KR101309279B1 - All fluidize bed that phlogiston device and produce steam resource - Google Patents

Abstract

The present invention is a combustion device that produces steam using heat generated by burning solid fuel (RPF) converted from natural waste such as waste vinyl among domestic and industrial wastes and petroleum coke which is a by-product generated during petroleum refining process. It is to provide an integrated fluidized bed combustor for producing and using the steam produced by using the steam produced by using the heat generated by combustion in the integrated fluidized bed combustor combined with a combustion furnace and a boiler. .
An integrated fluidized bed combustion device for producing and recycling the steam of the present invention for this purpose, an inlet for mixing and mixing solid fuel and petroleum coke; A circulating fluidized bed combustion furnace which forms the inlet in all directions and installs the cooling pipes to extend to both inner walls of the lower ends thereof, and safely burns them; A circulating fluidized bed secondary combustion furnace communicating with an upper portion of the circulating fluidized bed combustion furnace to secondary combustion of completely unburned petroleum coke, which is attracted to the guiding blower; A waste heat recovery unit installed in the circulating fluidized bed combustion furnace and the circulating fluidized bed secondary combustion furnace to recover exhaust gas containing waste heat generated during incineration in the circulating combustion furnace; A heat recovery boiler for producing steam by cooling hot exhaust gas from the circulating fluidized bed combustion furnace and the circulating fluidized bed secondary combustion furnace; A steam distribution pipe for distributing the steam generated in the heat recovery boiler to each use destination; .

Description

All fluidize bed that phlogiston device and produce steam resource

The present invention relates to an integrated fluidized bed combustor that produces and recycles steam, and more particularly, circulates a low calorific value 6,000 kW / kg solid fuel (RPF) and a low calorific value 7,850 kcal / kg petroleum coke. The present invention relates to an integrated fluidized bed combustor for producing and recycling steam for energy recovery of water into steam having high caloric value using heat generated by combustion in a fluidized bed combustor.

In general, waste vinyl is mostly incinerated or landfilled, reducing its reuse value, and in Korea, about 10% of the total amount produced is made of RDF (Refuse Derived Fuel) and RPF. It was treated in a cement kiln (rotary kiln), but this was only a temporary solution rather than a solution. This method is poor in accessibility and free economical value due to free treatment, there is a problem that causes secondary environmental pollution such as odor, air pollutant generation.

In addition, in the grate-type combustion furnace, problems such as damage to the grate due to high heat, frequent refractory breakage, and a structure in which the high sulfur content contained in the petroleum coke cannot be removed from the combustion furnace, and a problem that cannot be mixed between the two materials This is emerging.

On the other hand, the CDS (Circle Derivel System) combustion furnace, which has recently been widely distributed, is a system that burns RDF and RPF exclusively, and failed to completely ignite in the input device and the re-extraction unit. It has the disadvantage that it can not be mixed.

Although the RDF and RPF have been researched and proven in Korea, there are no reliable demonstration facilities. In Korea, the circulating fluidized bed combustion furnace is used to burn a single system of combustion materials like coal.

In order to solve the above problems, the present invention recovers water as steam with high calorific value by using heat generated by burning solid fuel (RPF) having high low calorific value and petroleum coke in a circulating fluidized bed combustor. In the process of treating waste vinyl generated in large quantities, the circulating fluidized bed combustion furnace is mixed by storing and transporting RPF which is made of solid fuel which is easy to handle and high calorific value and petroleum coke which is a by-product generated during petroleum refining process. It burns up to 950 ℃ by using high temperature exhaust gas and recovers energy by heat of steam using a heat recovery boiler in a combustion device in which a combustion furnace and a boiler are integrated. Renewable energy that raises utilization of coke and is waste energy It is an integrated fluidized bed combustion apparatus for recycling to produce steam to expand the dissemination of the project to provide.

In order to achieve the above object, the present invention provides an integrated fluidized bed combustion device that produces and recycles steam, including an inlet for mixing solid fuel and petroleum coke; A circulating fluidized bed combustion furnace which forms the inlet in all directions and installs the cooling pipes to extend to both inner walls of the lower ends thereof, and safely burns them; A circulating fluidized bed secondary combustor communicating with an upper portion of the circulating fluidized bed combustor for secondary combustion of completely unburned solid fuel and petroleum coke, which are attracted to an induction blower; A waste heat recovery unit installed in the circulating fluidized bed combustion furnace and the circulating fluidized bed secondary combustion furnace to recover exhaust gas containing waste heat generated during incineration in the circulating combustion furnace; The circulating fluidized bed

A heat recovery boiler for producing steam by cooling the hot exhaust gas from the combustion furnace and the circulating fluidized bed secondary combustion furnace; A steam distribution pipe for distributing the steam generated in the heat recovery boiler to each use destination; .

