KR101544747B1 - Independent power generator based on the salinity gradient - Google Patents

Abstract

The present invention relates to an independent power generator based on a salinity gradient. The purpose of the present invention is to provide an independent power generator based on a salinity gradient, wherein power can be supplied to electric facilities such as relay stations and streetlamps in a remote place or the like, where power is not supplied, by supplying power to small-scale facilities using a pressure-retarded osmosis (PRO) or reverse electrodialysis (RED) method. For the purpose, the present invention comprises: a fresh water tank for storing fresh water supplied from a fresh water supply source; a salinity adjustment means for receiving the fresh water from the fresh water tank and adjusting the salinity of the fresh water to convert the fresh water into high-concentration saline water; a saline water tank for storing the high-concentration saline water having the salinity adjusted by the salinity adjustment means; a membrane module for converting the high-concentration saline water to high-flux brackish water via osmotic pressure caused by the supply of the fresh water and the high-concentration saline water stored in the fresh water tank and the saline water tank; a turbine for generating power by the high-pressure spray of the high-flux brackish water converted by the membrane module; a power control means for controlling the power generated by the rotation of the turbine; a brackish water recovery means for recovering the brackish water, which has been converted to low pressure after generating power in the process of passing the turbine, and supplying the brackish water to the salinity adjustment means; and a fresh water returning means for returning fresh water, which has not permeated in the osmotic process of the membrane module, to the fresh water tank.

Description

Independent power generator based on the salinity gradient.

The present invention relates to a salinity charger generating system, and more particularly, to a salinity charger generating system which is separated from an existing power grid and operated in a small-scale power source in a city or a metropolis where power supply is difficult, The present invention relates to a self-generating apparatus using a salinity difference capable of supplying electric power to a facility that can be used.

Generally, water and energy shortage problems are caused worldwide in recent years, and it is required to secure water resources and to research and develop new energy sources that are sustainable and have no carbon emission as a future energy source.

In order to solve the above-mentioned problems, researches on a technique for desalination of seawater and a method for recovering difference in salinity between seawater and fresh water as energy have been conducted. Various techniques such as reverse osmosis, evaporation, and positive osmosis have been studied for desalination of seawater, but reverse osmosis has been studied as a typical seawater desalination technique because of its high efficiency.

On the other hand, the reverse osmosis method as described above is advantageous in that the desalination efficiency is higher than other methods, but the concentrated sea water discharged during the process may contaminate the environment, which is problematic.

In addition, the power generation method using the difference in salinity between seawater and fresh water can secure a stable output compared to other renewable energy, and it can advantageously reduce the initial installation cost by utilizing the marine area in connection with the estuary or the seawall Research is being actively carried out.

The energy recovery technology using the difference of the concentration of seawater and fresh water as described above can be divided into osmotic pressure method and electrolytic (NaCl) dialysis method first proposed by Prof. Sidney Loeb of Israel in 1975. Currently, Research is underway at Statkraft, Inc. and the Sustainable Hydropower Technology Center (Wetsus) in the Netherlands.

On the other hand, salinity generation technology is a power generation technology that injects a pressurized high-concentration solution and a low-use solution into a module separated by a semi-permeable membrane, and rotates the turbine by an osseous phenomenon to produce electric power.

FIG. 1 is a block diagram of a pressure-retarded osmosis (PRO) process, which is an object technology to be a basis of a general salinity difference generation technique.

As shown in FIG. 1, the pressure osmosis delay technique uses fresh water as a low-concentration solution and seawater as a high-concentration solution. The pretreated fresh water is permeated into the seawater through the semi-permeable membrane by osmotic pressure, and the turbine is rotated by the hydraulic pressure formed by the increased flow rate to produce energy.

In the pressure osmosis delay technique as described above, optimum conditions are 15 atmospheric pressure for 3.5% seawater and 25 to 30 atmospheric pressure for 7% concentrated water, and half of the brine side pressure is effective for the fresh water side pressure. At this time, the problems to be solved for the commercialization of PRO process are improvement of power density per membrane area, decrease of membrane price and improvement of energy consumption rate.

On the other hand, the self-power generation technology according to the related art is a device that automatically supplies an emergency power source when a commercial power supply is out of order, thereby enabling operation of a main facility, and has mainly used fossil fuel as a diesel generator.

However, recently, new renewable energy has been proposed for reduction of carbon dioxide emission, and methods using sunlight and wind power have been proposed. However, due to low efficiency and danger, a large-scale installation site is required, There is a problem that it is not effective as an always-on power source due to a constraint depending on the environment.

On the other hand, self-generation using salinity difference can produce constant power irrespective of natural environment if salt water and fresh water can be reused. In a laboratory-scale PRO experiment, a power density higher than 5 W / m ² can be obtained when a high concentration solution higher than seawater is used. Recently, Fane et al. In Singapore have found a power density of 10.6 W / m ² .

1. Korean Registered Patent No. 10-1067422 (issued on September 27, 2011) 2. Republic of Korea Open Patent No. 2012-0007133 (2012.01.20) 3. Korean Patent Laid-Open No. 2013-0003765 (Released on March 31, 2013) 4. Korean Registered Patent No. 10-1328433 (issued on November 14, 2013)

SUMMARY OF THE INVENTION The present invention has been conceived to solve all the problems of the prior art, and it is an object of the present invention to provide a power supply such as a repeater, a streetlight, etc., The purpose of the present invention is to provide a power generation system that can supply power to a facility.

Another object of the present invention is to provide salinity control means for controlling the concentration of saline water in the power generation system so as to produce a constant power with high efficiency, The present invention aims at providing a semi-permanent power generation by constructing a fresh water recovery means.

It is another object of the present invention to provide a battery for efficiently managing developed electric power, which can cope with an emergency situation by constituting a power control means for controlling charging / discharging of a battery and power supply to a load It has its purpose.

The present invention configured to achieve the above-described object is as follows. That is, the technology according to the first embodiment of the salinity car power generation system according to the present invention is characterized in that fresh water supplied from a fresh water supply source is stored in a fresh water tank; A salinity control means for receiving fresh water from a fresh water tank and adjusting the salinity of the fresh water to a high concentration of salt water; A brine tank for storing high-concentration brine having a controlled salinity through salinity control means; A membrane module for converting a high concentration brine into a high flow rate nodule through osmotic pressure according to supply of fresh water and high concentration brine stored in a fresh water tank and a brine tank; A turbine producing power by high-pressure injection of the high flow rate naphtha converted by the membrane module; Power control means for controlling power produced by rotation of the turbine; A water recovery means for generating electric power in the process of passing through the turbine, for recovering the navy water converted into low pressure and supplying it to the salinity control means; And fresh water conveying means for conveying the untransmitted fresh water to the fresh water tank in the osmotic pressure process of the membrane module.

The salinity control means constituting the present invention according to the first embodiment described above includes: a stirring tank in which fresh water and nose water supplied from the fresh water tank and the nose water collecting means are stored; A solute storage tank for filling and storing a solute such as sodium chloride (NaCl) for controlling salinity, which is fed into a stirring tank; A solute supply control valve provided on the solute supply line connected to the stirring tank from the solute reservoir to regulate the supply amount of the solute through opening and closing; And a stirrer installed inside the stirring tank for mixing the supplied fresh water and the supplied solids into the nacelle while dissolving the solute.

A crusher for crushing sodium chloride (NaCl) installed inside the solute reservoir constituting the saltiness controlling means of the present invention according to the first embodiment described above may be further constructed.

An electrical conductivity meter for measuring the concentration of the saline solution to be adjusted in the stirring tank constituting the salinity adjusting means of the present invention according to the first embodiment described above may be further constructed.

A water level sensor for measuring the water level of the salt water in the agitating tank constituting the salinity adjusting means of the present invention according to the first embodiment and adjusting the supply amount of the salt water supplied to the salt water tank may be further constructed.

A brine supply line is provided between the agitating tank and the brine tank constituting the salinity adjusting means according to the first embodiment of the present invention. The brine supply line is controlled by the level sensor to control the flow rate of the brine A brine flow control valve can be further constructed.

The power control means constituting the present invention according to the first embodiment of the present invention includes an inverter for converting a DC power source DC produced by the rotation of the turbine into an AC power source AC that requires a load, A battery for charging and storing power produced by the turbine; And a control circuit for connecting the electric power produced by the rotation of the turbine to the inverter or controlling the electric power upon charging the battery.

