KR101372948B1 - The waste heat recovery system using combustible wastes incinerator - Google Patents

Abstract

The present invention is a high-efficiency eco-friendly waste incineration dedicated heating furnace 100 and waste heat recovery boiler (200) and syngas boiler, the waste heat recovery boiler to generate steam with high-temperature gas generated by incineration of waste or waste solid fuel ( 200) and the combined heat and heat of the cogeneration generator to perform cogeneration to convert the energy generated by the heat generated from the syngas boiler and heating, and the heat and heat to circulate by cooling the heat supplied by using the waste heat of the cogeneration generator. An energy-saving eco-friendly waste treatment and resource system with a multi-stage energy circulation structure in which the exchanged heat exchanger is complementarily linked to each other, and is an environmentally friendly combustion of waste as a heat supply and heat exchange structure for energy to exchange waste heat of each independent process process organically. In addition to the waste treatment, The optimal recovery line configuration by organic combination of each process process line in one system device that is connected to supply power generation, heating water and hot water organically. Combined synergistic effects, such as recycling and improved heat exchange capacity, prevent global warming and environmental pollution, and improve the overall energy efficiency of waste combustion treatment, cogeneration and heating systems.

Description

Environment-friendly multi-energy resource recovery device linked with combustible waste heating furnace {The waste heat recovery system using combustible wastes incinerator}

The present invention relates to an environment-friendly multi-energy resource recovery apparatus in conjunction with a combustible waste heating furnace,

More specifically, high-efficiency eco-friendly waste incineration heating furnace 100 and waste heat recovery boiler 200 and steam generated by high-temperature gas generated by incineration of waste or waste solid fuel, and a synthesis gas boiler, the waste heat recovery boiler ( 200) and heat exchanger that exchanges heat with cooling water that circulates by cooling the waste heat of the cogeneration generator and the cogeneration generator to perform cogeneration to convert energy into power such as power generation and heating through steam generated in the syngas boiler. Energy-saving, eco-friendly waste treatment and resource recycling system with multi-stage energy circulation structure in which energy is complementary to each other.Environmentally friendly combustion treatment of waste as heat supply and heat exchange structure of energy that exchanges waste heat of each thermally independent process process organically. In addition to the heat generated from the combustion It is configured to connect heat and complementary, staged and selective exchange of heat in one system unit that is connected to supply power generation, heating water, and hot water organically. 'S eco-friendly treatment, combined with the synergistic effect of recycling unused energy that is not used effectively and improving heat exchange capacity, prevents global warming and environmental pollution, and improves the overall energy efficiency of waste combustion treatment, cogeneration and heating systems. There is an effect that can be improved.

      Korea is one of the countries that lack energy resources, energy saving is an essential task.

As fossil fuels, coal and petroleum, when burned, emit a lot of CO2, which causes air pollution and global warming.

In addition, due to the development of the industrial society and the improvement of living standards, the amount of combustible wastes such as waste wood, waste fiber, waste paper, and waste plastic is gradually increasing.

Although Korea is one of the countries with insufficient energy resources, energy saving is an essential task, but the utilization rate of heat generated by incineration facilities is very low in terms of waste disposal, rather than as energy.

In particular, in treating wastes generated at home, offices, and workplaces in a huge amount every day, conventional methods of treating air by air use carbon dioxide (CO ₂ ), carbon monoxide (CO), sulfur oxides (SOx), due to incomplete combustion or insufficient treatment. Nitrogen oxides (NOx), dust, etc. are generated, there is a technical problem that causes secondary environmental pollution by polluting the air or landfill ash by-produced,

The air-based combustion method is strengthening the environmental standard value by international conventions such as setting the total amount of emission by each country by emitting a large amount of carbon dioxide, which is considered as the main cause of global warming, and the complete resource and zeroization of waste is emerging as a national issue. have.

Therefore, in addition to the treatment of environmentally friendly wastes, various methods are being developed to utilize the heat source from the treatment.

The conventional waste treatment method is to reduce the energy efficiency of incineration residues or useful materials not recovered when the final product is incomplete or incinerated, and to secure a separate landfill to bury incineration residues. Etc. There was a problem.

The present inventors patent application 10-2004-0007109 (2004.02.04) "manufacturing method of solid fuel using waste plastic" and patent application as a prior art of waste recycling solid fuel (RDF) that promotes combustion and minimizes pollution Patent No. 10-2004-0007108 (2004.02.04) as a method of manufacturing solid fuel using waste tires or waste rubber products, "a method of manufacturing solid fuel recycled flammable waste (RDF)" and a combustor dedicated to flammable waste No. 10-2002-0087996 (December 31, 2002) has proposed, respectively, "a top-down multistage burner using waste rubber processed solid fuel."

