.

Furthermore, the energy storage system of the power consumption unit 200 stores the electric energy produced by the energy generation unit 100, and the management unit 400 based on the amount of energy produced by the energy generation unit 100 It is preferable to supply to the desalination unit 300 or the power system according to the control of.

Furthermore, the management unit 400 includes energy request information received from the outside, freshwater request information, solar energy insolation information, electric energy production information, thermal energy production information, and energy consumption information of the desalination unit 300 It is preferable to control the transmission state of the energy produced by the energy generation unit 100 to the power consumption unit 200 and the distribution state of operating energy to the desalination unit 300 using the monitoring information.

The operation method of the fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to the present invention is a highly condensing solar thermal module (HCPVT, High) that simultaneously produces electric energy and thermal energy using solar energy. Concentration Photo Voltaic Thermal) from the management department that controls the production energy of the energy production department, including externally input energy request information, freshwater request information, solar energy insolation information, electric energy production information, thermal energy production information, desalination By using monitoring information including energy consumption information in the unit, the control analysis step (S100) and the control analysis step (S100) determine the control of the transmission state to the power consumption unit and the operation energy distribution state to the desalination unit. According to the determination, the transmission state of the electric energy produced by the energy generation unit to the power consumption unit is controlled, and the distribution state of the electric energy or thermal energy produced by the energy generation unit for controlling the operation state of the desalination unit is controlled. It consists of a step (S200), wherein the power consumption unit includes an energy storage system (ESS) or a power system (Grid), and the desalination unit uses a reverse osmosis module (RO, Reverse Osmosis or evaporation type module). It is configured to include, and is preferably configured to further include a heat exchange module (HX, Heat Exchanger) for preheating the seawater supplied to the reverse osmosis module.

Furthermore, in the energy distribution step (S200), when the energy request information is present and the freshwater request information is higher than a preset reference value, the electric energy produced by the energy production unit is converted into the energy storage system and the power system of the power consumption unit. It is preferable to transmit the electric energy or thermal energy produced by the energy generation unit to the reverse osmosis pressure module and the evaporation module of the desalination unit, and to transmit the thermal energy produced by the energy generation unit as the operating energy of the heat exchange module.

Alternatively, in the energy distribution step (S200), when the energy request information exists and the freshwater request information is lower than a preset reference value, the electric energy produced by the energy generation unit is transmitted to the energy storage system and the power system of the power consumption unit. And, it is preferable to transmit the thermal energy produced by the energy production unit to the evaporation module of the desalination unit.

Alternatively, in the energy distribution step (S200), when the energy request information does not exist and the fresh water request information is higher than a preset reference value, the electric energy produced by the energy production unit is transmitted to the energy storage system of the power consumption unit, It is preferable that the electric energy produced by the energy production unit is transmitted to the reverse osmosis pressure module of the desalination unit, and the thermal energy produced by the energy generation unit is transmitted as the operating energy of the heat exchange module.

Alternatively, in the energy distribution step (S200), when the energy request information does not exist and the fresh water request information is lower than a preset reference value, the electric energy produced by the energy production unit 100 is converted to the energy storage system of the power consumption unit. It is preferable to transmit the thermal energy produced by the energy generation unit to the evaporation module of the desalination unit.

Alternatively, in the energy distribution step (S200), according to the determination by the control analysis step (S100), when the energy production amount information of the energy production unit is less than the energy consumption amount information or the energy request information of the desalination unit, the power consumption unit It is preferable to supply the electric energy stored in the energy storage system to the desalination unit 300 or the power system.

According to the convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to a preferred embodiment of the present invention and its operation method, various required in various regions in connection with the condensing solar thermal complex system Depending on the amount of electricity required/needed fresh water, in other words, it can be applied to various required amount of electricity/needed fresh water required in various regions, and the required amount of electricity/needed differently depending on the season or special day, even in the same area Since it is possible to control the configuration of the freshwater/electric power system in various ways according to the amount of freshwater, there is an advantage of being able to easily supply electricity/freshwater while flexibly responding to various required electric quantity/required freshwater quantity according to operation.

