KR102417963B1 - Energy producing system using emulsion and operating method thereof - Google Patents

Abstract

The present invention relates to an energy producing system using an emulsion and an operating method thereof. According to the present invention, a liquid fuel containing a hydrocarbon and a liquid are mixed to form an emulsion, and then discharged to a streamer to completely burn and recover an energy. A fuel supply unit supplies the liquid fuel containing the hydrocarbon. A liquid supply unit supplies the liquid. The liquid fuel supplied by an emulsion production unit from the fuel supply unit and the liquid supplied from the liquid supply unit are mixed to produce and deliver the emulsion. A streamer generation unit generates and transmits the streamer. Combustion proceeds by a burner unit discharging the emulsion delivered from the emulsion production unit to the streamer delivered from the streamer generation unit. The energy producing system using the emulsion of the present invention comprise: the fuel supply unit; the liquid supply unit; the emulsion production unit; the streamer generation unit; and the burner unit.

Description

Energy producing system using emulsion and its operating method {Energy producing system using emulsion and operating method thereof}

The technical field of the present invention relates to an energy production system using an emulsion and an operating method thereof, and in particular, by mixing liquid fuel and liquid containing hydrocarbons to make an emulsion, discharge with a streamer to completely It relates to an energy production system using an emulsion realized to be combusted and recovered as energy, and a method for operating the same.

In most fuel oil, single particles in the atomized state are ignited and burned, leaving pollutants behind and becoming the main cause of polluting the atmosphere. greatly pollute the environment. On the other hand, emulsion fuel oil can be completely combusted when waste is incinerated using it as fuel. Accordingly, the use of emulsion oil is a situation in which the development of alternative energy, improvement of the efficiency of existing energy, and the use of emulsion oil can be minimized, so the use of emulsion oil is actively recommended.

This emulsion oil is a fuel oil in which oil and water are finely mixed (10 microns or less) in a form in which the oil is surrounded around water particles (i.e., nucleus pulposus), in an emulsion oil state, that is, oil or fat is dissolved in water, Water particles are vaporized by the conduction of heat obtained by the combustion of oil surrounding water, and the vaporized water vapor increases in volume (about 5800 times), and this vapor diffuses the oil layer and causes an atomization phenomenon. ) to help the complete combustion of oil, so it is exhausted in a clean state with almost no pollutants such as nitrogen oxides.

In the combustion process of emulsion oil, water (H2O) is decomposed into water vapor at a high temperature to liberate oxygen, hydrogen, and hydroxyl groups through a continuous radical reaction. That is, water is decomposed into water vapor at a high temperature to generate hydrogen radicals, and these hydrogen radicals are combined with oxygen molecules to form oxygen radicals and water. Accordingly, oxygen radicals combine with hydrogen molecules to become hydroxyl radicals and hydrogen radicals, hydroxyl radicals combine with hydrogen molecules to become water and hydrogen radicals, and water vapor and hydrogen combine to produce water and hydrogen radicals. do.

Active research has been conducted for the practical use of this emulsion oil, but it is difficult to satisfy the conditions that the mixing ratio of oil and water must be within a certain range, and that it must be maintained in a stable emulsion state in which oil-water separation does not occur until combustion. There is a problem that it is difficult to generalize. In other words, it is easy to keep oil and water in an emulsion state for a short time, but when a long time has elapsed due to transportation/storage of fuel, the function and effect as an emulsion oil cannot be expected because of the separation of oil and water, and thus actual usability cannot be secured. There is no problem.

Of course, by mixing and stirring a surfactant having an HLB value of 3 to 4, a nonionic surfactant composed of water and polyvinyl alcohol, and heavy oil and waste oil in a certain ratio, the water is dispersed into fine particles to produce an emulsion fuel using the waste oil as a raw material. There is a way. This has another problem in that an additive such as a surfactant must be used.

Korea Patent No. 10-0588057 (registered on June 1, 2006) is an emulsion mixing combustion method that can induce complete combustion of industrial wastes by the micro-explosion phenomenon obtained when burning emulsion oil made by mixing oil and water. It is disclosed with respect to a waste incineration and melting apparatus of, a gas generator unit configured to obtain hydrogen and oxygen by electrolyzing water supplied from a water tank; a gas control device unit for controlling the flow paths of hydrogen gas and oxygen gas discharged from the gas generator unit; An emulsion oil production device unit for mixing water and oil in an emulsion state by the assisted action of hydrogen and oxygen gas supplied from the gas generator unit under the control of the gas control unit unit; a combustion device unit for supplying hydrogen and oxygen gas supplied from the gas generating unit unit and the emulsion oil supplied from the emulsion oil manufacturing unit unit to the combusted material to be combusted; It is characterized in that it comprises a heat recovery device that is provided so as to recover the heat source obtained from the combustion device. According to the disclosed technology, the emulsion oil is manufactured in the device unit having a simple structure and immediately supplied to the emulsion oil consumption element, so that the emulsion oil can be manufactured through a simple process, and thus the equipment cost can be reduced.

Korean Patent No. 10-0757317 (registered on Sept. 4, 2007) is a fuel that increases combustion efficiency by emulsifying fuel oil such as bunker oil used as fuel for industrial boilers with water to facilitate combustion. A device for emulsifying oil is disclosed. According to the disclosed technology, an electric motor; a mixer for mixing water and fuel oil into an emulsion; A power transmission device that is a flat belt with concavo-convex grooves wound around a pulley attached to the shaft of a motor and a pulley attached to the shaft of a mixer; And by including the base on which the motor and mixer are fixed, a special type of mixer that rotates at high speed is adopted, and it becomes an emulsion in which very fine water particles and fuel oil particles are mixed, thus preventing oil-water separation. It does not occur quickly and the emulsion state lasts for a relatively long time. The size of the fuel oil particles is very fine with a diameter of 10 μm or less, so combustion is easy, and the water particles contained in the fuel oil help the fuel oil combustion.

In the prior art as described above, as the consumption of petroleum products increases, the problem of disposal of wastes, particularly crude oil residues, lubricating oil and tool oil, lubricating coolant, etc., is becoming increasingly serious, and crude oil industry by-products are mixtures and emulsions of various fuels. It has been used for a long time as a hydrocarbon material in the world, but in most cases, it is used to improve the properties of fuel mixtures used in furnaces, boilers or combustion chambers, which are energy-intensive objects. There were three problems: a problem of securing fuel and an environmental problem.