However, the above-mentioned waste recycling solid fuel (RDF) manufacturing technology or a combustor using flammable industrial waste as an alternative fuel contributed to reducing environmental pollution by primarily minimizing the pollution caused by landfill and incineration of flammable waste. There is a problem in that the waste management has not been effectively utilized as an alternative energy source that satisfies the energy recovery standards.

Therefore, the present inventors minimize the pollution caused by landfilling and incineration of wastes, secondary pollution by landfilling of incinerators, and at the same time, efficiently converts them into energy sources, thereby releasing various environmental pollutants generated during the waste treatment process by recycling greenhouse gases. As a device that can drastically reduce energy consumption and actively use it as an alternative energy source, we have developed an energy-saving, eco-friendly waste recycling device that combines a furnace and a heat exchanger using flammable waste as fuel.

However, the above-mentioned device is an energy-saving eco-friendly waste resource recycling device that can save resources and recover energy while reducing the burden of combustible waste treatment by effectively utilizing heat sources from the treatment as well as environmentally friendly waste treatment. High temperature fluids such as steam and exhaust gas cannot be effectively used in each process such as plants, and thus there is a problem in that it is not reasonable in terms of thermodynamics and economics such as smooth response of energy loads and comprehensive thermal efficiency improvement due to economic operation.

In addition, the cogeneration system is a high efficiency energy utilization technology that uses two types of energy, heat and power, from primary energy such as petroleum, coal, and gas, and recycles waste heat (array) generated in the power production process. It can contribute to cost reduction and cost reduction, and can actively respond to environmental protection by reducing air pollution and seasonal imbalance of electricity and heat demand, but the demand is gradually increasing, but it is relatively expensive compared to the initial investment cost. There was a problem using fuel.

In addition, the conventional cogeneration system has a problem in that the heat loss is largely generated because the waste heat and the engine array of the exhaust gas discharged after generating power from the cogeneration generator are not directly discharged or not properly recovered and recycled.

Therefore, the present inventors minimize the pollution caused by landfilling and incineration of wastes, secondary pollution by landfilling of incinerators, and at the same time, efficiently converts them into energy sources, thereby releasing various environmental pollutants generated during the waste treatment process by recycling greenhouse gases. Efforts to develop a device that can significantly reduce the energy at the same time as an active alternative to the energy has completed the present invention.

As described above, the conventional waste treatment and recycling apparatus has various problems.

By treating wastes in an environmentally friendly way, organic gasification and molten slag recycling minimize the pollution caused by landfilling and incineration of wastes, and secondary pollution by incineration ashes.

In order to recycle the exhaust gas, waste heat is recovered in the process of efficient purification and heat recovery cooling, steam is produced, and energy is efficiently recycled to reduce the emission of various environmental pollutants generated during the waste treatment process by recycling the greenhouse gas. At the same time, it is an eco-friendly multi-energy resource linked with a combustible waste-only heating furnace that realizes a complex synergy effect such as recycling waste energy that is not used effectively and releasing unused energy that is not effectively used and improving heat exchange capacity so that it can be actively utilized as an alternative energy source. It is intended to construct a recovery device.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art,

  As a waste energy-enhancing facility, a combustible waste solid fuel (RDF) or a combustible waste is burned in an environment-friendly way, and a furnace for supplying hot water using heat generated during the incineration of waste,

   At the rear of the furnace, waste heat is recovered from the high-temperature combustion gas generated from the furnace and supplied to heat sources of heat demand such as cogeneration and heating facilities, and the waste heat recovery boiler of the energy saving type that emits exhaust gas into the atmosphere is interconnected. Link and configure the resourceization device,

   After the waste heat recovery boiler, the exhaust gas discharged from the waste heat recovery boiler is subjected to a gas purification process of dust collection, desulfurization, denitrification, and cooling in a gas purification processing device that is continuously configured, so that the gas that meets the standards of the air pollution preservation method after combustion is atmosphere. In the process of releasing the gas to form a gas purification treatment discharge line for the synthesis gas boiler to recover the waste heat again and use it for heating or power generation,

 The heating furnace is connected to the hot water supply line for supplying heat (hot water) to the heat storage tank or heating demand,

In addition, the heat generated from the waste heat recovery boiler and the synthesis gas boiler is supplied from the steam header to transfer the heat heated by the cogeneration generator to the heat exchanger and the heat transferred from the boiler water circulation pipe and the boiler water circulation pipe to return to the waste heat recovery boiler. It is a multi-energy recovery system consisting of a heating water supply line that is supplied from a heat exchanger to a heating demand source for heating and hot water supply, and provides high-efficiency cogeneration and multiple energy recovery devices in connection with a combustible waste heating furnace. The purpose is to.