In other words, regions with high demand for water with the presence of electricity demand, regions with low demand for water with the presence of demand for electricity, regions with large demand for water with no demand for electricity, regions with no demand for electricity and with little water demand, etc. There is an advantage of being able to configure a freshwater/electric power system to be optimized for various areas.

In addition, even if the freshwater/electricity system is configured according to the local situation, even if the electricity demand/water demand changes according to the season or the specific situation of the region, it is optimized accordingly to configure the freshwater/electricity system. It has the advantage of being able to easily supply electricity/fresh water by changing and controlling it.

At this time, not all desalination facilities are configured, but the merits of each desalination facility and the required amount of fresh water can be considered at the same time, and the amount of seawater intake can be reduced through the fusion of various desalination facilities and the quality of the produced water can be flexibly adjusted to obtain a synergy effect. There is an advantage.

In particular, when the operation state is controlled/configured by combining the reverse osmosis desalination method and the membrane distillation desalination method, the concentrated water discharged from the reverse osmosis desalination facility can be once again desalized with the membrane distillation desalination facility. Condensed water that must be generated can be reduced, and the amount of produced water can be increased, thereby improving economic efficiency such as water production cost.

In particular, even where there is no separate power grid (power plant, etc.), solar energy is used to produce electricity and heat, and the optimal system can be configured and operated through it. There is an advantage of being able to drive.

Through this, it has a lower water production cost compared to competitive technology (PV-RO) based on the same capacity facility, and it is possible to smoothly supply the required amount of electricity/needed fresh water through the configuration of an optimized facility according to the demand for water and electricity. There is an advantage of having a lower construction cost compared to the construction cost of an electricity production facility (PV-RO) of the same capacity.

1 is a block diagram showing a fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system according to an embodiment of the present invention.
2 is an exemplary view showing a fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system according to an embodiment of the present invention.
3 is a flow chart showing an operating method of a fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to an embodiment of the present invention.

Hereinafter, a fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system of the present invention and an operating method thereof will be described in detail with reference to the accompanying drawings. The drawings introduced below are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. In addition, the same reference numbers throughout the specification indicate the same elements.

In this case, unless there are other definitions in the technical terms and scientific terms used, they have the meanings commonly understood by those of ordinary skill in the art to which this invention belongs, and the gist of the present invention in the following description and accompanying drawings A description of known functions and configurations that may unnecessarily obscure will be omitted.

In addition, the system refers to a set of components including devices, devices, and means that are organized and regularly interact to perform a required function.

The convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to an embodiment of the present invention and its operation method are required according to the season as well as various regions in connection with the condensing solar thermal complex system. It is possible to control/configure the operation state of the optimized freshwater/electric power system according to the various required electricity quantity/needed freshwater quantity. Through this, it relates to a system that can flexibly respond and supply a required amount of electricity/needed fresh water required and an operation method thereof.

In particular, by configuring the RO or evaporative module (MD or MED) as the desalination facility, the concentrated water discharged from the RO desalination facility can be re-desalted in the evaporative desalination facility, effectively reducing the seawater concentrated water, a by-product of desalination. There is an advantage that can be reduced.

1 is a block diagram showing a fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system according to an embodiment of the present invention, and FIG. 2 is a condensing solar system according to an embodiment of the present invention. It is an exemplary diagram showing a fusion system capable of simultaneously supplying fresh water and electric power in connection with a photovoltaic complex system.

A fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal hybrid system according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 and 2.

The convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to an embodiment of the present invention is, as shown in FIG. 1, at least one of the energy production unit 100 and the management unit 400 The power consumption unit 200 operating according to the control, the desalination unit 300 operating under the control of the management unit 400, and the energy production unit 100, the power consumption unit 200, and the operation state of the desalination unit 300 It manages and is preferably configured to include a management unit 400 that controls the flow (supply) of the energy produced by the energy production unit 100.

To learn more about each configuration,

The energy production unit 100 is preferably configured to include a high concentration photovoltaic module (HCPVT, High Concentration Photo Voltaic Thermal) that simultaneously produces electrical energy and thermal energy using solar energy.

The energy conversion efficiency of existing photovoltaic power generation (PV, Photo Voltaic) is only 18%, but solar power generation using high-concentration photovoltaic modules can achieve energy conversion efficiency of more than 70%, the highest energy per condensing unit area. Indicates efficiency.