Korean Patent Registration No. 10-0588057 Korean Patent Registration No. 10-0757317

The problem to be solved by the present invention is to solve the problems as described above, and by mixing liquid fuel and liquid containing hydrocarbons to make an emulsion and discharge it with a streamer, complete combustion It is to provide an energy production system using an emulsion realized so that it can be recovered as energy and a method for operating the same.

As a means for solving the above problems, according to one aspect of the present invention, a fuel supply unit for supplying a liquid fuel containing hydrocarbons; a liquid supply unit for supplying a liquid; an emulsion production unit for producing and delivering an emulsion by mixing the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit; a streamer generating unit for generating and delivering a streamer; And it provides an energy production system using an emulsion comprising a burner unit that proceeds combustion by discharging the emulsion delivered from the emulsion production unit to the streamer delivered from the streamer generating unit.

In one embodiment, the fuel supply unit collects at least one or more of heavy oil, waste cooking oil, biodiesel, crude oil residue, liquid waste of livestock complexes and poultry farms, fuel oil, lubricating oil, waste oil, lubricating coolant, and naphtha sludge. It is characterized by supplying.

In one embodiment, the fuel supply unit, characterized in that for supplying the liquid hydrocarbon fuel (LHF) to the emulsion production unit.

In an embodiment, the liquid supply unit collects and supplies at least one or more of general industrial water, domestic sewage, sewage and wastewater.

In an embodiment, the emulsion production unit is characterized in that the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit are mixed in a ratio of 3:7.

In one embodiment, the emulsion production unit, using FLEC, the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit are mixed in a ratio of 3-7:7-3.

In an embodiment, the emulsion production unit is characterized in that the heavy oil supplied from the fuel supply unit and the water supplied from the liquid supply unit are mixed in a ratio of 2:8.

In one embodiment, the emulsion production unit is characterized in that it forms a mixer by combining a pump and a mixer.

In an embodiment, the streamer generating unit is characterized in that it generates a streamer using a high-pressure and high-frequency pulse generator or plasma generator.

In one embodiment, the streamer generator is characterized in that it is provided with two multi-function high voltage and high frequency resonance generator (MHHRG).

In one embodiment, the streamer generating unit, a first MHHRG for generating a streamer and delivering it to the burner unit; and a second MHHRG for purifying dust or gaseous emissions generated after combustion in the burner unit.

In one embodiment, the streamer generator, when using the second MHHRG, the exit signal has a cycle of 1 to 5 seconds and a duty cycle of 5 to 10, the voltage is 100 ~ 200KV, the frequency is 150 ~ 1100KHz characterized in that

In an embodiment, the streamer generating unit is characterized in that it generates a corresponding streamer according to the output signal parameter input from the emulsion production unit.

In an embodiment, the burner unit is characterized in that it burns by discharging the emulsion delivered from the emulsion production unit to the streamer delivered from the streamer generating unit using a 2.5 mega or 5.0 mega combustion device.

In an embodiment, the burner unit is characterized in that the size of the hole of the nozzle provided in the combustion device is formed to correspond to the flow and combustion of the emulsion delivered by the emulsion production unit.

In one embodiment, the burner unit, in order to completely burn by discharging the emulsion delivered from the emulsion production unit to the streamer delivered from the streamer generating unit, control for controlling the amount of emulsion delivered from the emulsion production unit It is characterized in that it is provided with a valve.

In one embodiment, the burner unit is characterized in that it is provided with an electrically powered pulse burner (EPSB).

In one embodiment, the burner unit is characterized in that it completely burns the emulsion delivered from the emulsion production unit by applying the streamer delivered from the streamer generating unit to the outlet side of the nozzle.

In one embodiment, the energy production system using the emulsion, a tank for temporarily storing the emulsion delivered by the emulsion production unit; and a recovery valve for recovering the emulsion stored in the tank and supplying it back to the emulsion production unit when a preset time has elapsed.

In one embodiment, the energy production system using the emulsion is formed in connection with the burner unit, and the electrode connected to the streamer generating unit is inserted into it, and the emulsion heated to a preset temperature is heated to a nozzle of the burner unit. It is characterized in that it further comprises a pre-chamber for allowing the arrived emulsion to arrive under a preset pressure through a left front combustion with the discharge of the streamer generated by the streamer generating unit.

In one embodiment, the emulsion production unit, a first inlet pipe for receiving the liquid fuel from the fuel supply unit; a second inlet pipe for receiving the liquid from the liquid supply unit; an outlet pipe for supplying the emulsion to the burner unit; a shut-off valve for blocking or opening the emulsion supplied to the burner unit through the outlet pipe; an emulsion pump connected to the shut-off valve to pump the emulsion through the shut-off valve and supply it to the burner unit; an emulsion amount meter connected to the outlet pipe and configured to measure the amount of the emulsion used to be supplied to the burner unit through the shut-off valve; and a controller for controlling the operation of the shut-off valve, the emulsion pump, and the emulsion usage meter.

In one embodiment, the emulsion production unit is characterized in that it further comprises a third inlet pipe for receiving the additive when necessary to store the emulsion for a long time.

In an embodiment, the controller receives data notified from each instrument related to the operation of the emulsion production unit through a wire, and adjusts each instrument according to a preset and stored program.

In one embodiment, the emulsion production unit is formed to be connected to each other, characterized in that it further comprises a plurality of emulsion storage tanks for storing the emulsion.

In one embodiment, the emulsion production unit, each installed inside the emulsion storage tank, further comprising a plurality of emulsion level measuring equipment for measuring the water level for the emulsion stored in the inside of the emulsion storage tank, respectively characterized in that

In one embodiment, the emulsion production unit, each of which is installed on the inlet side of the emulsion storage tank, a plurality of charging cut-off valve for receiving or blocking the emulsion, respectively; and a plurality of discharge blocking valves respectively installed at the outlet side of the emulsion storage tank to discharge or block the emulsion stored in the emulsion storage tank.

In one embodiment, the emulsion production unit is connected to the discharge cut-off valve, is carried out through the discharge cut-off valve, and further comprises a supply amount measuring instrument for measuring the supply amount of the emulsion supplied to the burner unit. do.

In one embodiment, the emulsion production unit is connected to the take-out shutoff valve, and it is carried out through the take-out shut-off valve to measure the amount of moisture in the emulsion supplied to the burner unit It is characterized in that it further comprises a moisture meter. .