The power source converted into AC power by the inverter constituting the power control means according to the first embodiment described above can be used as the AC power source AC necessary for the salinity difference generation.

The battery constituting the power control means according to the first embodiment described above can be configured as a storage type lithium ion battery.

The control circuit constituting the power control means according to the first embodiment described above can be configured to connect the DC power source (DC) of the battery to the inverter and control the conversion to the AC power source (AC).

The control circuit constituting the power control means according to the first embodiment described above can be configured to connect and control the DC power source (DC) of the battery directly to the load.

The control circuit constituting the power control means according to the first embodiment described above can be configured to connect and control the AC power source AC converted by the inverter to the load.

The control circuit constituting the power control means according to the first embodiment described above can be configured to control various matters according to salinity difference generation.

The present invention relates to a water recovery system comprising: a water recovery tank for generating electric power in a process of passing through a turbine and recovering a low water pressure converted water; A ninth water supply line for supplying nose water stored in the nose water collection tank by means of salinity control means; A nursery supply pump installed on the nursery supply line for supplying the nursing water stored in the nursery return tank to the brine control means; And a ninth water supply control valve provided on the ninth water supply line to adjust the supply amount of the ninth water supplied by the ninth water supply pump through opening and closing.

The fresh water conveying means constituting the present invention according to the first embodiment described above includes a fresh water conveyance line connected from the fresh water side of the membrane module to the fresh water tank; And a fresh water return pump installed on the fresh water return line for forcibly conveying the fresh water from the fresh water side of the membrane module to the fresh water tank.

In the construction of the present invention according to the first embodiment described above, a fresh water flow control valve is provided on the fresh water inflow line connected from the fresh water supply source to the fresh water tank to open / close the fresh water according to the amount of fresh water stored in the fresh water tank, Lt; / RTI >

In the structure of the present invention according to the first embodiment described above, on the fresh water supply line connected to the membrane module from the fresh water tank, the fresh water supply pump for supplying the fresh water of the fresh water tank to the membrane module and the fresh water supply pump A fresh water quantity control valve may be further constructed.

In the construction of the present invention according to the first embodiment described above, on the brine supply line connected to the membrane module from the brine tank, the quantity of brine supplied by the brine supply pump and the brine supply pump for supplying the brine of the brine tank to the membrane module A brine quantity control valve may be further constructed.

The structure of the present invention according to the first embodiment described above may further comprise fresh water recovery means for recovering fresh water from the nursery water recovered by the nursery recovery means.

The fresh water collecting means constituting the present invention according to the first embodiment described above includes an evaporation chamber for supplying nose water from the nose water collecting means and heating the nose water to a boiling point; And a condenser for condensing the vapor evaporated through the heating of the evaporation chamber to allow the condensed fresh water to flow into the fresh water tank.

The heating of the evaporation chamber constituting the fresh water collecting means according to the first embodiment may be performed through a heat ray or a solar collector.

The heating of the evaporation chamber constituting the fresh water recovery means according to the first embodiment is preferentially performed through the solar heat collector and when the boiling point of the solar collector is not reached due to environmental factors, the evaporation chamber is heated through the heat line Lt; / RTI >

The evaporation chamber constituting the fresh water recovery means according to the first embodiment may be provided with a temperature sensor so that the heating temperature can be controlled by the temperature sensor.

A noble water level sensor provided in the water collection means constituting the present invention according to the first embodiment and sensing the water level of the noble water may be further constructed.

A water level control valve for discharging the water level to the outside is further provided at one side of the water level collecting means constituting the present invention according to the first embodiment of the present invention. When the water level of the water level is higher than the maximum water level, And when the water level of the nose reaches the minimum water level, the supply to the evaporation chamber is stopped and the nose water is recovered.

The salinity water power generation system according to the second embodiment, which is another feature of the present invention, includes a fresh water tank in which fresh water supplied from a fresh water supply source is stored; A salinity control means for receiving fresh water from a fresh water tank and adjusting the salinity of the fresh water to a high concentration of salt water; A brine tank for storing high-concentration brine having a controlled salinity through salinity control means; A membrane module for converting a high concentration brine into a high flow rate nodule through osmotic pressure according to supply of fresh water and high concentration brine stored in a fresh water tank and a brine tank; A turbine producing power by high-pressure injection of the high flow rate naphtha converted by the membrane module; Power control means for controlling power produced by rotation of the turbine; A fresh water conveying means for conveying the untransmitted fresh water to the fresh water tank in an osmotic pressure process of the membrane module; A water recovery tank for generating electric power in the process of passing through the turbine and recovering the nodules converted to low pressure; And a brine recovery means for converting the nursery water stored in the nursery recovery tank into high-concentration brine through osmotic pressure using an induction solution.

The salinity control means constituting the salinity electric power generation system according to the second embodiment described above includes a stirring tank in which fresh water and high concentration brine supplied from the fresh water tank and the brine recovery means are stored; A solute storage tank for filling and storing a solute such as sodium chloride (NaCl) for controlling salinity, which is fed into a stirring tank; A solute supply control valve provided on the solute supply line connected to the stirring tank from the solute reservoir to regulate the supply amount of the solute through opening and closing; And a stirrer installed in the inside of the stirring tank to mix the supplied fresh water and the high-concentration brine while dissolving the solute.

A crusher for crushing sodium chloride (NaCl) installed inside the solute storage tank constituting the salinity-intensive power generation system according to the second embodiment described above may be further constructed.

An electrical conductivity meter for measuring the concentration of the saline solution to be adjusted in the stirring tank constituting the salinity electric power generating system according to the second embodiment described above can be further constructed.

A water level sensor for measuring the water level of the salt water in the stirring tank constituting the salinity water power generation system according to the second embodiment and adjusting the supply amount of the salt water supplied to the salt water tank may be further constructed.

A salt water supply line is provided between the agitation tank and the salt water tank constituting the salinity water power generation system according to the second embodiment described above. On the salt water supply line, a salt water A flow control valve may be further configured.

The power control means constituting the salinity electric power generation system according to the second embodiment described above includes an inverter (not shown) for converting the DC power produced by the rotation of the turbine into an AC power source (AC) ; A battery for charging and storing power produced by the turbine; And a control circuit for connecting the electric power produced by the rotation of the turbine to the inverter or controlling the electric power upon charging the battery.

The power source converted into the alternating-current power (AC) by the inverter constituting the salinity-intensive power generation system according to the second embodiment described above can be used as the alternating-current power source (AC) necessary for the salinity difference generation.

The battery constituting the salinity charger power generation system according to the second embodiment described above can be configured as a storage type lithium ion battery.

The control circuit constituting the salinity charger power generation system according to the second embodiment may be configured to connect the DC power source (DC) of the battery to the inverter to control the conversion to the AC power source (AC).

The control circuit constituting the salinity charger power generation system according to the second embodiment may be configured to directly control the DC power source (DC) of the battery by directly connecting to the load.

The control circuit constituting the salinity charger power generation system according to the second embodiment may be configured to connect and control the AC power source AC converted by the inverter to the load.

The control circuit constituting the salinity charger power generation system according to the second embodiment may be configured to control various matters according to salinity difference generation.

In the freshwater inflow line connected to the fresh water supply source from the fresh water supply source constituting the salinity generating system according to the second embodiment described above, the fresh water is opened and closed according to the quantity of the fresh water stored in the fresh water tank, A flow control valve may be further configured.

On the fresh water supply line connected to the membrane module from the fresh water tank constituting the salinity water power generation system according to the second embodiment, a fresh water supply pump for supplying the fresh water of the fresh water tank to the membrane module and a fresh water supply pump for supplying fresh water A fresh water quantity control valve for controlling the quantity of water may be further constructed.

On the salt water supply line connected to the membrane module from the salt water tank constituting the salinity water power generation system according to the second embodiment described above, there are provided a salt water supply pump for supplying the salt water of the salt water tank to the membrane module, A brine volume control valve for controlling the quantity of water may be further configured.

The saltwater recovery means constituting the salinity water power generation system according to the second embodiment of the present invention includes a forward osmosis membrane module for converting a nod into a high concentration brine through an osmotic action due to the introduction of nodal water and an induction solution in the nodule recovery tank; A high-concentration brine supply line for supplying the high-concentration brine converted in the osmotic process of the osmosis membrane module to the salt-adjusting means; And an induction solution supply means for supplying the induction solution to the positive osmosis membrane module.