Therefore, by configuring the energy production unit 100 to include a high-concentration photovoltaic module, it is possible to achieve the same level of desalination performance in half the area of the existing seawater desalination facility (PV-RO). It can be seen through an experiment that it increases by about %.

In detail, the installation cost compared to the existing PV-RO is similar, but the required site area is reduced by 24 to 59%, and the freshwater production is increased by 5 to 10% through experiments, so low water production cost/low It has the advantage of having a construction cost.

In detail, since the RO configuration cost is the same, the analysis result of comparing the installation cost and area between PV and HCPVT can be expressed as shown in Tables 1 and 2 below.

PV (based on 700kWp) Installation price 13.4 Billion Required area 11,600 m ² Area per kW 16.6 m ² /kW

HCPVT Area per unit 50 m ² Rated capacity 8.5 kW 700kW required number 82 dog Required area 4,118 m ² Required price 14.0 Billion

The energy production unit 100 may further include a solar position precise tracking means (not shown) in order to maximize the power generation efficiency of the highly concentrated solar thermal module.

Through this, the convergence system capable of simultaneously supplying fresh water and power in connection with the condensing solar thermal complex system according to an embodiment of the present invention uses heat and electricity produced through the highly condensing solar thermal module of the energy production unit 100 to seawater. By providing it as a desalination facility, it is possible to simultaneously supply fresh water and electricity by supplying power to the power system while supplying power to the power system while supplying power to the reverse osmosis (RO) desalination facility using electric energy or the evaporative desalination facility using thermal energy. There is this.

In particular, as described above, the desalination unit 300 of the production energy (electrical energy, thermal energy, etc.) of the energy production unit 100 according to various required electric quantity/needed freshwater quantity required in various ways through the management unit 400, the power consumption unit Since the flow to 200 can be optimized and controlled, the required amount of electricity / required amount of fresh water can be easily supplied.

The power consumption unit 200 preferably receives the electric energy produced by the energy production unit 100 under the control of the management unit 400, and as shown in FIG. 2, an energy storage system (ESS) ), it is preferable to be configured to include a power system (Grid).

In this case, the electric energy produced by the energy generating unit 100 is basically used as the operating energy required by the desalination unit 300. That is, even in the case of an evaporative desalination facility using thermal energy, it is natural that electric energy for driving the basic facility is required. Therefore, the electric energy produced by the energy production unit 100 first is the basic operating energy required by the desalination unit 300 It is desirable to be utilized as.

Thereafter, among the electric energy produced by the energy production unit 100, the remaining energy is used as the basic operating energy of the desalination unit 300, and the remaining surplus energy may be provided as the operating energy of the desalination unit 300 when solar energy does not exist. It is desirable to store it in the energy storage system or transmit it to the power system according to external energy request information.

For example, in the case of configuring only the desalination facility using a heat source through the desalination unit 300, most of the electric energy produced by the energy production unit 100, except for the basic operating energy, is transferred to the power consumption unit 200. You can use it.

In this case, in accordance with the energy request information from the outside, all of them may be transmitted to the power system, some may be stored in the energy storage system and some may be transmitted to the power system, or all may be stored in the energy storage system.

This operation state is made under the control of the management unit 400, and the control operation of the management unit 400 will be described in detail later.

It is preferable that the desalination unit 300 receives electric energy or thermal energy produced by the energy production unit 100 under the control of the management unit 400. In other words, the desalination unit 300 controls whether to proceed with the desalination operation according to the energy transmitted under the control of the management unit 400.

In detail, the desalination unit 300 is preferably configured to include a reverse osmosis desalination facility (hereinafter referred to as a reverse osmosis module (RO)) or an evaporative desalination facility (hereinafter, an evaporation type module), and a reverse osmosis pressure module In desalination, electric energy is used, and the evaporative module mainly uses thermal energy to desalination.

At this time, the evaporation module is composed of a membrane distillation module (MD, Membrane Distillation) or a multi-effect evaporation module (MED, Multi-Effect Distillation), but the productivity information of the membrane distillation module or the multi-effect evaporation module It can be configured selectively using economic information.