As described above, the eco-friendly multi-energy resource recovery device in conjunction with the combustible waste heating furnace of the present invention is a parallel heat supply facility.

In addition to environmentally friendly combustion treatment of wastes, the heat generated from the combustion and purification process of wastes is used to prevent global warming and environmental pollution by combining power supply, heating water, and hot water supply in one organically connected system. The overall energy efficiency of waste combustion and cogeneration systems and heating systems can be improved.

In particular, the present invention is a heat supply and heat exchange structure of energy to exchange the waste heat of each process process consisting of a multi-stage continuous unit process with each other organically, and in addition to the environmentally friendly combustion treatment of the waste, the heat generated during the combustion purification process of the waste Complementary, stepwise and selective exchange of heat in one system unit that is connected to supply power generation, heating water and hot water by using organically. In addition to the eco-friendly treatment of wastes, the combined synergistic effect of recycling unused energy that is not effectively used and released and improving heat exchange capacity prevents global warming and environmental pollution and prevents waste combustion treatment, cogeneration and heating systems. To improve energy efficiency It is effective.

The present invention has a wide range of scalability from small furnace to large power plant to convert waste into high value-added energy by linking various resources (combustion, waste heat recovery, power generation, cogeneration, heating water, etc.) I can make it

In particular, by additionally forming a heating system connected with the cogeneration generator, waste heat (exhaust steam, etc.) generated from an engine or turbine generating electricity can be efficiently recovered to prevent heat loss, thereby contributing to the prevention of environmental pollution, treatment cost reduction, and energy saving. In addition, the waste disposal costs are lowered due to sales revenue from heat supply and electricity sales, and the waste heat can be recovered and recycled as an energy source to reduce energy costs and promote profitability through energy resale.

Figure 1 is a block diagram schematically showing the flow and configuration of the environment-friendly multi-energy resource recovery device associated with the combustible waste dedicated heating furnace of the present invention
Figure 2 is a cross-sectional configuration showing a combustible waste solid fuel-only heating furnace of the present invention Figure 3 is a system configuration showing the overall configuration of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention for achieving the above object will be described in detail with reference to the accompanying drawings, and detailed descriptions of well-known components that may unnecessarily obscure the subject matter of the present invention will be omitted.

The present invention is an environment-friendly multi-energy resource recovery device in conjunction with a combustible waste heating furnace,
A furnace 100 for burning environmentally friendly fuel using flammable waste solid fuel (RDF) or combustible waste as a fuel and supplying hot water using heat generated during the incineration of waste as a waste energy-enhancing facility;
The rear end of the heating furnace 100 is configured to link the waste resource recovery device is provided with a waste heat recovery boiler 200 for recovering waste heat from the high-temperature exhaust gas generated in the heating furnace 100,
At the rear end of the waste heat recovery boiler 200, the exhaust gas discharged from the waste heat recovery boiler 200 is subjected to a gas purification process of dust collection, desulfurization, denitrification, and cooling in a group of gas purification treatment units configured in a continuous manner. Further forming a gas purification treatment discharge line (E) for releasing a gas meeting the standards of
The heating furnace 100 is connected to the hot water supply line (A) for supplying heat (hot water) to the heat storage tank 330 or the heating demand (500),
In addition, the steam generated from the waste heat recovery boiler 200 and the synthesis gas boiler 230 is supplied from the steam header 260 to transfer the heat generated by the cogeneration generator 300 to the heat exchanger 310 and to waste heat recovery boiler ( The boiler water supply line (B) that returns back to 200 and the heat transferred from the boiler water supply line (B) is supplied from the heat exchanger (310) and supplies the heating water for heating and hot water supply to the heating heat demand destination (500). The returning heating water supply line (C) is a combined multiple energy recovery device,

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In addition to environmentally friendly combustion treatment of wastes, the power generation, heating water and hot water supply functions are combined in one organically connected system using the heat generated during the combustion and purification process of wastes. Contributing to energy saving and reducing the generation of harmful substances, it is environmentally friendly, so it is connected with a combustible waste heating furnace that prevents global warming and environmental pollution, and improves the overall energy efficiency of waste combustion treatment, cogeneration and heating systems. High efficiency cogeneration and multiple energy recovery devices

Hereinafter, preferred embodiments of the present invention will be described in more detail.

As described above, the present invention is an energy-saving eco-friendly waste resource recycling device that connects a dedicated heating furnace 100 and a waste heat recovery boiler 200 that use flammable waste as fuel, and contributes to energy saving by recycling waste resources made of flammable waste. It is an eco-friendly, multi-energy resource recovery system that is linked to a furnace dedicated to environmentally friendly flammable waste that reduces the generation of harmful substances.