The induction solution supply means constituting the salinity electric power generation system according to the second embodiment described above includes an induction solution storage tank for supplying an induction solution to the positive osmosis membrane module; An induction solution supply line connecting the induction solution storage tank and the positive osmosis membrane module; An induction solution supply pump installed on the induction solution supply line for forcibly supplying the induction solution of the induction solution storage tank to the positive osmosis membrane module; And an induction solution supply amount regulating valve which is provided on the induction solution supply pump and regulates the supply amount of the induction solution supplied through opening and closing.

An induction solution inflow amount control valve for controlling the inflow amount of the induction solution introduced from the induction solution supply source may be further provided at one side of the induction solution storage tank constituting the salinity electric power generation system according to the second embodiment.

The salinity intensifier according to the second embodiment is installed on the nose inflow line for allowing the introduction of the nose water from the nose recovery tank constituting the power generation system into the osmosis membrane module, And a nose inflow amount control valve installed on the nose inflow line for controlling the inflow amount of the nose through opening and closing.

The induction solution constituting the salinity electric power generating system according to the second embodiment may be any one or a mixture of calcium nitrate, diammonium hydrogen phosphate and potassium chloride.

The diluted induction solution may be used as a fertilizer in the course of passing the osmosis membrane module according to the second embodiment through the osmosis membrane module constituting the power generation system.

The fresh water conveying means constituting the salinity-anchored power generation system according to the second embodiment described above includes a fresh water conveyance line connected from the fresh water side of the membrane module to the fresh water tank; And a fresh water return pump installed on the fresh water return line for forcibly conveying the fresh water from the fresh water side of the membrane module to the fresh water tank.

According to the technique of the present invention, power can be supplied through self-power generation at all times using the difference in salinity of fresh water and salt water without external power supply.

According to the technique of the present invention, the concentration of the saline solution can be kept constant at a high concentration to maximize the power density of the salinity gradient power generation using the semi-permeable membrane and obtain stable output.

In addition, the technique according to the present invention can store surplus power in the battery through the power control means, and can adjust the power generation amount according to the demand of the load.

1 is a block diagram of a pressure delay osmosis system according to the prior art.
FIG. 2 is a schematic view showing a first embodiment of a salinity charger generating system according to the technique of the present invention; FIG.
3 is a schematic view showing salinity control means of a salinity-less power generation system according to the technique of the present invention.
FIG. 4 is a schematic view showing power control means of a salinity-less power generation system according to the technique of the present invention; FIG.
FIG. 5 is a schematic view showing fresh water recovery means of a salinity-less power generation system according to the technique of the present invention; FIG.
6 is a configuration diagram showing a second embodiment of a salinity charger power generation system according to the technique of the present invention.
FIG. 7 is a view showing a salinity adjusting means according to FIG. 6; FIG.
8 is a configuration diagram showing power control means according to Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a salinity-differentiated power generation system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a view showing a first embodiment of a salinity charger generating system according to the technique of the present invention, FIG. 3 is a diagram showing a salinity adjusting means of a salinity charger generating system according to the technique of the present invention, FIG. 5 is a configuration diagram showing a fresh water recovery means of a salinity-less power generation system according to the technique of the present invention.

As shown in FIGS. 2 to 5, the salinity-type power generation system 100 according to the first embodiment of the present invention is capable of producing power using the salinity difference, A salinity control unit 120 for receiving fresh water from the fresh water tank 110 and controlling the salinity of the fresh water to a high concentration of saline water, a salinity control unit 120 A brine tank 130 for storing a saline-rich high-concentration salt water through an osmotic pressure regulator 130, and a high-concentration brine via an osmotic pressure according to supply of fresh water and high-concentration brine stored in a fresh water tank 110 and a brine tank 130, A turbine 150 that produces power by high pressure injection of the high flow rate naphtha converted by the membrane module 140, a turbine 150 that generates power by controlling the power produced by the rotation of the turbine 150, The control means 160, The water recovery means 170 for generating electricity in the process of passing through the bin 150 and recovering the nodules converted to the low pressure and supplying the recovered nodules to the saltiness regulating means 120 and the fresh water which is not permeated during the osmotic process of the membrane module 140 And a fresh water conveying means 180 for conveying the fresh water to the fresh water tank 110.

In the salinity water power generation system 100 according to the first embodiment of the present invention, fresh water is introduced from an external fresh water supply source and stored in the fresh water tank 110, and then the fresh water stored in the fresh water tank 110 And supplies a portion thereof to the salinity control means 120. [ At this time, the sea water recovered through the sea water recovery means 170 is also supplied to the saltiness control means 120.

Next, when the fresh water and the noodle are introduced from the fresh water tank 110 and the salinity adjusting means 120 as described above, the salinity adjusting means 120 injects sodium chloride (NaCl), dissolves it by stirring, Concentration salt water of the set value and supplies the salt water to the salt water tank 130. [

Meanwhile, the membrane module 140 constituting the present invention receives fresh water and high-concentration brine from the fresh water tank 110 and the salt water tank 130. That is, when the fresh water in the fresh water tank 110 is supplied to the membrane module 140 and the highly concentrated brine in the salt water tank 130 is supplied to the membrane module 140, the high concentration brine is changed to the high flow rate noodle by the osmotic pressure.

In other words, when the concentrated brine of the salt water tank 130 and the fresh water of the fresh water tank 110 are received in the semi-permeable membrane 142 of the membrane module 140 as described above, by the osmotic action of the semi-permeable membrane 142 As a part of the fresh water is permeated to the high concentration salt water side, the high concentration salt water is converted into the high water level water.

The fresh water that has passed through the semi-permeable membrane 142 of the membrane module 140 is conveyed to the fresh water tank 110 through the fresh water conveyance means 180 and the semi-permeable membrane 142 of the membrane module 140, The high-pressure nadir passes through the nozzle at a high pressure to rotate the turbine 150 to produce electric power.

In addition, as described above, the power produced by rotating the turbine 150 is supplied to the power control means 160, and the power control means 160 stores the supplied power or directly connects to the load 10.

As described above, the nose passing through the turbine 150 is changed to a low pressure and is collected and stored in the nose recovery means 170. Thus, the nose stored in the nose recovery means 170 is supplied to the salinity control means 120 or a part thereof is discharged to the outside.

On the other hand, the flow rate of the water recovered by the water collection means 170 is controlled according to the throughput of the salt adjustment means 120, as described above.

Each component constituting the salinity power generation system 100 according to the first embodiment of the present invention will now be described in more detail. First, the fresh water tank 110 constituting the first embodiment of the present invention is for storing fresh water, and fresh water supplied from a fresh water supply source is stored in the fresh water tank 110 as shown in FIG.

On the other hand, a fresh water inflow line 112 is connected to one side of the fresh water tank 110 as described above, and the fresh water inflow line 112 is opened and closed according to the amount of fresh water stored in the fresh water tank 110 And a fresh water flow control valve 112a for controlling the fresh water flow rate in the fresh water tank 110 so that fresh water can be flowed and blocked.

The fresh water supplied from the fresh water tank 110 to the salinity adjusting means 120 is supplied to the fresh water line 114 and the fresh water line 114 connecting the fresh water tank 110 and the salt- The fresh water is supplied by the supply pump 114a and the regulating valve 114b provided in the water supply system. At this time, the flow rate of the fresh water supplied from the fresh water tank 110 to the salinity adjusting means 120 is controlled by the level detecting sensor 127 constituting the salinity adjusting means 120.

2 and 3, the salinity adjusting means 120 may adjust the salinity of the fresh water tank 110, as shown in FIGS. 2 and 3, The salinity is adjusted to convert the fresh water to a high concentration of saline water.

3, the salinity adjusting means 120 includes a stirring tank 121 for storing fresh water and nursery water supplied from the fresh water tank 110 and the nursing water collecting means 170, a stirring tank 121, A solute storage tank 122 filled with a solute such as sodium chloride for controlling the saltiness (NaCl) introduced into the tank 121 and a solute supply line 123a connected to the stirring tank 121 from the solute reservoir 122, A solute supply control valve 123 for controlling the supply amount, and an agitator 124 installed inside the agitating tank 121 to mix the supplied solids into the fresh water and the nasal water while dissolving the solute.