For example, if the productivity information of the film distillation module is better, the film distillation module can be configured with an evaporative module, and if the economic information of the multi-effect evaporation module is better, the evaporation module can be used for multi-effect evaporation. A module can be configured, and of course, both a film distillation module and a multi-effect evaporation module can be configured at once, but in this case, since it may affect the economics of the entire system, it is selected and configured using the above information. It is most preferred.

At this time, the reverse osmosis module is preferably configured to further include a heat exchanger module (HX, Heat Exchanger) for seawater preheating, and since the heat exchange module preheats seawater using thermal energy, the reverse osmosis module also uses only electrical energy. It is preferable not to use it, but to use some heat energy.

Test that the permeability of the reverse osmosis module receiving the preheated seawater increases by 10-15% when preheating the seawater to 5℃ through the heat exchange module (the preheating temperature at a level that does not affect the life of the semipermeable membrane or the quality of the water produced). As confirmed through, it is desirable to improve the freshwater efficiency of the reverse osmosis module through seawater preheating.

The management unit 400 is connected to the energy production unit 100, the power consumption unit 200, and the desalination unit 300 and is connected to a wireless or wired network to manage the operation state, and monitoring information or energy request information including energy consumption, freshwater request It is preferable to include an EMS (Energy Management System) that controls the energy produced by the energy production unit 100 supplied to the power consumption unit 200 or the desalination unit 300 using information.

In other words, the management unit 400 is based on the energy request information, which is the required amount of electricity information input from the outside, and the freshwater request information, which is the required freshwater amount information, information about solar energy transmitted from the energy production unit 100, and information on the amount of electric energy produced. , It is preferable to analyze monitoring information including information on the amount of heat energy production, information on the amount of energy consumption of each desalination facility included in the desalination unit 300, and the like.

It is most preferable to use a previously stored optimal analysis or optimal control algorithm for this analysis process.

According to the analysis result, the operation of the facility corresponding to the energy produced by the energy production unit 100 by selecting at least one facility that can most optimize and satisfy the energy request information among the facilities included in the desalination unit 300 By transmitting as energy, the distribution of operating energy to the desalination unit 300 with respect to the energy produced by the energy generation unit 100 may be controlled. Of course, the transmission state of the energy produced by the energy generation unit 100 to the energy storage system of the power consumption unit 200 or the power facility may also be controlled.

The management unit 400 may classify the energy request information into four types according to the analysis result, and the operation distribution of each desalination facility included in the desalination unit 300 according to the classified four types will be described later.

Category 1

According to the analysis result, the management unit 400 has energy request information (energy request information that requests the supply of electric energy from the outside), and when the freshwater request information is higher than a preset reference value, the power consumption unit 200 stores energy. It is preferable to transmit the electric energy produced by the energy production unit 100 to the system and the power system.

In addition, it is preferable to consist of a reverse osmosis module of the desalination unit 300 and an evaporation type module, and it is preferable to transmit electric energy or thermal energy produced by the energy production unit 100 as operating energy for desalination of seawater by each module. desirable.

Specifically, the reverse osmosis module can supply electric energy as operating energy, and the evaporation module can supply a small amount of electric energy for basic operation and thermal energy for freshwater operation as operating energy, as described above. It is preferable to configure, including a heat exchange module for preheating seawater supplied to the reverse osmosis module.

Therefore, it is preferable to also supply the heat energy produced by the energy production unit 100 to the heat exchange module.

At this time, the electric energy transmitted to the power consumption unit 200 is most preferably the remaining electric energy consumed by the desalination unit 300 first, but when'energy request information' is prioritized under the control of an external manager. , After satisfying the amount of electricity demanded through the power consumption unit 200 first, the desalination unit 300 may be operated using the remaining electric energy.

Here, the freshwater request information is preferably set based on the number of residents who will be supplied with freshwater, and the preset reference value of the freshwater request information is preferably a reference value set in consideration of productivity and economy of the reverse osmosis module.

In addition, by configuring the evaporative module together with the reverse osmosis module, the concentrated water discharged from the reverse osmosis module is once again desalted with the evaporative module, thereby reducing the concentration of water, thereby making it eco-friendly.