In one embodiment, the emulsion production unit, a tank pump for supplying the emulsion to the burner unit by pumping the emulsion through the discharge shut-off valve according to the drive control; And it characterized in that it further comprises a actuator for controlling the driving of the emulsion level measuring device, the charging cut-off valve, the discharge cut-off valve, the supply amount meter, the moisture meter, and the tank pump.

In one embodiment, the actuator receives data notified from each instrument related to the operation of the emulsion production unit through a wire, and adjusts each instrument according to a preset and stored program.

In one embodiment, the driver determines the output signal parameter of the streamer generated by the streamer generating unit in response to the data provided by the supply amount measurement meter and the moisture meter, and the determined output signal parameter is input to the streamer generating unit.

In one embodiment, the streamer generating unit, a first MHHRG for generating a first streamer and delivering it to the burner unit; a second MHHRG for generating and delivering a second streamer; an electrode for receiving and discharging a second streamer from the second MHHRG; a purifier for purifying the dust or gas emission generated after combustion in the burner unit by the second streamer discharged through the electrode; a gas scrubber for capturing the effluent purified by the purifier, removing impurities from the captured effluent, and delivering; And it is formed in the form of a chimney having a preset height, characterized in that it comprises an outlet for discharging the exhaust delivered from the gas cleaner into the atmosphere.

In an embodiment, the first MHHRG generates a first streamer corresponding thereto according to an output signal parameter input from the driver.

In an embodiment, the second MHHRG generates a second streamer corresponding thereto according to an output signal parameter input from the driver.

In one embodiment, the burner unit, ignition combustion nozzle for spraying the emulsion supplied from the emulsion production unit; and a burner for burning the emulsion sprayed from the ignition combustion nozzle by discharging it to the streamer supplied from the streamer generator, and converting the emulsion into thermal energy through combustion.

In one embodiment, the burner unit, a three-way valve for receiving thermal energy supplied from the outside or supplied with thermal energy generated by combustion of the burner; and a fuel heater for receiving thermal energy from the three-way valve when the burner is ignited, heating the emulsion supplied from the emulsion production unit, and transferring it to the ignition combustion nozzle; and a centrifugal pump for recovering thermal energy used in the fuel heater and supplying it to the burner.

As a means for solving the above problems, according to another aspect of the present invention, the fuel supply unit comprising the steps of supplying a liquid fuel containing hydrocarbons; supplying a liquid by a liquid supply unit; The emulsion production unit mixing the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit to produce and deliver an emulsion; A streamer generating unit generating and delivering a streamer; And it provides an operating method of an energy production system using an emulsion comprising the step of discharging the emulsion delivered by the burner unit from the emulsion production unit to the streamer delivered from the streamer generating unit to proceed with combustion.

As an effect of the present invention, an emulsion is made by mixing a liquid fuel containing hydrocarbons and a liquid, and discharged with a streamer, so that the energy using the emulsion can be completely burned and recovered as energy. By providing a production system and its operating method, it is possible to completely burn the emulsion to solve three problems at once: the problem of waste disposal, the problem of securing inexpensive and complete fuel, and the environmental problem.

1 is a view for explaining an energy production system using an emulsion according to an embodiment of the present invention.
FIG. 2 is a view showing a streamer generated by the streamer generating unit in FIG. 1 .
3 is a view for explaining the emulsion production unit in FIG. 1 as a first example.
4 is a view for explaining the emulsion production unit in FIG. 1 as a second example.
FIG. 5 is a view for explaining the streamer generator shown in FIG. 1 .
FIG. 6 is a view for explaining the burner unit shown in FIG. 1 .
FIG. 7 is a view for explaining the purification effect of exhaust gas from the burner unit of FIG. 1 .
8 is a view showing the combustion of the emulsion using the streamer discharge in the burner unit shown in FIG.
9 is a view for explaining a method of operating an energy production system using an emulsion according to an embodiment of the present invention.
FIG. 10 is a view for explaining an exhaust gas purification process using a streamer after the combustion progress step in FIG. 9 .
11 is a view for explaining the comparison of the economic feasibility of each fuel of the operating method of the energy production system using the emulsion according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, since the description of the present invention is merely an embodiment for structural or functional description, the scope of the present invention should not be construed as being limited by the embodiment described in the text. That is, since the embodiment is capable of various changes and may have various forms, it should be understood that the scope of the present invention includes equivalents capable of realizing the technical idea. In addition, since the object or effect presented in the present invention does not mean that a specific embodiment should include all of them or only such effects, it should not be understood that the scope of the present invention is limited thereby.

The meaning of the terms described in the present invention should be understood as follows.

Terms such as “first” and “second” are for distinguishing one component from another, and the scope of rights should not be limited by these terms. For example, a first component may be termed a second component, and similarly, a second component may also be termed a first component. When a component is referred to as being “connected to” another component, it may be directly connected to the other component, but it should be understood that other components may exist in between. On the other hand, when it is mentioned that a certain element is "directly connected" to another element, it should be understood that the other element does not exist in the middle. Meanwhile, other expressions describing the relationship between elements, that is, "between" and "between" or "neighboring to" and "directly adjacent to", etc., should be interpreted similarly.

The singular expression is to be understood to include the plural expression unless the context clearly dictates otherwise, and terms such as "comprise" or "have" are not intended to refer to the specified feature, number, step, action, component, part or any of them. It is intended to indicate that a combination exists, and it should be understood that it does not preclude the possibility of the existence or addition of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Terms defined in general used in the dictionary should be interpreted as having the same meaning in the context of the related art, and cannot be interpreted as having an ideal or excessively formal meaning unless explicitly defined in the present invention.

Now, an energy production system using an emulsion according to an embodiment of the present invention and an operating method thereof will be described in detail with reference to the drawings.

1 is a view illustrating an energy production system using an emulsion according to an embodiment of the present invention, and FIG. 2 is a view showing a streamer generated by the streamer generator in FIG. 1 .

1 and 2 , the energy production system 100 using the emulsion is a fuel supply unit 110 , a liquid supply unit 120 , an emulsion production unit 130 , a streamer generating unit 140 , a burner unit 150 . ) is included.

The fuel supply unit 110 supplies the liquid fuel containing hydrocarbons to the emulsion production unit 130 .

In one embodiment, the fuel supply unit 110 is a hydrocarbon-containing liquid fuel, for example, heavy oil of any quality, waste cooking oil, biodiesel, crude oil residue, liquid waste from livestock complexes and poultry farms, and fuel oil, as well as, At least one or more of lubricating oil, waste oil, lubricating coolant, naphtha sludge, etc. may be collected and supplied to the emulsion production unit 130 .