The salinity control means 120 includes a crusher 125 installed in the solute reservoir 122 for crushing sodium chloride (NaCl) stored in the solute reservoir 122, a concentration of salt water controlled in the stirring tank 121, A water level sensor 127 for measuring the level of the salt water in the stirring tank 121 and controlling the supply amount of the salt water to be supplied to the salt water tank 130, The brine outlet control valve 128a is installed on the brine supply line 128 formed between the tanks 130 and controlled by the water level sensor 127 to control the flow rate of the brine.

The salinity control means 120 configured as described above is a means for controlling the salinity of the fresh water tank 110 flowing into the stirring tank 121 and the brine of the tank water recovery tank 170, The concentration of salt water is measured through the meter (126). At this time, if the measured concentration of the saline solution does not reach the set value, sodium chloride (NaCl) for controlling the salinity, which is stored in the solute storage tank 122, is supplied to the stirring tank 121 through the solute supply control valve 123.

As described above, when a certain amount of sodium chloride (NaCl) for controlling the saltiness is supplied to the inside of the stirring tank 121, the stirrer 124 is stirred by driving to dissolve sodium chloride (NaCl) as a solute in the brine in the stirring tank 121 . The high concentration brine in which the concentration of sodium chloride (NaCl) is dissolved is discharged to the brine tank 130 through the brine discharge control valve 128a.

In other words, the salinity adjusting means 120 according to the present invention adjusts the salinity by adding sodium chloride (NaCl) stored in the solute storage tank 122 to the stirring tank 121 and stirring the same. At this time, the brine concentration in the stirring tank 121 is measured by the electrical conductivity meter 126. When the measured brine concentration is lower than the set value, sodium chloride in the solute reservoir 122 is supplied to adjust the concentration of the brine to a set value .

As described above, NaCl stored in the solute reservoir 122 is pulverized through the pulverizer 125, and the amount of NaCl is adjusted through the solute supply control valve 123 to be introduced into the agitation tank 121.

The stirrer 124 constituting the salinity adjusting means 120 as described above is allowed to flow through the structure of the electric motor and the impeller so that the sodium chloride (NaCl) can be dissolved smoothly in the salt water.

As described above, when the concentration of the high concentration brine is reached through the dissolution of sodium chloride (NaCl) in the brine in the stirring tank 121, the high concentration brine is discharged by the brine discharge control valve 128a according to the measured level of the brine tank 130 And is supplied to the salt water tank 130 through the control.

On the other hand, the stirring tank 121 constituting the salinity adjusting means 120 as described above is basically supplied with nose water from the nose water collecting means 170, and the insufficient amount replenishes the fresh water from the fresh water tank 110 . At this time, the water level of the stirring tank 121 is controlled by the water level sensor 127.

2, the saltwater tank 130 is configured to store high-concentration brine having a set value. The saltwater tank 130 is connected to the salinity tank 130 through a salinity adjusting means 120, High concentration brine will be supplied and stored.

The brine tank 130 configured as described above is supplied with and stores the high-concentration brine whose concentration is adjusted by the salt-adjusting means 120 through the brine supply line 128 connected to the stirring tank 121.

Next, the membrane module 140 constituting the present invention generates a high-flow rate of water according to the osmotic pressure of the fresh water and the salt water through the semi-permeable membrane 142, which is supplied to the membrane module 140, As shown in the figure, the brine tank 110 and the brine tank 130 convert the high-concentration brine into a high-flow rate nodule through the osmotic pressure caused by the supply of the fresh water and the high-concentration brine.

The fresh water supplied to the membrane module 140 as described above is formed on the fresh water supply line 116 connected to the membrane module 140 from the fresh water tank 110 to supply the fresh water of the fresh water tank 110 to the membrane module 140. [ And a fresh water quantity control valve 116b for controlling the quantity of fresh water supplied by the fresh water supply pump 116a.

The high concentration brine supplied to the membrane module 140 as described above is formed on the brine supply line 132 connected to the membrane module 140 from the brine tank 130 to supply the high concentration brine of the brine tank 130 And is supplied through a brine supply pump 134 supplying the membrane module 140 and a brine quantity control valve 136 regulating the quantity of brine supplied by the brine supply pump 134.

On the other hand, when fresh water is supplied from the fresh water tank 110 to the semipermeable membrane 142 of the membrane module 140 and high-concentration saline water is supplied from the salt water tank 110 to the semipermeable membrane 142, So that the fresh water permeates toward the high concentration brine. As a result, the high-concentration brine is changed to a high-flow nodule.

Next, the turbine 150 constituting the present invention is for producing electric power, and this turbine 150 is driven by the high-pressure injection of the high flow rate radar converted by the membrane module 140 as shown in FIG. 2 And is rotated to produce electric power.

In other words, as described above, fresh water and high concentration brine are received in the semi-permeable membrane 142 of the membrane module 140, and a high flow rate nodule generated as osmotic pressure permeates some fresh water toward the high concentration brine, The turbine 150 is rotated in a process of being sprayed at a high pressure so that electric power can be produced.

As described above, when the turbine 150 is rotated in the course of jetting the high-purity water through the nozzle at high pressure to produce electric power, the produced electric power is supplied to the electric power control means 160, The high-pressure nod is turned into a low pressure and is recovered to the nodule recovery means 170. That is, when the high concentration brine is converted to the high flow rate by the osmotic pressure, the high flow rate nose is sprayed to the turbine 150 at a high pressure to produce electric power.

On the other hand, as described above, the high pressure and high flow rate nodules having passed through the turbine 150 are converted to low pressure and recovered through the nodule recovery means 170. Some of the low pressure nodules collected by the nodule recovery means 170 are supplied to the salt adjustment means 120 and some are discharged to the outside.

Next, the power control means 160 constituting the present invention is for controlling the produced power, and this power control means 160 is controlled by the rotation of the turbine 150 as shown in FIGS. 2 and 4 And controls the produced electric power.

The power control unit 160 includes an inverter 162 for converting the DC power produced by the rotation of the turbine 150 into an AC power required by the load 10, A battery 164 for charging and storing the electric power produced by the turbine 150 and a control for connecting the electric power produced by the rotation of the turbine 150 to the inverter 162 or controlling the electric power upon charging the battery 164 Circuit 500 shown in FIG.

On the other hand, the power source converted into the alternating current power (AC) by the inverter 162 constituting the power control means 160 as described above can be used as the alternating current power source (AC) necessary for the salinity difference generation. The battery 164 is constructed of a storage type lithium ion battery.

The control circuit 500 constituting the power control means 160 controls the conversion of the AC power source AC by connecting the DC power source DC of the battery 164 to the inverter 162 , The control circuit 500 controls the DC power source DC of the battery 164 to be directly connected to the load 10 or when the AC power source AC converted by the inverter 162 is connected to the load 10 do.

In addition, the control circuit 500 constituting the power control unit 160 as described above controls all matters related to salinity difference generation.

Next, the water-recovery means 170 constituting the present invention is for recovering and storing the low-pressure water that has passed through the turbine 150, and this water-recovery means 170 is constructed as shown in FIGS. 2 and 5 In the process of passing through the turbine (150), the low-pressure converted water is introduced and stored, and a part of the water is supplied to the salt control means (120).

In other words, as described above, the high pressure nadir produces electricity in the course of passing through the turbine 150, and then is converted to low pressure nadir. The low-pressure converted nodules are recovered by the nodule recovery means 170 and supplied to the saltiness regulating means 120.

2 and 3, the water recovery means 170 includes a water recovery tank 172 for generating electric power in the process of passing through the turbine 150 and recovering the low water pressure, A puddle water supply line 174 for supplying the puddle water stored in the recovery tank 172 to the salinity regulating means 120 and a puddle water storage tank 172 provided on the puddle water supply line 174, And a water supply control valve 178 which is provided on the water supply line 174 for supplying water to the water supply control valve 120 and regulates the water supply amount supplied by the water supply pump 176 through opening / .

On the other hand, the flow rate of the water recovered to the water recovery tank 172 in the structure of the water recovery means 170 as described above is changed according to the throughput of the salinity adjustment means 120 by the water supply pump 176 and the water supply control valve 178). At this time, the nursing water discharged to the outside from the nursing water recovery tank 172 is discharged to the outside through the nursing water level control valve 172a provided on one side of the nursing water recovery tank 172.