The dedicated heating furnace 100 using the combustible waste as a fuel is disclosed in the patent application No. 10-2011-54975 filed by the present inventors in "Energy-saving eco-friendly waste recycling apparatus linked to a heat exchanger and a heat exchanger using the combustible waste as fuel" The same device as the adopted heating furnace 100,

Flammable waste such as waste rubber or plastic or flammable waste processing such as waste rubber or waste synthetic resin The solid fuel is heated to a high temperature of 1300 ℃ or higher, and the downward multistage direct combustion method is used to prevent the emission of harmful gases such as dioxins or heavy metals. As a combustion furnace 100 to treat waste by completely burning the waste gas and supply it to the waste heat recovery boiler at the rear end,

The construction consists of a wall 102 made of a steel fire-resistant steel plate coated with a refractory paint to withstand high thermal shocks of 1300 ° C. or more on the outer periphery of the rectangular enclosure-shaped body 101 in which the combustion chamber is divided into three stages. ) The inner edge stores water (water) supplied from the water supply 180 and is heated by the high temperature combustion heat of the heating furnace 100 so that hot water is supplied to the hot water supply line (A) without a separate heating means (500) or The water heating unit 104 for supplying the heat storage tank is formed,

In the middle of the upper portion of the waste inlet 105 and directly in communication with the hopper 110 for injecting the combustible waste or combustible waste processing solid fuel continuously transported from the waste transport conveyor 111, one side of the lower body 101 Combustion material outlet 106 for discharging the combustion material to the outside is formed, and the other side is formed with a gas outlet 107 for supplying a high temperature combustion gas to the heat exchanger or waste heat recovery boiler 200, respectively, The combustion gas is discharged and supplied to the waste heat recovery boiler 200, and the hot water heated by the combustion heat of the flame is also supplied to the heat demand directly or to the heat storage tank 330 by the hot water supply line (A). It is formed to efficiently use the heat generated in the heating furnace.

The heating furnace 100 of the present invention is an indefinite refractory material, instead of a castable, water flows between the inner and outer walls of the heating furnace wall 102 to produce hot water as combustion heat and move into the body. In order to form the heating part 104, the wall 102 is formed of a steel refractory steel plate coated with a refractory paint.

The body 101 of the heating furnace is installed by installing the ignition burner 121 for ignition on one side of the wall 102 and the lower stall 122 that swings from side to side in conjunction with a driving motor at the bottom. The combustion chamber 120 is configured to directly burn solid fuel falling from the hopper 110 at a high temperature, and unburned gas and combustion residues are dropped into the secondary combustion chamber 130.

In addition, the secondary combustion chamber 130 formed under the primary combustion chamber 120 has a combustion gas passage through which unburned gas and residues pass between unit heat filter blocks 131 in which air blow holes 133 are integrally formed ( A plurality of horizontally speaking 134 are formed, and the combustion gas passage 134 formed at the center of the heat filter block 131 and the outer circumference of the heat filter block 131 of the spaced space structure communicates with the blower 135 to form a pressure. By supplying the high-speed reciprocating air with a low loss and a large downward suction force, it becomes continuous and explosive combustion, so that the combustion gas incompletely burned in the primary combustion chamber 120 is reburned and completely burned.

In addition, a combustion material conveying screw 109 driven by a motor is mounted in the lower portion of the secondary combustion chamber 130 to be automatically discharged through a combustion material outlet 106 having an opening / closing door that opens and closes as necessary.

That is, the flammable waste heating furnace 100 of the present invention is a direct flame furnace of flame pyrolysis type, as in the conventional multistage combustion device proposed by the present applicant,

 The primary combustion chamber 120 and the secondary combustion chamber 130 are in the center of the heating furnace 100, and the tertiary combustion chamber 140 is a side flue end space partitioned as a gas moving space communicating with the secondary combustion chamber 130. By forming sequentially to

Flammable waste such as waste rubber or waste plastic or flammable waste processing such as waste rubber or waste synthetic resin The solid fuel is heated to a high temperature of 1300 ℃ or higher, and direct downward combustion is performed to prevent harmful gases such as dioxin or pollutants such as heavy metals. The waste gas is completely burned by the method, and the hot combustion gas generated during the incineration process is supplied to the waste heat recovery boiler 200 or the heat exchanger at a laterally through the gas outlet 107 to generate various combustible wastes without additional pollution. It's a complete process.