In an embodiment, the fuel supply unit 110 may supply liquefied hydrocarbon fuel (LHF) to the emulsion production unit 130 .

The liquid supply unit 120 supplies a liquid to the emulsion production unit 130 .

In one embodiment, the liquid supply unit 120, as water, for example, general industrial water, domestic sewage, sewage or waste water, etc. can be collected at least one or more of the collected and supplied to the emulsion production unit (130).

The emulsion production unit 130 receives the liquid fuel containing hydrocarbon from the fuel supply unit 110 and receives the liquid from the liquid supply unit 120, mixes the supplied liquid fuel containing the hydrocarbon with the liquid to produce an emulsion, and the production One emulsion is delivered to the burner unit 150 .

In an embodiment, the emulsion production unit 130 mixes the hydrocarbon-containing liquid fuel supplied from the fuel supply unit 110 with the liquid supplied from the liquid supply unit 120 without additives such as surfactants at a ratio of 3:7 Thus, an emulsion can be made and supplied to the burner unit 150 .

In an embodiment, the emulsion production unit 130 mixes the liquid supplied from the liquid supply unit 120 with the liquefied hydrocarbon fuel (LHF) supplied from the fuel supply unit 110 in a mechanical mixing method using a mixer to emulsion (fuel liquid) emulsion; FLE) can be created.

In one embodiment, the emulsion production unit 130, a separate emulsion production equipment (fuel-liquid emulsion complex; FLEC) may be provided, using the FLEC liquid hydrocarbon fuel (LHF) supplied from the fuel supply unit 110 using the and the liquid supplied from the liquid supply unit 120 may be mixed at a ratio of 30 to 70% and 30 to 70% to produce an emulsion (FLE).

In an embodiment, the emulsion production unit 130 mixes the heavy oil supplied from the fuel supply unit 110 and the water supplied from the liquid supply unit 120 at a mixing ratio of 20%:80% to produce an emulsion (FLE). have.

In an embodiment, the emulsion production unit 130 may be formed as a mixer by combining a pump, a mixer, and the like.

The streamer generating unit 140 generates a streamer and delivers it to the burner unit 150 .

In an embodiment, the streamer generator 140 may include a high-pressure and high-frequency pulse generator (or, a high-pressure and high-frequency plasma generator), and uses the corresponding pulse generator (or plasma generator) in FIG. 2 . It is possible to generate a streamer as shown in and deliver it to the burner unit 150 to discharge it. Here, Figure 2 is a view showing only the discharge of the streamer in the absence of fuel.

In an embodiment, the streamer generator 140 may include two multi-functional high voltage high frequency resonant generators (MHHRGs).

In one embodiment, the streamer generating unit 140 generates a streamer and transmits the first MHHRG to the burner unit 150, and the exhaust in the form of dust or gas generated after combustion in the burner unit 150. A second MHHRG for purification may be provided. Here, the first MHHRG has a voltage of 150 to 250 KV and a frequency of 450 to 550 KHz. The second MHHRG has characteristics such that the exit signal has a period of 1 to 5 seconds and a duty cycle of 5 to 10, a voltage of 100 to 200 KV, and a frequency of 450 to 550 KHz.

In one embodiment, when the streamer generating unit 140 uses the second MHHRG, the characteristic values are as follows, the exit signal has a period of 1 to 5 seconds and a duty cycle of 5 to 10, and the voltage is 100 ~200KV, and the frequency is 150~1100KHz.

In an embodiment, the streamer generating unit 140 may generate a corresponding streamer according to the output signal parameter input from the emulsion production unit 130 .

The burner unit 150 receives the emulsion delivered from the emulsion production unit 130 and receives the streamer delivered from the streamer generating unit 140, and discharges the supplied emulsion to the supplied streamer to prevent combustion. proceed

In one embodiment, the burner unit 150 may be provided with a combustion device (burner) of 2.5 mega or 5.0 mega, the streamer generating unit ( 140), it can be completely burned by discharging it with the streamer supplied.

In one embodiment, the burner unit 150 may form a size corresponding to the hole size of the nozzle provided in the combustion device (burner) to suit the flow and combustion of the emulsion supplied from the emulsion production unit 130 . Alternatively, the burner unit 150 discharges the emulsion supplied from the emulsion production unit 130 to the streamer supplied from the streamer generating unit 140 to completely burn the emulsion supplied from the emulsion production unit 130. A control valve for controlling the amount may be provided.

In an embodiment, the burner unit 150 may include an electrokinetic pulse-speed burner (EPSB).

In an embodiment, the burner unit 150 may apply the streamer generated by the streamer generating unit 140 to the outlet side of the nozzle to completely burn the emulsion supplied from the emulsion generating unit 130 .

The energy production system 100 using an emulsion having the above-described configuration is made by mixing liquid fuel and liquid containing hydrocarbons in the emulsion production unit 130 to make an emulsion, and the streamer generation unit 140 generates the By discharging from the burner unit 150 with a trimmer so that it can be completely combusted and recovered as energy, the emulsion is completely combusted to solve three problems at once: a waste treatment problem, a problem of securing inexpensive and complete fuel, and an environmental problem can be solved

The energy production system 100 using the emulsion having the above-described configuration is a thermal power plant, a combined heat and power plant, a boiler, etc. using liquefied hydrocarbon fuel (LHF). can

The energy production system 100 using the emulsion having the configuration as described above is a unit that uses liquefied hydrocarbon fuel (LHF) to recover electrical energy or thermal energy, crude oil processing field, and companies that process industrial and household waste , can be applied to exhaust gas purification companies, and liquid hydrocarbon fuel (LHF) is mixed with liquid without additives such as surfactants to make an emulsion, and it can be completely burned using a pulse generator (or plasma generator).

The energy production system 100 using the emulsion having the above-described configuration includes a tank for temporarily storing the emulsion produced by the emulsion production unit 130, and the emulsion stored in the tank when a preset time elapses. Thus, it can be provided with a recovery valve for supplying it back to the emulsion production unit 130, and the corresponding tank can make it unnecessary to store the emulsion produced in the emulsion production unit 130 for a long time, and even if oil-water separation occurs sometimes Since it is enough to return it to the emulsion production unit 130 through the corresponding recovery valve before supplying it to the burner unit 150, additives such as surfactants are not required in the emulsion production.

The energy production system 100 using the emulsion having the configuration as described above may include a prechamber.