The fresh water conveying means 180 constituting the present invention is for conveying the untransmitted fresh water to the fresh water tank 110 during the osmotic pressure process of the membrane module 140, A fresh water conveyance line 182 and a fresh water conveyance line 182 connected to the fresh water tank 110 from the fresh water side of the membrane module 140 as shown in FIG. And a fresh water conveying pump 184 for forcibly conveying the fresh water to the fresh water conveying pipe 110.

The fresh water conveying means 180 constructed as described above is constructed so that the fresh water side fresh water which is not permeated to the high concentration salt water side during the osmotic pressure process by the semi-permeable membrane 142 of the fresh water supplied to the membrane module 140 and the high- The operation of opening the fresh water flow control valve 112a for flowing the fresh water from the fresh water supply source into the fresh water tank 110 can be reduced by reducing the opening and closing operation of the fresh water flow control valve 112a.

Meanwhile, the salinity water power generation system 100 according to the first embodiment of the present invention may further include a fresh water recovery means 190 for recovering fresh water from the nursery water stored in the nursery recovery tank 172. The fresh water recovering means 190 includes a vaporizing chamber 192 for receiving the nursery water from the nursing water recovery tank 172 and heating the nursing water to a boiling point and condensing the evaporated vapor through the heating of the evaporation chamber 192, And a condenser 194 for allowing the water to flow into the fresh water tank 110.

The fresh water recovery means 190 configured as described above generates steam through the supply of the nursery water from the nursery recovery tank 172 and heating the nursery water to the boiling point and condenses the steam through the condenser 194, So that fresh water can be recovered by allowing the condensed fresh water to flow into the fresh water tank 110. At this time, when the amount of the fresh water through the fresh water collecting means 190 is insufficient, fresh water can be supplied to the fresh water tank 110 through the fresh water supply source, thereby compensating for the shortage of fresh water.

In the structure of the fresh water recovery means 190 as described above, the evaporation chamber 192 is heated through the heat ray 196a or the solar collector 196b. At this time, the heating of the evaporation chamber 192 is preferentially performed through the solar collector 196b, but when the boiling point of the solar collector 196b is not reached due to environmental factors, the evaporation chamber 192 is heated through the heating wire 196a .

In addition, the evaporation chamber 192 constituting the fresh water recovering means 190 as described above is further provided with a temperature sensing sensor 198a so that the heating temperature can be controlled by the temperature sensing sensor 198a. The temperature sensor 198a controls the heating temperature of the evaporation chamber 192.

In the structure according to the present invention, a radiant water level sensor 172b for sensing the radiant water level is installed in the inside of the radiant water recovery tank 172. This radiant water level sensor 172b senses the radiant water level in the radiant water recovery tank 172 so that the radiant water level control valve 172a to be described later can be controlled.

The radiant water level control valve 172a is configured to discharge the radiant water to the outside on one side of the radiant water recovery tank 172. The radiant water level control valve 172a is disposed inside the radiant air recovery tank 172 The water level control valve 172a is opened to discharge the water to the outside, and when the water level of the water level reaches the minimum water level, the supply of the water to the evaporation chamber 192 is stopped and the water level is recovered .

Further, the fresh water tank 110 constituting the technique according to the present invention is further provided with a fresh water level detection sensor 110a for detecting the level of the fresh water stored therein and controlling the inflow of fresh water. The fresh water level sensor 110a senses the level of the fresh water in the fresh water tank 110 and transmits the sensed signal to the control circuit 500 so that the fresh water level control valve 112a is opened / So that fresh water can be replenished.

FIG. 6 is a configuration diagram showing a second embodiment of the salinity charger generating system according to the technique of the present invention. FIG. 7 is a view showing a salinity adjusting means according to FIG. 6. FIG. Fig.

6 to 8 show the salinity-differentiated power generation system 200 according to the second embodiment of the present invention, and the salinity difference generation process is the same as that described in Figs. 2 to 5.

However, the technique according to the second embodiment of the present invention uses a chemical fertilizer Fertilizer Driven Forward Osmosis method as a method for recovering highly concentrated brine from the nursery water of the nursery recovery tank 270.

In other words, the salinity-type power generation system 200 according to the second embodiment of the present invention is configured such that the solution of the noble water of the nacelle recovery tank 270 and the solution of the inductive solution storage tank 283a is supplied to the positive osmosis membrane module 281 Water is supplied to the forward osmosis membrane (FO) by the osmotic pressure so that the water in the nursery water is transmitted to the induction solution side, and the noble water passing through the osmosis membrane 281a is converted into the high concentration brine, ). At this time, the induction solution passing through the osmosis membrane 281a is replaced with a diluted Fertilizer Solution and used as fertilizer.

As shown in FIGS. 6 to 8, the salinity electric power generation system 200 according to the second embodiment of the present invention includes a fresh water tank 210 in which fresh water supplied from a fresh water supply source is stored, A salt water tank 230 for storing high-concentration saline water having a controlled salinity through a salinity control means 220, a fresh water tank 210 for storing saline water, A membrane module 240 for converting high-concentration brine into a high-concentration nodule through osmotic pressure according to the supply of fresh water and high-concentration brine stored in the tank 230, a high- A power control means 260 for controlling the electric power produced by the rotation of the turbine 250, a turbine 250 for generating electric power, a turbine 250 for generating electric power in the process of passing through the turbine 250, A collection tank 270 for recovering water, Salt water recovery means 280 for converting the nursery water stored in the nursery recovery tank 270 into osmotic pressure through the osmotic pressure using the induction solution and fresh water not permeated in the osmotic pressure process of the membrane module 240 to the fresh water tank 210 And a fresh water conveying means (290) for conveying the fresh water.

The salinity-power generation system 200 according to the second embodiment of the present invention configured as described above receives fresh water from an external fresh water supply source, stores the fresh water in the fresh water tank 210, A portion of which is supplied to the salinity control means 220. At this time, the nodules collected through the nodule recovery tank 270 are recovered through the saline recovery means 280 and supplied to the salinity control means 220.

Meanwhile, as described above, the inductive solution passing through the osmosis membrane module 281 of the saline solution recovery means 280 during the recovery of the high-concentration saline solution through the saline solution recovery means 280 is diluted with a diluted Fertilizer Solution, . At this time, Diluted Fertilizer Solution is used as fertilizer.

Next, when fresh water and noodle are introduced from the fresh water tank 210 and the salinity adjusting means 220 as described above, the salinity adjusting means 220 injects sodium chloride (NaCl) Concentration salt water of the set value to supply the salt water to the salt water tank 230. [

Meanwhile, the membrane module 240 constituting the present invention receives fresh water and high-concentration brine from the fresh water tank 210 and the salt water tank 230. That is, when the fresh water in the fresh water tank 210 is supplied to the membrane module 240, and the highly concentrated brine in the salt water tank 230 is supplied to the membrane module 240, the high concentration brine is converted into the high-

In other words, when the concentrated brine of the salt water tank 230 and the fresh water of the fresh water tank 210 are received in the semi-permeable membrane 242 of the membrane module 240 as described above, by the osmotic action of the semi-permeable membrane 242 As a part of the fresh water is permeated to the high concentration salt water side, the high concentration salt water is converted into the high water level water.

The fresh water that has passed through the semi-permeable membrane 242 of the membrane module 240 is conveyed to the fresh water tank 210 through the fresh water conveyance means 290 and the semi-permeable membrane 242 of the membrane module 240, And the turbine 250 is rotated to generate power by injecting the high-pressure noxious gas through the nozzle.

Further, as described above, the electric power produced by rotating the turbine 250 is supplied to the electric power control means 260, and the electric power control means 260 charges the supplied electric power or directly connects to the load 20.

As described above, the nose passing through the turbine 250 is changed to a low pressure and is collected and stored in the water recovery tank 270. The nacre stored in the nacre recovery tank 270 is recovered through the saline recovery means 280 and supplied to the salinity control means 220.

The constituent elements of the salinity electric power generation system 200 according to the second embodiment of the present invention will now be described in more detail. First, the fresh water tank 210 constituting the second embodiment of the present invention is for storing fresh water. In the fresh water tank 210, as shown in FIGS. 6 and 7, fresh water supplied from a fresh water supply source is stored .

On the other hand, a fresh water inflow line 212 is connected to one side of the fresh water tank 210 as described above, and the fresh water inflow line 212 is opened and closed according to the amount of fresh water stored in the fresh water tank 210 And a fresh water flow control valve 212a for controlling the fresh water flow rate in the fresh water tank 210 so that fresh water can be flown and shut off.