Category 2

According to the analysis result, the management unit 400 has energy request information (energy request information that requests the supply of electric energy from the outside), and when the freshwater request information is lower than a preset reference value, the power consumption unit 200 stores energy. It is preferable to transmit the electric energy produced by the energy production unit 100 to the system and the power system.

In addition, the desalination unit 300 is preferably configured as an evaporation type module, and it is preferable to transmit the thermal energy produced by the energy production unit 100 as operating energy for desalination of seawater by the evaporation type module.

In this case, the electric energy transmitted to the power consuming unit 200 is most preferably the remaining electric energy after the desalination unit 300 preferentially consumes a small amount of electric energy for basic operation.

Category 3

According to the analysis result, when the energy request information does not exist and the freshwater request information is higher than a preset reference value, the management unit 400 uses the energy storage system of the power consumption unit 200 to convert the electric energy produced by the energy production unit 100. It is desirable to transmit.

That is, since a request for supply of electric energy does not occur from the outside, the electric energy produced by the energy generating unit 100 can be transmitted to and stored in the energy storage system.

In addition, it is preferable to configure a reverse osmosis module of the desalination unit 300, and it is preferable to transmit the electric energy produced by the energy production unit 100 as operating energy for desalination of seawater by the reverse osmosis module.

In addition, it is preferable to include a heat exchange module for preheating seawater supplied to the reverse osmosis module.

Therefore, it is preferable to also supply the heat energy produced by the energy production unit 100 to the heat exchange module.

At this time, since the'energy request information' does not exist, the electric energy transmitted to the power consuming unit 200 is most preferably the remaining electric energy consumed by the desalination unit 300.

Category 4

According to the analysis result, when the energy request information does not exist and the freshwater request information is lower than a preset reference value, the management unit 400 uses the energy storage system of the power consumption unit 200 to store the electric energy produced by the energy production unit 100. It is desirable to transmit.

That is, since a request for supply of electric energy does not occur from the outside, the electric energy produced by the energy generating unit 100 can be transmitted to and stored in the energy storage system.

In addition, it is preferable to configure an evaporative module of the desalination unit 300, and it is preferable to transmit the thermal energy produced by the energy production unit 100 as operating energy for desalination of seawater for the evaporative module.

At this time, since the'energy request information' does not exist, the electric energy transmitted to the power consuming unit 200 is most preferably the remaining electric energy consumed by the desalination unit 300.

In addition, the fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to an embodiment of the present invention includes waste heat in addition to the highly condensing solar thermal module to the energy production unit 100. It may be configured to include a power generation module such as a diesel generator to generate.

In this case, the management unit 400 only partially transmits the electric energy produced by the energy generation unit 100 as the operating energy of the reverse osmosis module of the desalination unit 300, and all the rest is the power system and energy of the power consumption unit 200. Since it can be transmitted to a storage system, there is an advantage that maximum power operation is possible.

In addition, the thermal energy produced by the energy production unit 100 can be transmitted as the operating energy for preheating seawater with a heat exchange module included in the reverse osmosis module of the desalination unit 300 and can be transmitted as the operating energy of the evaporative module. It has the advantage of being able to supply fresh water.

3 is a flow chart showing an operating method of a fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to an embodiment of the present invention.

Referring to FIG. 3, a method of operating a fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal hybrid system according to an embodiment of the present invention will be described in detail.

The operation method of the fusion system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal hybrid system according to an embodiment of the present invention is as shown in FIG. 3, by the management unit 400, the power consumption unit ( Energy distribution in which the production energy is distributed according to the determination by the control analysis step (S100) and control analysis step (S100) of determining the control of the distribution state of the energy production unit 100 to the desalination unit 300 and the energy production unit 300 It is preferable that it consists of step (S200).

To learn more about each step,

The control analysis step (S100) is input from the outside in the management unit 400 that manages the energy produced by the energy production unit 100, which includes a high-concentration photovoltaic module that simultaneously produces electric energy and thermal energy using solar energy. Based on the energy request information, which is the required amount of electricity that is required, and the fresh water request information, which is the required freshwater amount information, the solar energy information transmitted from the energy production unit 100, electric energy production information, thermal energy production information, and the desalination unit 300 Monitoring information including energy consumption information of each desalination facility that has been installed is analyzed.