The prechamber is formed in connection with the burner unit 150, and an electrode connected to the streamer generating unit 140 is inserted into it, and the emulsion heated to a preset temperature is heated to a preset temperature through the nozzle of the burner unit 150. It allows it to arrive under pressure, and allows the emulsion to be burned to the left along with the discharge of the streamer generated by the streamer generating unit 140 .

The energy production system 100 using the emulsion having the above-described configuration does not need to store the emulsion produced by the emulsion production unit 130 for a long time. It can also be used by adding it to water.

The energy production system 100 using the emulsion having the configuration as described above, in particular, makes an emulsion in the ratio of 5% liquid fuel and 95% water in the emulsion production unit 130 to succeed in combustion in the burner unit 150. does it

The energy production system 100 using an emulsion having the above-described configuration is, in particular, an emulsion made in a ratio of less than 70% of liquid fuel and 30% or more of water in the emulsion production unit 130 in the streamer generating unit 140. It can be combusted in the burner unit 150 using ultra-high pressure and high frequency pulses.

The energy production system 100 using the emulsion having the above-described configuration is used to make an emulsion in the emulsion production unit 130, and in particular, a reverse emulsion in which numerous fine water droplets are placed in oil particles is used, and thus the burner In the unit 150, when the temperature of the reverse emulsion reaches 175 degrees, an explosion of fine water droplets occurs and the oil particles are dispersed to a smaller size and burned, which is generated by the streamer generating unit 140 It causes secondary combustion to occur by applying ultra-high-pressure and high-frequency pulses.

FIG. 3 is a view for explaining the emulsion production unit in FIG. 1 as a first example, and FIG. 4 is a view for explaining the emulsion production unit in FIG. 1 as a second example.

3 and 4, the emulsion production unit 130, as a fuel emulsion preparation unit (FEPU), a first inlet pipe (inlet pipe) 131, a second inlet pipe 132, a third inlet pipe ( 133), an outlet pipe 134, a shut-off valve 135, an emulsion pump 136, an emulsion usage meter 137, and a controller 138 may be provided.

The first inlet pipe 131 allows the hydrocarbon-containing liquid fuel to be supplied from the fuel supply unit 110 .

The second inlet pipe 132 allows the liquid to be supplied from the liquid supply unit 120 .

The third inlet pipe 133 allows an additive such as a surfactant to be injected when it is necessary to store the prepared emulsion for a long time.

The outlet pipe 134 supplies the prepared emulsion to the burner unit 150 .

The shut-off valve 135 is connected to the outlet pipe 134 to block or open the emulsion supplied to the burner unit 150 through the outlet pipe 134 .

The emulsion pump 136 is connected to the shut-off valve 135 and pumps the emulsion through the shut-off valve 135 and supplies it to the burner unit 150 .

The emulsion usage meter 137 is connected to the outlet pipe 134 , and measures the usage amount of the emulsion supplied to the burner unit 150 through the shut-off valve 135 .

The controller 138 controls the driving of the components of the emulsion production unit 130 (eg, shut-off valve 135, emulsion pump 136, emulsion usage meter 137, etc.).

In one embodiment, the controller 138 receives data notified from each instrument related to the operation of the emulsion production unit 130 through the wire 13, and adjusts each instrument according to a preset and stored program. can give

The emulsion production unit 130 having the above-described configuration may include a plurality of emulsion storage tanks 1301 connected to each other, as shown in FIG. 4 .

The emulsion storage tank 1301 stores the prepared emulsion.

The emulsion production unit 130 having the configuration as described above, as shown in FIG. 4, is installed in each emulsion storage tank 1301, respectively, in the emulsion stored inside each emulsion storage tank 1301. A plurality of emulsion level measuring equipment 1302 may be further provided to measure the water level for each.

The emulsion production unit 130 having the above-described configuration, as shown in FIG. 4, is installed on the inlet side of each emulsion storage tank 1301, respectively, to receive or block the prepared emulsion. A plurality of discharge shutoff valves 1304 installed on the outlet side of the charging shutoff valve 1303 and each emulsion storage tank 1301 to discharge or block the emulsion stored in each emulsion storage tank 1301, respectively. ) may be further provided.

The emulsion production unit 130 having the configuration as described above, as shown in FIG. 4, is connected to each take-out shut-off valve 1304, and is carried out through each carry-out shut-off valve 1304, and the burner unit 150. It may further include a supply amount measuring instrument 1305 for measuring the supply amount of the emulsion supplied to the

The emulsion production unit 130 having the configuration as described above, as shown in FIG. 4, is connected to each take-out shut-off valve 1304, and is carried out through each carry-out shut-off valve 1304, and the burner unit 150. It may further include a moisture meter 1306 for measuring the amount of moisture in the emulsion supplied to the

The emulsion production unit 130 having the configuration as described above, as shown in FIG. 4, may further include a tank pump 1307 and a driver 1308.

The tank pump 1307 pumps the emulsion through each discharge shut-off valve 1304 according to the adjustment of the actuator 1308 and supplies it to the burner unit 150 .

The actuator 1308 is a component of the emulsion production unit 130 (eg, the emulsion level measuring device 1302, the charging shutoff valve 1303, the unloading shutoff valve 1304, the supply amount measuring device 1305, the moisture meter 1306, the tank pump 1307, etc.).

In one embodiment, the actuator 1308 receives data notified from each instrument related to the operation of the emulsion production unit 130 through the wire 13, and adjusts each instrument according to a preset and stored program can give

In one embodiment, the actuator 1308 is a data provided by the supply amount meter 1305 and the moisture meter 1306 (that is, the supply amount of the emulsion measured by the supply amount meter 1305 and the moisture meter 1306) According to the measured amount of water), it is possible to determine the output signal parameter of the streamer generated by the streamer generating unit 140 in response thereto, and the determined output signal parameter to the streamer generating unit 140 ) can be entered.

FIG. 5 is a view for explaining the streamer generator shown in FIG. 1 .

Referring to FIG. 5 , the streamer generating unit 140 includes a first MHHRG 141 , a second MHHRG 142 , an electrode 143 , a purifier 144 , a gas cleaner 145 , and an outlet 146 . can

The first MHHRG 141 generates a first streamer and delivers it to the burner unit 150 .

In an embodiment, the first MHHRG 141 may generate a corresponding first streamer according to an output signal parameter input from the driver 1308 .

The second MHHRG 142 generates a second streamer and delivers it to the electrode 143 .

In an embodiment, the second MHHRG 142 may generate a corresponding second streamer according to an output signal parameter input from the driver 1308 .