The fresh water supplied from the fresh water tank 210 to the salinity adjusting means 220 is passed through the fresh water line 214 connecting the fresh water tank 210 and the salinity adjusting means 220, The fresh water is supplied by the supply pump 214a and the regulating valve 214b provided in the water supply pipe 214a. At this time, the flow rate of the fresh water supplied from the fresh water tank 210 to the salinity adjusting means 220 is controlled by the level detecting sensor 227 constituting the salinity adjusting means 220.

6 and 7, the salinity adjusting means 220 includes a fresh water tank 210 and a fresh water tank 210. The freshness adjusting means 220 is provided to adjust the freshness of the fresh water, The salinity is adjusted to convert the fresh water to a high concentration of saline water.

7, the salinity adjusting means 220 includes a stirring tank 221 in which fresh water and high-concentration brine supplied from the fresh water tank 210 and the saline-water collecting means 280 are stored, a stirring tank 221 A solute reservoir 222 for filling and storing a solute such as sodium chloride (NaCl) to be added to the solute reservoir 222, a solute supply line 223a connected to the agitation tank 221 from the solute reservoir 222, And a stirrer 224 installed inside the agitating tank 221 to mix the supplied fresh water with the supplied water while dissolving the solute in the water.

The salinity control means 220 includes a crusher 225 installed in the solute reservoir 222 for crushing sodium chloride (NaCl) stored in the crushing tank 221, A water level sensor 227 for measuring the level of salt water in the stirring tank 221 and controlling the amount of salt water supplied to the salt water tank 230, The brine outlet control valve 228a is installed on the brine supply line 228 between the tanks 230 and is controlled by the water level sensor 227 to control the flow rate of the brine.

The salinity degree adjusting means 220 may be configured as described above so that the fresh water of the fresh water tank 210 flowing into the stirring tank 221 and the high concentration brine supplied from the salt water recovery means 280, The brine is measured for the concentration of saline through an electrical conductivity meter (226). At this time, if the measured concentration of the saline solution does not reach the set value, sodium chloride (NaCl) for controlling salinity, which is stored in the solute storage tank 222, is supplied to the stirring tank 221 through the solute supply control valve 223.

As described above, when a certain amount of sodium chloride (NaCl) for controlling the saltiness is supplied to the inside of the stirring tank 221, the stirrer 224 agitates through driving to dissolve sodium chloride (NaCl) as a solute in the brine in the stirring tank 221 . The high concentration brine whose concentration is controlled by dissolving sodium chloride (NaCl) is discharged to the salt water tank 230 through the brine discharge control valve 228a.

In other words, the salinity control means 220 according to the present invention controls the salinity by adding sodium chloride (NaCl) stored in the solute storage tank 222 to the stirring tank 221 according to the concentration of the saline solution. At this time, the brine concentration in the stirring tank 221 is measured by the electric conductivity meter 226. When the measured brine concentration is lower than the set value, sodium chloride in the solute reservoir 222 is supplied to adjust the concentration of the brine to a set value .

Meanwhile, as described above, sodium chloride (NaCl) stored in the solute storage tank 222 is pulverized through the pulverizer 225 and is supplied to the agitation tank 221 while adjusting the amount of the supplied liquid through the solute supply control valve 223.

The stirrer 224 constituting the salinity adjusting means 220 as described above is allowed to flow through the structure of the electric motor and the impeller so that the sodium chloride (NaCl) can be dissolved smoothly in the salt water.

As described above, when the concentration of the high concentration brine is reached through the dissolution of sodium chloride (NaCl) in the brine in the stirring tank 221, the high concentration brine is discharged by the brine discharge control valve 228a in accordance with the measured level of the brine tank 230 And is supplied to the salt water tank 230 through the control.

Meanwhile, the stirring tank 221 constituting the salinity adjusting means 220 as described above is basically supplied with high-concentration brine from the saline-water collecting means 280, and supplies insufficient amount of fresh water from the fresh water tank 210 do. At this time, the water level of the stirring tank 221 is controlled by the water level sensor 227.

6 and 7, the salt water tank 230 constituting the present invention is for storing high-concentration brine having a set value. The salt water tank 230 is connected to the salinity tank 230 through a salinity adjusting means 220, And the high-concentration brine is regulated.

The brine tank 230 configured as described above is supplied with high-concentration brine whose concentration has been adjusted by the salt-adjusting means 220 through a brine supply line 228 connected to the agitation tank 221 and stored.

Next, the membrane module 240 constituting the present invention generates a high-flow rate water according to the osmotic pressure of the fresh water and the salt water through the semi-permeable membrane 242 to be supplied. As shown in the figure, the brine tank 210 and the brine tank 230 convert the high-concentration brine into a high-flow rate nodule through the osmotic pressure caused by the supply of the fresh water and the high-concentration brine.

The fresh water supplied to the membrane module 240 as described above is formed on the fresh water supply line 216 connected to the membrane module 240 from the fresh water tank 210 to supply the fresh water of the fresh water tank 210 to the membrane module 240. [ And a fresh water quantity control valve 216b for controlling the quantity of fresh water supplied by the fresh water supply pump 216a.

The high concentration brine supplied to the membrane module 240 as described above is formed on the brine supply line 232 connected to the membrane module 240 from the brine tank 230 to supply the high concentration brine of the brine tank 230 Is supplied through a brine supply pump 234 supplying the membrane module 240 and a brine quantity control valve 236 regulating the quantity of brine supplied by the brine supply pump 234.

On the other hand, when fresh water is supplied from the fresh water tank 210 to the semipermeable membrane 242 of the membrane module 240 as described above, while high concentration brine is supplied from the salt water tank 210 to the semipermeable membrane 242, So that the fresh water permeates toward the high concentration brine. As a result, the high-concentration brine is changed to a high-flow nodule.

Next, the turbine 250 constituting the present invention is for producing electric power, and this turbine 250 is driven by the high-pressure injection of the high flow rate radar converted by the membrane module 240 as shown in FIG. 6 And is rotated to produce electric power.

In other words, as described above, fresh water and high concentration brine are supplied to the semi-permeable membrane 242 of the membrane module 240, and a high flow rate nodule generated as osmotic pressure permeates some fresh water toward the high concentration brine, The turbine 250 is rotated in a process of being sprayed at a high pressure so that the electric power can be produced.

As described above, when the turbine 250 is rotated in the course of high pressure jetting through the nozzles, the generated power is supplied to the power control unit 260, and the turbine 250 The high-pressure naphtha passing through is changed to low pressure and is recovered to the naphtha recovery tank 270. That is, when the high concentration brine is converted to the high flow rate by the osmotic pressure, the high flow rate nadir is sprayed to the turbine 250 at high pressure to produce electric power.

On the other hand, as described above, the high-pressure, high-flow rate water that has passed through the turbine 250 is converted to low pressure and recovered through the water recovery tank 270. The low-pressure noble water recovered in the nacre recovery tank 270 is supplied to the saline recovery means 280 and a part of the nacre is discharged to the outside.

Next, the power control means 260 constituting the present invention is for controlling the produced power, and this power control means 260 is controlled by the rotation of the turbine 250 as shown in FIGS. 6 and 8 And controls the produced electric power.

The power control means 260 as described above includes an inverter 262 for converting the DC power produced by the rotation of the turbine 250 into an AC power source AC required by the load 20, A battery 264 for charging and storing the electric power produced by the turbine 250 and a control for connecting the electric power produced by the rotation of the turbine 250 to the inverter 262 or for controlling the electric power upon charging the battery 264 Circuit 500 shown in FIG.

On the other hand, the power source converted into the alternating-current power source AC by the inverter 262 constituting the power control means 260 as described above can be used as the alternating-current power source AC necessary for the salinity difference generation. The battery 264 is constituted by a storage type lithium ion battery.

The control circuit 500 constituting the power control means 260 described above controls the conversion of the AC power source AC to the AC power source DC by connecting the DC power source DC of the battery 264 to the inverter 262 , The control circuit 500 controls the DC power supply DC of the battery 264 either directly to the load 20 or when the AC power AC converted by the inverter 262 is connected to the load 20 do.

In addition, the control circuit 500 constituting the power control unit 260 as described above controls all matters related to salinity difference generation.

The water recovery tank 270 constituting the present invention is for recovering and storing the low pressure water that has passed through the turbine 250. This water recovery tank 270 is connected to the turbine 250 as shown in FIG. 250 to the saltwater recovery means 280. The saline water recovering means 280 receives the low-pressure converted nacreous water.