At the top of the furnace body 110, a hopper 110 collecting and loading combustible waste processing solid fuel formed into a predetermined size, such as combustible waste or pellets, which is automatically continuously supplied by the waste conveying conveyor 108, is disposed on top. Is formed in the lower combustion chamber 120 and is configured to communicate with the waste inlet 105,

The bottom of the funnel-shaped hopper 110 is equipped with a combustible waste transfer screw 111 in which a spiral rotating blade is continuously formed on a rotating shaft driven by a motor to stir and transport the combustible waste drop-supplied to evenly distribute the combustible waste. It is possible to form a stable waste discharge so that all the operation of transferring and injecting combustible waste into the furnace 100 to maintain a constant temperature in the furnace temperature of the furnace 100 to the set value under the control of a control device not shown. do.

In addition, the furnace 100 of the present invention selects combustible wastes such as waste synthetic resins or waste tires, except vinyl chloride or PVC-based plastics, which discharge a large amount of dioxin, instead of all of the combustible wastes having different characteristics. It is preferable to use the pulverized to a size of 5mm or less as a flammable waste regeneration fuel of the present inventors Patent Application No. 10-2004-0007109 (2004.02.04) "Manufacturing method of solid fuel using waste plastic" and Patent application No. 10-2004-0007108 (2004.02.04) uses the combustible waste solid fuel (RDF) manufactured by the manufacturing method of solid fuel using waste tires or waste rubber products to serve as an environmentally stable heat source. Can be done.

In the third combustion chamber 140, which is positioned to correspond to the heat filter block 131 on the side of the secondary combustion chamber 130, gas is generated in the secondary combustion chamber 130 to generate gas at the side wall 141 on the side of the heat filter block 131. By recycling the high-temperature flame gas discharged through the discharge hole 142, the embers are turned into a living state and mixed combustion of the combustion gas which is countercurrently contacted to be finally discharged to the outside through the gas discharge port 107,

In addition, it is preferable to facilitate the cleaning of the waste accumulated therein by forming a detachable detachable primary combustion chamber 120 equipped with the rostol 122 in the body of the heating furnace 100.

As a result, the heating furnace 100 of the present invention is a direct flame which pyrolyzes the combustible waste drop-fed supplied from the central hopper 110 of the heating body body 110 so that the solid fuel burns at a high temperature of 1300 ° C. or higher to be completely melted. A primary combustion chamber 120 and a secondary combustion chamber 130 having a multi-combustion structure in which a heat filter block 131 is formed below the primary combustion chamber 120 are formed, and the gas and residue burned in the primary combustion chamber 120 are exhaust gas passages. By supplying external air to the heat filter block 131 through the blower 135 to facilitate combustion while passing through the 134, the high-temperature combustion gas of the flame state incompletely combusted in the primary combustion chamber 120 with a strong blowing pressure. It is mixed with the supplied air to be reburned, and at the end space of the flue at a position corresponding to the heat filter block 131 on the side of the secondary combustion chamber to recycle the high temperature combustion gas generated in the secondary combustion chamber 130. formation In the third combustion chamber 140, the first combustion chamber and the second combustion chamber perform the two-stage combustion process and return the uncompressed combustion gas to the exhaust gas from the side wall 141 on the side of the heat filter block 131. By contacting with the high temperature secondary combustion chamber combustion gas strongly supplied through the ball 142 to make the recombustion, the unburned substances such as odor and pollutants are finally removed to remove the high temperature combustion gas from the waste heat recovery boiler (HRSG) ( 200) or a waste heat recovery heat exchanger (not shown).

In addition, the gas purification treatment discharge line (E) is sequentially connected to the rear end of the heating furnace 100, the gas purification treatment discharge line is a waste heat recovery boiler for the heat held by the gas discharged from the heating furnace (100) (HRSG) (200) and the waste heat recovery boiler (heat preheater) 210 attached to the waste heat recovery boiler and the waste heat recovery boiler unit for generating steam and supplying to the demand destination for each application, and heat exchange cooling in the waste heat recovery boiler unit Synthesis gas purification unit for collecting the treated exhaust gas through the gas purification process of dust collection, desulfurization, cooling, connected to the rear end of the synthesis gas purification apparatus unit to cool the exhaust gas flowing from the synthesis gas boiler 230 A chiller section to perform,

And it is connected to the stack (stack) 190 to discharge the flue gas (flue gas) passing through the cooling device to the atmosphere is configured to discharge the flammable waste or waste solid fuel by purifying the gas with high purity. The high-purity exhaust gas is supplied to a carbon dioxide recovery device (not shown) or discharges gas that meets the standards of the Atmospheric Environmental Conservation Act to the atmosphere, and at the same time recovers the waste heat from the syngas boiler 230 and recovers the steam header. It is configured to supply steam to the steam demand destination 700 or the cogeneration generator 300 through 260 to be utilized for multipurpose cogeneration or heating.