The electrode 143 is installed inside the purifier 144 , receives the second streamer from the second MHHRG 142 , and discharges the second streamer to the inside of the purifier 144 .

The purifier 144 purifies the exhaust in the form of dust or gas generated after combustion in the burner unit 150 by the second streamer discharged through the electrode 143 .

In one embodiment, the purifier 144 is a device for electrodynamic purification of an emission such as dust or gas, and using the electrode 143 from which the streamer generated by the second MHHRG 142 is discharged, the burner unit ( 150) can almost completely purify the dust or gaseous emissions generated after combustion.

The gas scrubber 145 captures the effluent purified by the purifier 144 , removes impurities from the captured effluent, and delivers it to the outlet 146 .

In one embodiment, the gas scrubber 145 may be a conventional purification device, for example, a scrubber.

The exhaust port 146 discharges the exhaust from which impurities are removed from the gas cleaner 145 to the atmosphere.

In one embodiment, the outlet 146 may be formed in the form of a high chimney having a preset height, so that the exhaust discharged to the atmosphere meets environmental standards.

FIG. 6 is a view for explaining the burner unit in FIG. 1 , and FIGS. 7 and 8 are views for explaining the purification effect of exhaust gas from the burner unit in FIG. 1 .

6 to 8 , the burner unit 150 includes a three-way valve 151 , a centrifugal pump 152 , a fuel heater 153 , a nozzle for ignition combustion 154 , and a burner ( 155) can be provided.

The three-way valve 151 receives thermal energy from the outside or receives thermal energy generated by combustion of the burner 155 and provides it to the fuel heater 153 .

The centrifugal pump 152 recovers thermal energy used by the fuel heater 153 and supplies it to the burner 155 .

The fuel heater 153 is connected between the emulsion production unit 130 (ie, the tank pump 1307) and the burner 155, and receives thermal energy from the three-way valve 151 when the burner 155 is ignited. The emulsion supplied from the emulsion production unit 130 is heated and delivered to the ignition and combustion nozzle 154 .

In one embodiment, the fuel heater 153 may be configured as a set together with the three-way valve 151 and the centrifugal pump 152 , and also heat energy generated by combustion of the burner 155 by using the three-way valve 151 . Through partial use, the emulsion supplied from the emulsion production unit 130 may be heated.

In one embodiment, when an emulsion containing a large amount of liquid (water) is supplied to the burner 155 of the burner unit 150, all temperature processes are stabilized by the boiling point of water, that is, in this case, the water acts as a thermal brake. Since this is highly undesirable in the burner 155, the fuel heater 153 can significantly increase the combustion efficiency of the emulsion by sufficiently heating the emulsion before it is fed to the nozzle 154 in the burner 155. have.

In one embodiment, the fuel heater 153 may reduce the viscosity of the emulsion upon heating to facilitate pumping of the emulsion, and may also remove water from the emulsion in liquid form (at least 99% of the water is in the form of steam). , thereby providing favorable conditions for heating other components (hydrocarbons) of the emulsion, and heating to a boiling point temperature level to create optimal conditions necessary for successful combustion. In this case, water vapor may reduce the emission of nitrogen oxides and other harmful combustion emissions, and may also increase combustion efficiency.

The nozzle 154 for ignition and combustion is formed inside the burner 155 and sprays the emulsion supplied from the emulsion production unit 130 .

The burner 155 discharges the emulsion sprayed from the ignition combustion nozzle 154 to the streamer supplied from the streamer generating unit 140 (ie, the first MHHRG 141) to completely burn it, and It converts the emulsion into thermal energy (or power energy) through

In an embodiment, the burner 155 may burn the emulsion sprayed from the ignition combustion nozzle 154 using the discharge of the first streamer generated by the first MHHRG 141 as EPSB.

In one embodiment, since the combustion rate and degree of combustion of all fuels, including the emulsion, depend on the size of the reaction area, in order to increase the reaction surface of the emulsion, the burner 155 is used close to the outlet of the nozzle 154. it's good

In one embodiment, the burner 155, in resonance, due to the effects of the streamer discharge, the flame immediately crushes the emulsion droplets into small particles, increasing the reaction surface of the fuel by about 200 times and increasing the combustion reaction itself by up to 5 times. can accelerate it.

In an embodiment, the burner 155 may partially decompose water molecules into oxygen and hydrogen when they collide with carbon molecules, and partially decompose oxygen in the air into ozone and active oxygen, in which case the decomposed hydrogen The atoms can diffuse rapidly into the saturated ozone region, raising the combustion temperature, allowing the fuel to burn almost completely. This phenomenon may appear as shown in FIG. 7 . That is, FIG. 7 is a view for explaining the purification effect of the exhaust gas in the burner unit shown in FIG. 1 . Here, (a) of FIG. 7 shows the general combustion of fuel (ie, combustion without a streamer), and (b) of FIG. 7 shows combustion using a streamer discharge (ie, combustion of exhaust gas without emulsion with a streamer) is shown.

8 is a view showing the combustion of the emulsion using the streamer discharge in the burner unit shown in FIG. Referring to FIG. 8 , the length of the flame may be 800 mm (in some burners 155, the length of the flame is 1200 mm).

The burner unit 150 having the above-described configuration can maintain the liquid content in the emulsion in the range of 30 to 70% when the ESPB (ie, the burner 155) is used.

The burner unit 150 having the above-described configuration is a liquid hydrocarbon and liquid in the burner 155 using the discharge of the streamer generated with parameters of a voltage of 150 to 250 KV and a frequency of 450 to 550 KHz in the first MHHRG 141 . Almost complete combustion can be achieved by combining various At this time, the specific value of the signal parameter of the first MHHRG 141 depends on the percentage of liquid hydrocarbon and liquid in the emulsion. At the same time, since the combustion rate is increased due to the appearance of ozone, active oxygen and hydrogen atoms generated in the decomposition process, it is possible to greatly reduce the air consumption in the combustion chamber of the burner 155 . In addition, the content of SOX, NOX and vanadium compounds in the exhaust gas decreases in proportion to the proportion of liquid in the emulsion, which can greatly reduce the abrasion of the convection surface.

9 is a flowchart illustrating a method of operating an energy production system using an emulsion according to an embodiment of the present invention.

Referring to FIG. 9 , the fuel supply unit 110 supplies the liquid fuel containing hydrocarbons to the emulsion production unit 130 ( S901 ).