In other words, as described above, the high pressure nadir produces power in the course of passing through the turbine 250, and then is converted to low pressure nadir. The low-pressure converted nodal water is recovered by the nodal recovery tank 270 and supplied to the saline recovery means 280.

Next, the saline-water recovering means 280 constituting the present invention is for separating the high-concentration saline water from the saline recovered into the saline-water recovery tank 270. The saline-water recovering means 280, as shown in FIG. 6, A positive osmosis membrane module 281 for converting the nodal water into high concentration saline water through the osmotic action of the nodule of the recovery tank 270 and the influx of the induction solution, A high concentration brine supply line 282 supplied to the regulating means 220 and an induction solution supply means 283 for supplying the induction solution to the forward osmosis membrane module 281.

In the structure of the saline recovery means 280 as described above, the induction solution supply means 283 includes an induction solution storage tank 283a for supplying the induction solution to the forward osmosis membrane module 281, an induction solution storage tank 283a, An inductive solution supply line 283b for connecting the positive osmosis membrane module 281 and an inductive solution supply line 283b for supplying the inductive solution in the inductive solution storage tank 283a to the positive osmosis membrane module 281 And an induction solution supply amount regulating valve 283d which is provided on the induction solution supply pump 283c and the induction solution supply pump 283c to regulate the supply amount of the induction solution supplied through opening and closing.

On the other hand, on the nose inflow line 272 for allowing the nose water to flow from the nose recovery tank 270 to the normal osmosis membrane module 281, the nose of the water recovery tank 270 is connected to the positive osmosis membrane module 281, And a nose inflow control valve 276 is provided on the nose inflow line 272 for controlling the inflow amount of the nose through opening and closing.

The brine recovery means 280 configured as described above is configured to receive the purified osmosis membrane module (s) from the nacreous recovery tank 270 via the nacreous inflow line 272 connecting the nacreous recovery tank 270 and the osmosis membrane module 281 281). At this time, the nose of the nose recovery tank 270 is controlled through the nose pump 274 and the nose inflow control valve 276.

When the nose of the nacre recovery tank 270 is supplied to the osmosis membrane module 281 through the nacelle pump 274 and the nacre inflow control valve 276 as described above, the induction solution stored in the induction solution storage tank 283a Solution is supplied to the positive osmosis membrane module 281 through the induction solution supply pump 283c and the induction solution supply amount regulating valve 283d.

As described above, when the nose and inducing solution are received in the osmosis membrane module 281, the water in the nose water is permeated to the induction solution side by the osmotic pressure of the osmosis membrane 281a, and the nose passing through the osmosis membrane 281a is It turns into high concentration brine. Further, the induction solution passing through the osmosis membrane 281a is converted into a diluted Fertilizer Solution. At this time, the high-concentration brine that has passed through the cleansing osmosis membrane 281a is recovered by the salinity control means 220, and the diluted induction solution that has passed through the osmosis membrane 281a is recovered and used as fertilizer.

In the meantime, in the structure of the saline recovery means 280 as described above, the Fertilizer Solution flows from the outside into the induction solution storage tank 283a. In accordance with the level of the induction solution storage tank 283a, And controls an inflow amount of the induction solution inflow amount control valve 283e which is provided at one side of the induction solution supply source 283a and controls the inflow amount of the induction solution introduced from the induction solution supply source.

In the above-described constitution, the induction solution can generate osmotic pressure by using calcium nitrate, diammonium hydrogen phosphate and potassium chloride, which are used as fertilizer with high solubility. In the case of Calcium Nitrate, theoretically, it has an osmotic pressure of 600 atm or higher in the melting range. In addition, it is possible to increase the osmotic pressure by using Calcium Nitrate, Diammonium Hydrogen Phosphate and Potassium Chloride as an inducing solution.

The fresh water conveying means 290 constituting the present invention is for conveying untransmitted fresh water to the fresh water tank 210 during the osmotic pressure process of the membrane module 240, A fresh water return line 292 and a fresh water return line 292 connected from the fresh water side of the membrane module 240 to the fresh water tank 210 as shown in FIG. And a fresh water conveying pump 294 for forcibly conveying the fresh water to the fresh water conveying pipe 210.

The fresh water conveying means 290 constituted as described above is constructed so that the fresh water side fresh water which is not permeated to the high concentration salt water side during the osmotic pressure process by the semi-permeable membrane 242 of the fresh water supplied to the membrane module 240 and the high- The operation of opening the fresh water flow control valve 212a for flowing fresh water from the fresh water supply source into the fresh water tank 210 can be reduced by reducing the opening and closing operation of the fresh water flow control valve 212a.

As described above, the technology according to the present invention can always supply power through self-power generation by using salinity difference between fresh water and saline water without supplying external power, and it is possible to maintain the saline concentration at a high concentration It is possible to maximize the power density of the salinity difference generation power using the semi-permeable membrane and obtain stable output. Accordingly, the technique according to the present invention can not only store the surplus power in the battery through the power control means, but also adjust the power generation amount according to the demand of the load.

The present invention is not limited to the above-described embodiments, and various modifications may be made within the scope of the technical idea of the present invention.

100, 200. Salinity Chiller Power Generation System
110, 210. Fresh water tank
120, 220. Salinity control means
130, 230. Salt water tank
140, 240. Membrane module
150, 250. Turbine
160, 260. Power control means
170. Nose recovery means
270. Nose recovery tank
180, 290. Fresh water conveying means
190. Fresh water recovery means
280. Saline recovery means
500. Control circuit

Claims (41)