According to the analysis result, a determination is made for controlling the transmission state of the energy produced by the energy generation unit 100 to the power consumption unit 200 and the distribution state of the operating energy to the desalination unit 300.

In the energy distribution step (S200), according to the determination by the control analysis step (S100), the transmission state of the energy produced by the energy generation unit 100 to the power consumption unit 200 is controlled, and the operation energy of the desalination unit 300 is controlled. It is possible to control the distribution state of the energy produced by the energy production unit 100 for.

The determination by the control analysis step (S100) is the same as the first classification, the second classification, the third classification, and the fourth classification described above.

In other words, in the energy distribution step (S200), according to the determination by the control analysis step (S100), energy request information (energy request information for requesting the supply of electric energy from the outside) exists, and the freshwater request information is less than a preset reference value. When it is high, it is preferable to transmit the electric energy produced by the energy generation unit 100 to the energy storage system and the power system of the power consumption unit 200.

In addition, it is preferable to consist of a reverse osmosis module of the desalination unit 300 and an evaporation type module, and it is preferable to transmit electric energy or thermal energy produced by the energy production unit 100 as operating energy for desalination of seawater by each module. desirable.

Specifically, the reverse osmosis module can supply electric energy as operating energy, and the evaporation module can supply a small amount of electric energy for basic operation and thermal energy for freshwater operation as operating energy, as described above. It is preferable to configure, including a heat exchange module for preheating seawater supplied to the reverse osmosis module.

Therefore, it is preferable to also supply the heat energy produced by the energy production unit 100 to the heat exchange module.

At this time, the electric energy transmitted to the power consumption unit 200 is most preferably the remaining electric energy consumed by the desalination unit 300 first, but when'energy request information' is prioritized under the control of an external manager. , After satisfying the amount of electricity demanded through the power consumption unit 200 first, the desalination unit 300 may be operated using the remaining electric energy.

Alternatively, in the energy distribution step (S200), according to the determination by the control analysis step (S100), energy request information (energy request information for requesting the supply of electric energy from the outside) exists, and the freshwater request information is lower than a preset reference value. In this case, it is preferable to transmit the electric energy produced by the energy generation unit 100 to the energy storage system and the power system of the power consumption unit 200.

In addition, it is preferable to configure an evaporative module of the desalination unit 300, and it is preferable to transmit the thermal energy produced by the energy production unit 100 as operating energy for desalination of seawater by the evaporation type module.

In this case, the electric energy transmitted to the power consuming unit 200 is most preferably the remaining electric energy after the desalination unit 300 preferentially consumes a small amount of electric energy for basic operation.

Alternatively, in the energy distribution step (S200), according to the determination by the control analysis step (S100), when there is no energy request information and the freshwater request information is higher than a preset reference value, the energy storage system of the power consumption unit 200 is used. It is preferable to transmit the electric energy produced by the energy production unit 100.

That is, since a request for supply of electric energy does not occur from the outside, the electric energy produced by the energy generating unit 100 can be transmitted to and stored in the energy storage system.

In addition, it is preferable to configure a reverse osmosis module of the desalination unit 300, and it is preferable to transmit the electric energy produced by the energy production unit 100 as operating energy for desalination of seawater by the reverse osmosis module.

In addition, it is preferable to include a heat exchange module for preheating seawater supplied to the reverse osmosis module.

Therefore, it is preferable to also supply the heat energy produced by the energy production unit 100 to the heat exchange module.

At this time, since the'energy request information' does not exist, the electric energy transmitted to the power consuming unit 200 is most preferably the remaining electric energy consumed by the desalination unit 300.

Alternatively, in the energy distribution step (S200), according to the determination by the control analysis step (S100), when there is no energy request information and the freshwater request information is lower than a preset reference value, the energy storage system of the power consumption unit 200 is used. It is preferable to transmit the electric energy produced by the energy production unit 100.

That is, since a request for supply of electric energy does not occur from the outside, the electric energy produced by the energy generating unit 100 can be transmitted to and stored in the energy storage system.

In addition, it is preferable to configure an evaporative module of the desalination unit 300, and it is preferable to transmit the thermal energy produced by the energy production unit 100 as operating energy for desalination of seawater for the evaporative module.