In supplying the liquid fuel in the above-described step S901, in the fuel supply unit 110, as a hydrocarbon-containing liquid fuel, for example, heavy oil of any quality, waste cooking oil, biodiesel, crude oil residue, livestock complex and poultry farm liquid waste , and not only fuel oil, but also lubricating oil, waste oil, lubricating coolant, naphtha sludge, etc. may be collected and supplied to the emulsion production unit 130 by collecting at least one or more.

In supplying the liquid fuel in the above-described step S901, the fuel supply unit 110, it is possible to supply the liquid hydrocarbon fuel (LHF) to the emulsion production unit (130).

At the same time as supplying the liquid fuel in the above-described step S901, the liquid supply unit 120, the liquid is supplied to the emulsion production unit 130 (S902).

In supplying the liquid in the above-described step S902, the liquid supply unit 120 collects at least one or more of, for example, general industrial water, domestic sewage, sewage or waste water as water, and supplies it to the emulsion production unit 130. can give

When the liquid is supplied in the above-described step S902, the emulsion production unit 130 receives the hydrocarbon-containing liquid fuel from the fuel supply unit 110 and receives the liquid from the liquid supply unit 120, and the supplied hydrocarbon containing liquid fuel and The liquid is mixed to produce an emulsion, and the produced emulsion is delivered to the burner unit 150 (S903).

In producing and delivering the emulsion in step S903 described above, in the emulsion production unit 130, the hydrocarbon-containing liquid fuel supplied from the fuel supply unit 110, without additives such as a surfactant, is supplied from the liquid supply unit 120. and 3:7 can be mixed to form an emulsion and supplied to the burner unit 150 .

In producing and delivering the emulsion in step S903 described above, in the emulsion production unit 130, a pump, a mixer, etc. may be combined to form a mixer. Accordingly, in the emulsion production unit 130, the liquid hydrocarbon fuel (LHF) supplied from the fuel supply unit 110 and the liquid supplied from the liquid supply unit 120 are mixed by a mechanical mixing method using the mixer to produce an emulsion (FLE). can make

In producing and delivering the emulsion in step S903 described above, in the emulsion production unit 130 having a separate emulsion production equipment (FLEC), the liquefied hydrocarbon fuel (LHF) supplied from the fuel supply unit 110 using the FLEC ) and the liquid supplied from the liquid supply unit 120 can be mixed in a ratio of 30 to 70% and 30 to 70% to produce an emulsion (FLE).

In producing and delivering the emulsion in step S903 described above, in the emulsion production unit 130, the heavy oil supplied from the fuel supply unit 110 and the water supplied from the liquid supply unit 120 are mixed at a mixing ratio of 20%: 80%. It can also produce an emulsion (FLE).

At the same time as producing and delivering the emulsion in step S903 described above, the streamer generating unit 140 generates a streamer and delivers it to the burner unit 150 (S904).

In generating and delivering the streamer in step S904 described above, in the streamer generator 140 having a high-pressure and high-frequency pulse generator (or a high-pressure and high-frequency plasma generator), the pulse generator (or plasma) generator) to generate a streamer as shown in FIG. 2 and deliver it to the burner unit 150 to be discharged.

In generating and delivering the streamer in step S904 described above, the streamer generating unit 140 may include two multifunctional high voltage and high frequency resonance generators (MHHRG).

In generating and delivering the streamer in step S904 described above, in the streamer generating unit 140 , the first MHHRG for generating and delivering the streamer to the burner unit 150 , and after combustion in the burner unit 150 . A second MHHRG for purifying the generated dust or gaseous emission may be provided.

In generating and transmitting the streamer in step S904 described above, the first MHHRG has a voltage of 150 to 250 KV and a frequency of 450 to 550 KHz, and the second MHHRG has an exit signal with a period of 1 to 5 seconds and 5 to It has a duty cycle of 10, a voltage of 100 to 200 KV, and a frequency of 450 to 550 KHz.

In generating and transmitting the streamer in step S904 described above, in the streamer generating unit 140, when the second MHHRG is used, the characteristic values are as follows. has a duty cycle of, the voltage is 100~200KV, and the frequency is 150~1100KHz.

In generating and delivering the streamer in step S904 described above, the streamer generating unit 140 may generate a corresponding streamer according to the output signal parameter input from the emulsion production unit 130 .

When the streamer is generated and delivered in the above-described step S904, the burner unit 150 receives the emulsion delivered from the emulsion production unit 130 and receives the streamer delivered from the streamer generating unit 140. The supplied emulsion is discharged to the supplied streamer to proceed with combustion (S905).

In the combustion in step S905 described above, in the burner unit 150 having a combustion device (burner) of 2.5 mega or 5.0 mega, using the combustion device (burner), the emulsion production unit 130 supplied from By discharging the emulsion to the streamer supplied from the streamer generating unit 140, it can be completely burned.

In the combustion in step S905 described above, in the burner unit 150 having a combustion device (burner) of 2.5 mega or 5.0 mega, the hole size of the nozzle provided in the combustion device (burner) is determined by the emulsion production unit ( 130) can be formed in a size corresponding to the flow and combustion of the emulsion supplied from it.

In the combustion in step S905 described above, in the burner unit 150 having a control valve for controlling the amount of the emulsion supplied from the emulsion production unit 130, the emulsion production unit 130 using the control valve. By controlling the amount of the emulsion supplied from the streamer generation unit 140, it is also possible to discharge to the streamer supplied from the complete combustion.

In the combustion in step S905 described above, the burner unit 150 may include an electrically powered pulse burner (EPSB).

In proceeding combustion in the above-described step S905, in the burner unit 150, the streamer generated by the streamer generating unit 140 is applied to the outlet side of the nozzle to completely burn the emulsion supplied from the emulsion production unit 130. can make you do it

The operation method of the energy production system using the emulsion according to an embodiment of the present invention having the configuration as described above is the air of the purifier 144 provided in the streamer generating unit 140 - Formation of a streamer in a smog environment As a result, in the case of oxidation and afterburning treatment of exhausts in the form of dust, gas, it can be made violent by accelerating the oxidation of unburned residues of organic origin with the formation of ozone and oxygen.

In the operating method of the energy production system using the emulsion according to an embodiment of the present invention having the configuration as described above, the destruction of complex radicals and hydrocarbons by the high oxidizing power and chemical activity of ozone and oxygen, pollution removal , can be effective in neutralizing dust and gas emissions.

The operating method of the energy production system using the emulsion according to the embodiment of the present invention having the configuration as described above, the active oxidizer strongly mixed with the pure gas, an important promotion of combustion, and a large amount in the merge and gas exhaust part It can provide re-oxidation of toxic substances.