A fresh water tank in which fresh water supplied from a fresh water supply source is stored;
A salinity control means for receiving fresh water from the fresh water tank and adjusting the salinity of the fresh water to a high concentration of salt water;
A brine tank for storing high-concentration brine having a controlled salinity through the salinity adjusting means;
A membrane module for converting the high-concentration brine into a high-concentration nodule through osmotic pressure according to the supply of fresh water and high-concentration brine stored in the fresh water tank and the brine tank;
A turbine that produces power by high pressure injection of the high flow rate naphtha converted by the membrane module;
Power control means for controlling power produced by rotation of the turbine;
Water recovery means for generating electric power in the process of passing through the turbine and recovering the low-pressure converted water to supply it to the salinity control means; And
And fresh water conveying means for conveying fresh water not permeated in the osmotic pressure process of the membrane module to the fresh water tank. [2] The apparatus according to claim 1, wherein the salinity adjusting means comprises: a stirring tank in which fresh water supplied from the fresh water tank and the water collection means is stored;
A solute storage tank for filling and storing a solute such as sodium chloride (NaCl) for controlling salinity, which is introduced into the stirring tank;
A solute supply control valve provided on the solute supply line connected to the stirring tank from the solute storage tank to adjust the supply amount of the solute through opening and closing; And
And a stirrer installed inside the stirring tank to mix the supplied fresh water and the nasal water while dissolving the solute. 3. The salinity electric power generation system according to claim 2, further comprising an electrical conductivity meter for measuring the concentration of the brine to be regulated in the stirring tank. 3. The salinity electric power generating system according to claim 2, further comprising a water level sensor for measuring a level of the salt water in the stirring tank to adjust a supply amount of the salt water supplied to the salt water tank. 5. The apparatus of claim 4, wherein a brine supply line is provided between the agitator and the brine tank, and a brine outlet control valve is provided on the brine supply line for controlling the flow rate of the brine by being controlled by the level sensor Wherein the salinity-generating system is a salinity-type power generation system. The power control apparatus according to claim 1, wherein the power control means includes: an inverter for converting a DC power produced by rotation of the turbine into an AC power source required for a load, which is a power supply facility;
A battery for charging and storing electric power produced through the turbine; And
And a control circuit for connecting the electric power produced by the rotation of the turbine to the inverter or controlling the electric power upon charging the battery. The salinity electric power generating system according to claim 6, wherein the power source converted by the AC power source (AC) by the inverter is used as an AC power source (AC) required for salting power generation. The salinity electric generator system according to claim 6, wherein the control circuit connects a DC power source (DC) of the battery to the inverter to control the conversion to an AC power source (AC). The salinity electric generator system according to claim 6, wherein the control circuit connects and controls a DC power source (DC) of the battery directly to the load. 7. The salinity electric power generating system according to claim 6, wherein the control circuit connects and controls the AC power source (AC) converted by the inverter to the load. The salinity electric generator system according to claim 6, wherein the control circuit controls all matters related to salinity difference generation. [2] The turbine of claim 1, wherein the water collection means comprises: a water collection tank for generating electric power in the process of passing through the turbine and recovering the low water pressure converted water;
A ninth water supply line for supplying the nursing water stored in the nursing water recovery tank to the salinity adjusting means;
A nursery supply pump installed on the nursery supply line for supplying nursing water stored in the nursery return tank to the salt water regulating means; And
And a radial supply control valve provided on the radial supply line for adjusting the supply amount of radial water supplied by the radial supply pump through opening and closing. 2. The membrane module as claimed in claim 1, wherein the fresh water conveying means comprises: a fresh water return line connected from the fresh water side of the membrane module to the fresh water tank; And
And a fresh water conveyance pump installed on the fresh water conveyance line for forcibly conveying the fresh water from the fresh water side of the membrane module to the fresh water tank. The fresh water flow control valve according to claim 1, further comprising a fresh water flow control valve that opens and closes fresh water according to the amount of fresh water stored in the fresh water tank on the fresh water inflow line connected to the fresh water supply source from the fresh water supply source Characteristic salinity charger generation system. 2. The membrane module as claimed in claim 1, wherein a fresh water supply line connected to the membrane module from the fresh water tank comprises a fresh water supply pump for supplying fresh water of the fresh water tank to the membrane module, Characterized in that a quantity control valve is further configured. 16. The salinity water generator system according to any one of claims 1 to 15, further comprising fresh water recovering means for recovering fresh water from the nose recovered by the nose recovery means. [17] The apparatus of claim 16, wherein the fresh water recovery means comprises: an evaporation chamber that receives the nursery water from the nursery recovery means and heats the nursery water to a boiling point; And
And a condenser for condensing the vapor to be evaporated through heating of the evaporation chamber to allow the condensed fresh water to flow into the fresh water tank. 18. The system as claimed in claim 17, wherein the heating of the evaporation chamber is performed through a hot wire or a solar collector. 19. The method of claim 18, wherein the heating of the evaporation chamber is preferentially performed through the solar collector, and when the boiling point of the solar collector is not reached due to environmental factors, the evaporation chamber is heated through the heating wire Car generator system. 18. The system as claimed in claim 17, wherein the evaporation chamber is further provided with a temperature sensor so that the heating temperature can be controlled by the temperature sensor. 18. The salinity water generation system according to claim 17, further comprising a pumped water level sensor installed in the pumped water recovery means for sensing the water level of the pumped water. [Claim 18] The water treatment system according to claim 17, further comprising a pseudo water level control valve for discharging the pseudo water to the outside at one side of the pseudo water recovery means, if the water level of the pseudo water is the maximum water level or more, The supply to the evaporation chamber is stopped and the recovery of the nose is made when the water level of the salinity water reaches the minimum water level. A fresh water tank in which fresh water supplied from a fresh water supply source is stored;
A salinity control means for receiving fresh water from the fresh water tank and adjusting the salinity of the fresh water to a high concentration of salt water;
A brine tank for storing high-concentration brine having a controlled salinity through the salinity adjusting means;
A membrane module for converting the high-concentration brine into a high-concentration nodule through osmotic pressure according to the supply of fresh water and high-concentration brine stored in the fresh water tank and the brine tank;
A turbine that produces power by high pressure injection of the high flow rate naphtha converted by the membrane module;
Power control means for controlling power produced by rotation of the turbine;
A water recovery tank for generating electric power in the course of passing through the turbine and recovering the low water pressure converted water;
Salt water recovery means for converting the nascent water stored in the nacre recovery tank into high-concentration saline water through osmotic pressure using an inducing solution; And
And fresh water conveying means for conveying fresh water not permeated in the osmotic pressure process of the membrane module to the fresh water tank. 24. The method of claim 23, wherein the salinity adjusting means comprises: a stirring tank in which fresh water supplied from the fresh water tank and the saline water collecting means and the high-concentration saline water are stored;
A solute storage tank for filling and storing a solute such as sodium chloride (NaCl) for controlling salinity, which is introduced into the stirring tank;
A solute supply control valve provided on the solute supply line connected to the stirring tank from the solute storage tank to adjust the supply amount of the solute through opening and closing; And
And a stirrer installed in the stirring tank to mix the supplied fresh water and the high-concentration brine while dissolving the solute into the salt water. The salinity electric power generation system according to claim 24, further comprising an electrical conductivity meter for measuring the concentration of the saline water to be adjusted in the stirring tank. The salinity water generator system according to claim 24, further comprising a water level sensor for measuring a water level of the salt water in the stirring tank to adjust a supply amount of the salt water supplied to the salt water tank. 27. The apparatus of claim 26, wherein a brine supply line is provided between the agitation tank and the brine tank, and a brine flow control valve is provided on the brine supply line to control the flow rate of the brine by being controlled by the level sensor Wherein the salinity-generating system is a salinity-type power generation system. The power control apparatus according to claim 23, wherein the power control means includes: an inverter for converting a DC power produced by the rotation of the turbine into an AC power source required for a load, which is a power supply facility;
A battery for charging and storing electric power produced through the turbine; And
And a control circuit for connecting the electric power produced by the rotation of the turbine to the inverter or controlling the electric power upon charging the battery. The salinity electric power generating system according to claim 28, wherein the power source converted into AC power by the inverter is used as an AC power source (AC) required for salting power generation. The salinity electric generator system according to claim 28, wherein the control circuit connects the DC power source (DC) of the battery to the inverter to control the conversion to an AC power source (AC). The salinity electric generator system according to claim 28, wherein the control circuit connects and controls a DC power source (DC) of the battery directly to the load. The salinity electric generator system according to claim 28, wherein the control circuit connects and controls the AC power source (AC) converted by the inverter to the load. 29. The system of claim 28, wherein the control circuit controls all aspects of salinity differential generation. The fresh water flow control valve according to claim 23, further comprising a fresh water flow control valve on the fresh water inflow line connected from the fresh water supply source to the fresh water inflow line to open and close the fresh water in accordance with the quantity of fresh water stored in the fresh water tank Characteristic salinity charger generation system. 24. The membrane module of claim 23, further comprising: a fresh water supply pump for supplying fresh water of the fresh water tank to the membrane module from a fresh water supply line connected to the membrane module from the fresh water tank; and a fresh water supply unit for controlling the quantity of fresh water supplied by the fresh water supply pump Characterized in that a quantity control valve is further configured. The osmosis membrane module according to any one of claims 23 to 35, wherein the saline-water recovering means comprises a positive osmosis membrane module for converting the noble water into the high-concentration saline water through the osmotic action according to the introduction of the noble water and the induction solution in the nacryi recovery tank;
A high concentration brine supply line for supplying the high concentration brine converted in the osmotic pressure process of the osmosis membrane module to the salinity adjusting means; And
And an induction solution supply means for supplying the induction solution to the positive osmosis membrane module. 37. The apparatus of claim 36, wherein the inductive solution supply means comprises: an inductive solution storage tank for supplying an induction solution to the positive osmosis membrane module;
An induction solution supply line connecting the induction solution storage tank and the positive osmosis membrane module;
An induction solution supply pump installed on the induction solution supply line for forcibly supplying the induction solution of the induction solution storage tank to the positive osmosis membrane module; And
And an induction solution supply amount regulating valve provided on the induction solution supply pump for regulating a supply amount of the induction solution supplied through opening and closing. The salinity electric power generating system according to claim 37, further comprising an induction solution inflow amount control valve for controlling an inflow amount of the induction solution introduced from the induction solution supply source to one side of the induction solution storage tank. The osmosis membrane module as claimed in claim 37, further comprising: a nodule disposed on the nose inflow line for allowing introduction of the nordinator from the nordic recovery tank into the osmosis membrane module, Further comprising a pump and a nosepiece inflow control valve provided on the nose inflow line for controlling the inflow amount of the nose through opening and closing. 38. The system of claim 37, wherein the diluted inductive solution is used as a fertilizer during the passage through the osmosis membrane module. 24. The apparatus of claim 23, wherein the fresh water conveyance means comprises: a fresh water return line connected from the fresh water side of the membrane module to the fresh water tank; And
And a fresh water conveyance pump installed on the fresh water conveyance line for forcibly conveying the fresh water from the fresh water side of the membrane module to the fresh water tank.

Images