At this time, since the'energy request information' does not exist, the electric energy transmitted to the power consuming unit 200 is most preferably the remaining electric energy consumed by the desalination unit 300.

That is, in other words, the convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system according to an embodiment of the present invention and its operation method are limited to various areas in connection with the condensing solar thermal complex system. Rather, it provides a configuration of a freshwater/electric power system optimized according to the various required electric quantity/needed freshwater quantity that is differently required according to the season and special situation (case), and the required electric quantity/needed freshwater quantity according to their operation is easily provided. There are advantages to supply.

As described above, in the present invention, specific matters such as specific components, etc. and limited embodiments have been described, but this is provided only to aid in a more general understanding of the present invention, and the present invention is limited to the above-described embodiment. It is not, and those of ordinary skill in the field to which the present invention belongs can make various modifications and variations from this description.

Therefore, the spirit of the present invention is limited to the described embodiments and should not be determined, and all things equivalent or equivalent to the claims as well as the claims to be described later belong to the scope of the spirit of the present invention. .

100: Energy Production Department
200: power consumption unit
300: desalination unit
400: management department

Claims (16)

An energy production unit 100 comprising a high concentration photovoltaic module (HCPVT, High Concentration Photo Voltaic Thermal) that simultaneously produces electrical energy and thermal energy using solar energy;
A power consumption unit 200 receiving electric energy generated by the energy generation unit 100 according to the control;
A desalination unit 300 receiving electric energy or thermal energy produced by the energy production unit 100 according to control, and performing desalination of the supplied seawater; And
The energy production unit 100, the power consumption unit 200, and the desalination unit 300 are connected to a wireless or wired network to manage the operation state of the power consumption unit 200 and the desalination unit 300, and request energy from the outside. Including an EMS (Energy Management System) that controls the energy produced by the energy production unit 100 supplied for the operation of the power consumption unit 200 or the desalination unit 300 using information or freshwater request information Management unit 400;
Convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, comprising: a.
The method of claim 1,
The power consumption unit 200 is
Convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that it is configured to include an energy storage system (ESS) or a grid.
The method of claim 2,
The desalination unit 300 is
Convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that it includes a reverse osmosis module (RO) or an evaporative module.
The method of claim 3,
A convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system
When configured to include the reverse osmosis module as the desalination unit,
A fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that it further comprises a heat exchange module (HX, Heat Exchanger) for preheating seawater supplied to the reverse osmosis module.
The method of claim 4,
The management unit 400
When the energy request information exists and the fresh water request information is higher than a preset reference value,
The electric energy produced by the energy production unit 100 is transmitted to the energy storage system and the power system of the power consumption unit 200,
The electric energy or thermal energy produced by the energy production unit 100 is transmitted to the reverse osmosis pressure module and the evaporation module of the desalination unit 300, and the thermal energy produced by the energy generation unit 100 is converted to the operating energy of the heat exchange module. Convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system characterized in that transmission.
The method of claim 4,
The management unit 400
When the energy request information is present and the fresh water request information is lower than a preset reference value,
The electric energy produced by the energy production unit 100 is transmitted to the energy storage system and the power system of the power consumption unit 200,
A convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that the thermal energy produced by the energy production unit 100 is transmitted to an evaporative module of the desalination unit 300.
The method of claim 4,
The management unit 400
When the energy request information does not exist and the fresh water request information is higher than a preset reference value,
The electric energy produced by the energy production unit 100 is transmitted to the energy storage system of the power consumption unit 200,
The electric energy produced by the energy generating unit 100 is transmitted to the reverse osmosis module of the desalination unit 300, and the thermal energy produced by the energy generating unit 100 is transmitted as operating energy of the heat exchange module. Convergence system capable of simultaneously supplying fresh water and electric power in connection with the condensing solar thermal complex system.
The method of claim 4,
The management unit 400
When the energy request information does not exist and the fresh water request information is lower than a preset reference value,
The electric energy produced by the energy production unit 100 is transmitted to the energy storage system of the power consumption unit 200,
A convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that the thermal energy produced by the energy production unit 100 is transmitted to an evaporative module of the desalination unit 300.
The method according to any one of claims 5 to 8,