The waste heat recovery boiler 200 is connected to an economizer 210 for preheating purpose of recovering exhaust heat of the gas discharged from the waste heat recovery boiler 200 as an accessory, and complementary like the waste heat recovery boiler device 200. As an energy-saving configuration that recovers waste heat, purifies and recycles waste gas for use as fuel as a fuel, the waste gas recovery from the furnace 100 is recovered. Passes into the boiler 200 to generate steam (heat) through heat exchange, and the generated steam (steam) is supplied to the demand destination for each use through the steam header 260 or drives a steam turbine of the cogeneration generator 300. It can be used for versatile purposes such as process and heating, depending on the steam use.

Located in the rear end of the waste heat recovery boiler unit, the syngas purification processing unit which removes fine dust and sulfur contained in the gas generated by the waste pyrolysis gasification and is transported to highly refine the synthesis gas to a level usable as fuel. Acid gas such as bag filter (dust collector) 221, evaporative cooler 222, hydrochloric acid (HCL) contained in syngas, hydrogen sulfide (H ₂ S), and the like, which collect and filter a small amount of dust contained in exhaust gas. As a desulfurization apparatus for removing harmful substances, a hydrogen sulfide adsorption tower for adsorbing and removing H ₂ S (hydrogen sulfide), which is a odor generating substance in the exhaust gas primarily removed from a wet scrubber (wet scrubber) 223, is added. The booster fan 224, which blows the purified exhaust gas to the rear end synthesis gas boiler 230, is sequentially provided in the gas supply line and connected to the gas supply line.

In addition, the syngas boiler unit unit syngas discharged from the syngas boiler 230 and the syngas boiler 230 to recover the waste heat of the syngas blown by the booster fan 224 from the syngas purification unit unit of the front end Denitrification apparatus 233 (SCR, Selective Catalytic Reduction Denitrator) for removing the nitrogen oxides (NO _X ) in the inside and the economizer 232 for recovering the exhaust heat of the synthesis gas discharged from the syngas boiler 230 As an energy-saving configuration for recovering and recycling waste heat complementarily, such as waste heat recovery boiler 200, the syngas boiler apparatus 200 supplies oxygen to the syngas supplied at 45 ° C. and 5,250 Nm 3 / h. shown hereinafter), the oxygen and mixing was by the non-air injecting only oxygen (O₂), the boiler after the combustion of carbon dioxide (CO ₂₎ and water (H₂O combustion supplied from) the exhaust and carbon dioxide The configuration is able to capture.

In addition, in the syngas boiler 230, a denitrification apparatus (not shown) connected to nitrogen oxides (NO _X ) in the purified exhaust gas (FLUE GAS) passing through the water pipe of the syngas boiler 230 by a duct line (not shown) (SCR). After removing from, it is introduced into the economizer 232, and again, the synthesized gas (FLUE GAS) is cooled to 150 ° C. in the economizer 232 to be discharged to the cooling device unit 240 in the rear stage.

At this time, the syngas boiler 230 produces superheated steam and exhaust gas may be combusted with pure oxygen conditions or air, and the burner adopts a microprocessor-controlled burner management system (BMS) to perform efficient management.

A cooling device unit 240 is connected to the rear end of the synthesis gas boiler unit, and the cooling unit 240 is configured by two gas coolers connected in sequence to be introduced from the synthesis gas boiler 230. The exhaust gas is cooled and sent to the stack 250.

In addition, the water heater 104 formed between the inner wall and the outer wall of the heating furnace 100 by connecting a hot water supply line (A) for supplying heat (hot water) to the heat storage tank or the heating heat demand destination (500). It is possible to supply the hot water heated in the heating and hot water for use, it is configured to recycle for heating and hot water use without discarding the combustion heat of the waste generated in the combustion process of the waste incineration dedicated furnace 100.

As described above, the waste heat recovery boiler 200 recovering heat from the combustion gas generated in the combustion process of the waste incineration-only heating furnace 100 and the heat retained by the gas in the process of purifying the combustion gas are recovered. Boiler water supply line for supplying the heat generated from the syngas boiler 230 to supply to the steam header 260, performs cogeneration with the heat supplied from the steam header 260, and return to the waste heat recovery boiler 200 again ( B) and the heating steam supply line (D) for supplying heat generated from the syngas boiler 230 to the steam header 260 are connected in parallel, respectively.