FIG. 10 is a view for explaining an exhaust gas purification process using a streamer after the combustion progress step in FIG. 9 .

Referring to Fig. 10, the process of neutralizing dust and gas emissions is shown, i.e., a fragment of a high-speed video recording of a previous contaminant purification process in the reactor. Here, the time interval between adjacent fragments is about 10 ms. In FIG. 10 , the image corresponds to the moment of full bloom of the reactor (ie, the neutralization treatment of dust and gas exhaust in the last about 30 ms), indicating the onset of the high voltage pulse shape of the second MHHRG 142 .

Considering the slow movement of exhaust such as dust and gas, it produces an output signal in the form of a pulse train with a period in the range of 1 to 5 and an operation cycle of 5 to 10, with an amplitude ranging from 100KV to 200KV and frequencies ranging from 150KHz to 1100KHz. In order to select the pulse parameters, provided by the second MNNRG 142 , the refiner 144 is reinforced. In this case, the specific value of the parameter depends on the percentage of LHF and liquid in the fuel emulsion, the power of the power generating device, the area of the cross section of the outlet, the height of the outlet of the power plant, and the like.

11 is a view for explaining the comparison of the economic feasibility of each fuel of the operating method of the energy production system using the emulsion according to an embodiment of the present invention.

Referring to FIG. 11 , economic efficiency can be evaluated based on a virtual power facility with a capacity of 2 mW. Natural gas, heavy oil, and an emulsion with a liquid content of 70% are compared, and the fuel price is open source as of December 2016. The alternative fuel prices are calculated based on data from open sources.

11, for the same amount of energy produced, the cost of emulsion fuel is about 16 times less than that of heavy oil and about 11.5 times less than that of natural gas. In terms of energy costs, it is well understood that emulsion fuels are advantageous over traditional fuels. This results in reduction of air use, reduction of CO2 as well as SOX, NOX and vanadium compounds in dust-gas emissions, improvement of the environment as a result of treatment of industrial and domestic waste, and energy production using electric and/or thermal emulsions in thermal power plants, power plants. The proposed invention group boiler houses and other energy facilities that use liquid hydrocarbon fuels to recover energy are very attractive from a scientific, technical and commercial point of view. The individual parts of the equipment manufactured according to the present invention are general ones freely available for purchase.

As such, the present invention comprehensively solves the problem of producing biofuel while processing industrial and household waste, effectively converting this fuel into electricity and/or thermal energy, and ensuring high-quality purification of exhaust gas.

Above, the embodiment of the present invention is not implemented only through the above-described apparatus and/or operation method, but through a program for realizing a function corresponding to the configuration of the embodiment of the present invention, a recording medium in which the program is recorded, etc. It may be implemented, and such an implementation can be easily implemented by an expert in the technical field to which the present invention pertains from the description of the above-described embodiments. Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improved forms of the present invention are also provided by those skilled in the art using the basic concept of the present invention as defined in the following claims. is within the scope of the right.

100: energy production system using an emulsion
110: fuel supply unit
120: liquid supply unit
130: emulsion production department
131: first inlet pipe
132: second inlet pipe
133: third inlet pipe
134: outlet pipe
135: shut-off valve
136: emulsion pump
137: Emulsion Usage Meter
138: controller
1301: emulsion storage tank
1302: emulsion level measuring equipment
1303: charging shut-off valve
1304: carry-out shut-off valve
1305: supply meter
1306: moisture meter
1307: tank pump
1308: actuator
140: streamer generating unit
141: first MHHRG
142: second MHHRG
143: electrode
144: refiner
145: gas scrubber
146: outlet
150: burner unit
151: three-way valve
152: centrifugal pump
153: fuel burner
154: ignition combustion nozzle
155: burner

Claims (5)

a fuel supply unit for supplying liquid fuel containing hydrocarbons; a liquid supply unit for supplying a liquid; an emulsion production unit for producing and delivering an emulsion by mixing the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit; a streamer generating unit for generating and delivering a streamer; and a burner unit for discharging the emulsion delivered from the emulsion production unit to a streamer delivered from the streamer generating unit to proceed with combustion; The emulsion production unit mixes the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit in a ratio of 3:7 without an additive of a surfactant; The streamer generating unit may include: a first MHHRG for generating a streamer and delivering it to the burner unit; and a second MHHRG for purifying dust or gaseous emissions generated after combustion in the burner unit;
The burner unit includes a control valve for controlling the amount of emulsion delivered from the emulsion production unit in order to discharge the emulsion delivered from the emulsion production unit to the streamer delivered from the streamer generating unit to burn completely;
a tank for temporarily storing the emulsion delivered by the emulsion production unit; and a recovery valve for recovering the emulsion stored in the tank when a preset time elapses and supplying it back to the emulsion production unit.
According to claim 1, wherein the fuel supply unit,
Energy using an emulsion, characterized in that it collects and supplies at least one or more of heavy oil, waste cooking oil, biodiesel, crude oil residue, liquid waste from livestock complexes and poultry farms, fuel oil, lubricating oil, waste oil, lubricating coolant, and naphtha sludge production system.
According to claim 1, wherein the liquid supply unit,
An energy production system using an emulsion, characterized in that at least one or more of general industrial water, domestic sewage, sewage and wastewater is collected and supplied.
delete supplying liquid fuel containing hydrocarbons by the fuel supply unit; supplying a liquid by a liquid supply unit; The emulsion production unit mixing the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit to produce and deliver an emulsion; A streamer generating unit generating and delivering a streamer; and discharging the emulsion delivered by the burner unit from the emulsion production unit to the streamer transmitted from the streamer generating unit to proceed with combustion; The emulsion production unit mixes the liquid fuel supplied from the fuel supply unit and the liquid supplied from the liquid supply unit in a ratio of 3:7 without an additive of a surfactant; The streamer generating unit may include: a first MHHRG for generating a streamer and delivering it to the burner unit; and a second MHHRG for purifying dust or gaseous emissions generated after combustion in the burner unit;
The burner unit includes a control valve for controlling the amount of emulsion delivered from the emulsion production unit in order to discharge the emulsion delivered from the emulsion production unit to the streamer delivered from the streamer generating unit to burn completely;
a tank for temporarily storing the emulsion delivered by the emulsion production unit; and a recovery valve for recovering the emulsion stored in the tank when a preset time elapses and supplying it back to the emulsion production unit.

Images