The energy storage system of the power consumption unit 200
It stores the electric energy produced by the energy production unit 100,
According to the control of the management unit 400 based on the amount of energy produced by the energy production unit 100,
Convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that supplying to the desalination unit 300 or the power system.
The method according to any one of claims 5 to 8,
The management unit 400
Using the monitoring information including energy request information, freshwater request information, solar energy information, electric energy production information, thermal energy production information, and energy consumption information of the desalination unit 300, received from the outside, In connection with the condensing solar thermal complex system, characterized in that the transmission status of the energy produced by the energy production unit 100 to the power consumption unit 200 and the distribution of operating energy to the desalination unit 300 are controlled, Convergence system that can supply power simultaneously.
Energy request information received from the outside from the management department that controls the energy produced by the energy production department, which includes a high concentration photovoltaic module (HCPVT, High Concentration Photo Voltaic Thermal) that simultaneously produces electrical energy and thermal energy using solar energy. Using monitoring information including freshwater request information, solar energy insolation information, electric energy production information, thermal energy production information, and energy consumption information in the desalination unit, the transmission status to the power consumption unit and the operating energy distribution to the desalination unit A control analysis step (S100) of determining control of a state; And
According to the determination by the control analysis step (S100), the transmission state of the electric energy produced by the energy generation unit to the power consumption unit is controlled, and the electric energy produced by the energy generation unit for controlling the operation state of the desalination unit or An energy distribution step (S200) in which a distribution state of heat energy is controlled;
Is made of,
The power consumption unit is configured to include an energy storage system (ESS) or a power system (Grid),
The desalination unit is configured to include a reverse osmosis module (RO, Reverse Osmosis or evaporation type module, and further comprises a heat exchange module (HX, Heat Exchanger) for preheating seawater supplied to the reverse osmosis module). A method of operating a fusion system capable of simultaneously supplying fresh water and power in connection with a condensing solar thermal complex system.
The method of claim 11,
The energy distribution step (S200)
When the energy request information exists and the fresh water request information is higher than a preset reference value,
The electric energy produced by the energy production unit is transmitted to the energy storage system and the power system of the power consumption unit,
Condensing solar heat, characterized in that the electric energy or thermal energy produced by the energy production unit is transmitted to the reverse osmosis module and the evaporation module of the desalination unit, and the thermal energy produced by the energy generation unit is transmitted as operating energy of the heat exchange module. A method of operating a fusion system capable of simultaneously supplying fresh water and electricity in connection with a complex system.
The method of claim 11,
The energy distribution step (S200)
When the energy request information is present and the fresh water request information is lower than a preset reference value,
The electric energy produced by the energy production unit is transmitted to the energy storage system and the power system of the power consumption unit,
A method of operating a fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that transmitting thermal energy produced by the energy generating unit to an evaporative module of the desalination unit.
The method of claim 11,
The energy distribution step (S200)
When the energy request information does not exist and the fresh water request information is higher than a preset reference value,
The electric energy produced by the energy production unit is transmitted to the energy storage system of the power consumption unit,
Fresh water in connection with a condensing solar thermal complex system, characterized in that the electric energy produced by the energy production unit is transferred to the reverse osmosis module of the desalination unit, and the thermal energy produced by the energy production unit is transferred to the operating energy of the heat exchange module. And a method of operating a fusion system capable of simultaneously supplying power.
The method of claim 11,
The energy distribution step (S200)
When the energy request information does not exist and the fresh water request information is lower than a preset reference value,
Transmitting the electric energy produced by the energy production unit 100 to the energy storage system of the power consumption unit,
A method of operating a fusion system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that transmitting thermal energy produced by the energy generating unit to an evaporative module of the desalination unit.
The method according to any one of claims 12 to 15,
The energy distribution step (S200)
According to the determination by the control analysis step (S100), when the energy production amount information of the energy production unit is less than the energy consumption information or the energy request information of the desalination unit,
A convergence system capable of simultaneously supplying fresh water and electric power in connection with a condensing solar thermal complex system, characterized in that the electric energy stored in the energy storage system of the power consuming unit is supplied to the desalination unit 300 or the power system. Method of operation.

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