The boiler water supply line (B) is formed in parallel so that the heating water supply line (C) share the pipe network to supply the heat generated in the process of the waste heat recovery boiler 200 to the demand destination for each application or cogeneration generator (300) It can be used for various purposes, such as power generation process and heating purposes, etc., depending on the purpose of producing electricity and supplying electricity to the source of electricity 600 by driving steam turbines. And it is configured to increase the overall energy efficiency by using step by step.

The boiler water (steam) supply line (B) is a steam heat generator 260, steam from the waste heat recovery boiler 200 that generates steam as a high-temperature exhaust gas to obtain the rotational energy by steam to produce heat and electricity The heating and heating water is heated with the heat from the cogeneration generator 300 equipped with the steam turbine and the steam turbine of the cogeneration generator, and the heated heating water is exchanged with the heating water returned from the heating heat demand source 500 to supply the heating and hot water supply. Heat exchanger 310 to be made, a return pump (P) for returning the steam (or water) cooled by heat exchange with heating water to the waste heat recovery boiler 200, degassing device to remove oxygen dissolved in water and prevent corrosion (Deaerator) 320, the heat storage tank 330 for storing heat storage of the heating water

  In addition, the steam supplied from the steam header 260 is supplied in addition to the steam turbine to the steam demand destination 700, such as an industry to maximize the use efficiency, and the excess heat is supplied to the cogeneration generator 300 of the steam turbine to heat and electricity And the excess heat of turbine consumption may be supplied to the heating water supply line instead of releasing to the atmosphere.

In the deaerator 320, oxygen is removed from the condensed water that is introduced, heated and pumped by a water supply pump to supply boiler water to the economizer 210 attached to the waste heat recovery boiler 200.

In addition, in the above-described configuration, the cogeneration generator 300 is provided with both a steam turbine and a generator to inflate and expand heat generated by the waste heat recovery boiler 200 and the syngas boiler 230 to generate power to a steam turbine to generate power. Simultaneous production of electricity by the driving method, the electricity is supplied to the steam source of the cogeneration generator 300, the steam to the electricity demand destination (600).

In addition, the heat storage tank 330 may be heat storage with PCM or hot water, which is a phase change material, as a heat storage material.

The boiler water supply line (B) is to supply heat generated by the cogeneration generator to the heat exchanger (310) as steam passing through the heating water supply line (C) connected to the boiler water supply line (B) is an auxiliary heat source device. As an auxiliary heat source device 400 for heating the heating water is additionally installed to supply the heating and hot water supply to the heating heat using place 500, the auxiliary heat source device 400 for supplementing the insufficient heat energy is a backup boiler or solar heat, wind power, etc. By selectively operating the auxiliary heat source is made, even if the heat energy load fluctuations are severe, the hot water above the set temperature without a thermal energy supply temperature difference is continuously supplied without stopping.

As an auxiliary heat source for supplementing the insufficient heat amount of the heating water cooled and returned in the above configuration, the boiler may use exhaust gas discharged from the cogeneration generator 300, and the driving power may be used to generate its own power generated by the cogeneration generator 300. In addition to the gas, the heat source may be generated and supplied by using a heat pump or a solar heat collecting plate that heats up the heating water to a heat source such as exhaust gas, cooling water, river water, geothermal water, seawater, and plant wastewater.

Eventually, the eco-friendly multi-energy resource recovery apparatus in connection with the combustible waste-only heating furnace of the present invention is a waste heat recovery boiler that generates steam with high-temperature gas generated by incineration of the waste incineration-only furnace 100 and waste or waste solid fuel. (200) and the combined heat and power generator 300 to perform cogeneration to convert the energy generated by the heat generated by the synthesis gas boiler, the waste heat recovery boiler 230 and the synthesis gas boiler 230 and heating, cogeneration Energy-saving eco-friendly waste treatment and resource recycling system of multi-stage energy circulation structure in which a heat exchanger 310 that exchanges heat with cooling water that is cooled by heating water heated and supplied by waste heat of a generator is connected to each other. Environmentally friendly waste of heat as heat supply and heat exchange structure of energy to exchange waste heat of process process organically In addition to the subtreatment, the heat generated from the combustion of the waste and gas refining process is used to connect heat, complementary, phased and selective exchange of power in one system unit with power supply, heating water and hot water supply. It is composed of the optimal recovery line by organic combination of each process line, combined with the synergy effect of eco-friendly treatment of waste, recycling of unused energy that is not used effectively, and improvement of heat exchange capacity, global warming and environmental pollution Prevention and improve the overall energy efficiency of waste combustion and cogeneration systems and heating systems.

In the present invention, the above-described waste heat recovery boiler 200 and the gas purification treatment discharge line including the syngas boiler 230 are omitted, and the present invention conventionally provides a combined heat exchanger and cooling capable of generating both steam and gas. It is possible to implement a small cogeneration system by reducing the burden of installation costs by adopting the gas purification device of the selective economical and supplying the steam to the cogeneration generator (300).

In addition, the above-described installation and circulation structure of each process line is a preferred embodiment illustrated for convenience of illustration and description, and various modifications can be made within the same range of technical spirit of the present invention according to the installation conditions.

While the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. .

100: heating 101: body
102: wall 104: water heater
105: waste inlet 106: combustion material outlet
107: gas outlet 108: transfer conveyor
109: Combustion feed screw
110: hopper 111: waste feed screw
120: 1 combustion chamber 121: ignition burner
122: rostol 130: secondary combustion chamber
131: heat filter block 133: air blowing air
134: combustion gas passage 135: blower
140: 3rd combustion chamber 141: side wall
142: gas discharge hole 180: water supply
200: waste heat recovery boiler
210: economizer (preheater) 220: synthetic gas purification unit
221: bag filter (dust collector) 222: evaporative cooler
223: (wet) scrubber 224: booster fan
230: synthesis gas boiler 232: economizer (preheater)
233: denitrification unit (SCR) 240: cooling unit
250: Stack 260: Steam header
300: cogeneration generator 310: heat exchanger
320: deaerator 330: heat storage tank
400: auxiliary heat source device 500: heating heat demand destination
600: electricity demand 700: steam demand
P: Pump
A: hot water supply line B: boiler water supply line
C: Heating water supply line D: Heated steam supply line
E: Gas Purification Discharge Line

Claims (5)

As a waste energy-energy facility, a combustible waste solid fuel (RDF) or a combustible waste is burned in an environment-friendly manner, and a heating furnace 100 for supplying hot water using heat generated during the incineration of waste, and the heating furnace ( 100) a waste heat recovery boiler 200 for recovering waste heat from the high-temperature exhaust gas generated in the heating furnace 100 to discharge the exhaust gas to the atmosphere through the stack 250,
The heating furnace 100 comprises a wall 102 made of a fireproof steel plate coated with a refractory paint to withstand high thermal shocks of 1300 ° C. or more on the outer periphery of the rectangular enclosure-shaped body 101 in a downward multistage direct combustion method. (102) The inner edge stores the water (water) supplied from the water supply 180 and warmed by the high temperature combustion heat of the heating furnace 100 to heat the hot water to the hot water supply line (A) without a separate heating means (500) Or a water heating unit 104 is formed to supply heat to the heat storage tank and is configured to supply heat to the heat storage tank 330 or the heating demand 500.
The economizer 210 for preheating purpose is connected to the waste heat recovery boiler 200 to recover the waste heat from the economizer 210 and then supply the waste heat recovery boiler 200 to the waste heat recovery boiler 200.
The gas purification processing unit at the rear end of the waste heat recovery boiler 200 undergoes a gas purification process of dust collection, desulfurization, denitrification, and cooling, thereby releasing gas that meets the standards of the Air Conservation Act after combustion to the atmosphere.
In the gas purification process, the synthesis gas boiler 230 recovers the waste heat again, and the steam generated in the waste heat recovery boiler 200 and the synthesis gas boiler 230 is supplied to the steam header 260 and the steam header 260 By using the steam supplied, the cogeneration generator 300 produces heat and electricity and supplies it to the electricity demanding place, or exchanges heat with the heat exchanger 310 to supply the heating heat demanding place, thereby treating wastes in an environment-friendly combustion and combustion refining process of the wastes. In the eco-friendly multi-energy resource recovery system in connection with the combustible waste-only heating furnace that performs a combination of power generation, heating water, hot water supply function in one system unit organically connected using the heat generated in the process,
The rear end of the waste heat recovery boiler 200 is a gas purification treatment discharge line E for discharging the exhaust gas emitted from the waste heat recovery boiler 200 to the atmosphere through a gas purification process, and the heat storage tank includes a heat storage tank ( 330 or the hot water supply line A for supplying heat (hot water) to the heating demand 500, and also the steam generated from the waste heat recovery boiler 200 and the synthesis gas boiler 230 is supplied from the steam header 260. Receives the heat generated by the cogeneration generator 300 to transfer the heat transmitted from the boiler water supply line (B) and the boiler water supply line (B) to transfer to the heat exchanger 310 and back to the waste heat recovery boiler (200). Connected to the heating water supply line (C) for supplying the heating water for heating and hot water supply to the heating heat demand source 500 and returning from the supplying machine 310 to complementary, stepwise, and selectively exchange heat. Consisting of a heat recovery line Environment-friendly multi-energy recovery device in connection with the only flammable waste heat, characterized by delete delete delete delete

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