A primary pressurized blower for supplying combustion air for burning solid fuel and petroleum coke to a burner at a bottom of the circulation flow bed combustion furnace; A secondary press-fit blower for supplying combustion air secondaryly to accelerate combustion of the solid fuel and petroleum coke; And a manned blower for guiding a portion of the solid fuel and the petroleum coke from the circulating fluidized bed combustion furnace so that the solid fuel and the petroleum coke are not completely burned in the circulating fluidized bed combustion furnace.

In addition, the circulating fluidized bed combustion furnace includes heating the solid fuel and petroleum coke to 800 ℃ ~ 900 ℃ to ensure that only 50% of the solid fuel and petroleum coke is made.

In addition, the circulating fluidized bed secondary combustion furnace includes heating 50% of the remaining solid fuel and petroleum coke to 1100 ° C. in the solid fuel and petroleum coke transferred to the manned blower.

According to the present invention, it is effective to recover energy by heat of high calorie steam using heat generated by burning solid fuel (RPF) and petroleum coke with low calorific value to 950 ° C. in a circulating fluidized bed combustor. have.

In particular, it is possible to expand the amount of waste vinyl produced in large quantities in the living and industrial areas by increasing the use of solid fuel (RPF), and to use petroleum coke, a by-product generated during the petroleum refining process, which generates high calorific value, as a poor heat source. The development of fluidized bed combustion furnaces has the effect of replacing the scarce petroleum resources by increasing the use of both RPF and petroleum coke.

In addition, it is a very useful invention because it has the effect of expanding the spread of renewable energy business that is the energy conversion of waste.

1 is an overall configuration of the integrated fluidized bed combustion apparatus for producing and recycling steam in accordance with the present invention.
Figure 2 is a block diagram showing a combustion device of an integrated fluidized bed combustion device for producing and recycling steam in accordance with the present invention.
Figure 3 is a side view showing the waste heat recovery unit in the combustion device of the integrated fluidized bed combustion apparatus for producing and recycling steam according to the present invention.
Figure 4 is a plan view of the combustion apparatus of the integrated fluidized bed combustion apparatus for producing and recycling steam in accordance with the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The configuration of the present invention for achieving the above object,

An inlet for mixing solid fuel and petroleum coke;

A circulating fluidized bed combustion furnace which forms the inlet in all directions and installs the cooling pipes to extend to both inner walls of the lower ends thereof, and safely burns them;

A circulating fluidized bed secondary combustor communicating with an upper portion of the circulating fluidized bed combustor for secondary combustion of completely unburned solid fuel and petroleum coke, which are attracted to an induction blower;

A waste heat recovery unit installed in the circulating fluidized bed combustion furnace and the circulating fluidized bed secondary combustion furnace to recover exhaust gas containing waste heat generated during incineration in the circulating combustion furnace;

A heat recovery boiler for producing steam by cooling hot exhaust gas from the circulating fluidized bed combustion furnace and the circulating fluidized bed secondary combustion furnace;

A steam distribution pipe for distributing the steam generated in the heat recovery boiler to each use destination; It was achieved by providing an integrated fluidized bed combustor for producing and resourceizing steam comprising.

1 is an overall configuration diagram of an integrated fluidized bed combustion apparatus for producing and recycling steam according to the present invention.

As shown, the combustion apparatus 200 according to the present invention is calorific value of water using heat generated by burning solid fuel and petroleum coke with a very high lubrication in the circulating fluidized bed combustion furnace 120 The recovery of this high steam, especially in the treatment of waste vinyl generated in large quantities in the living and industrial world, is made of solid fuel that is easy to handle, and is a solid fuel (RPF) that is received and petroleum, which is a high calorific value and a by-product generated during the petroleum refining process. After storing and transporting the coke, the mixture is mixed and burned to 950 ° C. using a circulating fluidized bed combustion furnace, and the high heat exhaust gas generated at this time is a heat recovery boiler 150 in the combustion device 200 in which the combustion furnace and the boiler are integrated. By recovering energy with the heat of steam by using the steam produced in the place of use.

This, the combustion device 200 is mixed with the solid fuel (RPF) and petroleum coke is introduced through the inlet 110.

The circulating fluidized bed combustion furnace 120 in which the inlet 110 is formed in all directions is installed safely to extend the cooling pipe 122 to both inner walls of the lower end.

In addition, the circulating fluidized bed secondary combustion furnace 130 communicating with the upper portion of the circulating fluidized bed combustion furnace 120 to secondary combustion of completely unburned solid fuel (RPF) petroleum coke, which is attracted to the draw fan 128. Is connected.

In addition, a waste heat recovery unit 140 is installed inside the circulating fluidized bed combustion furnace 120 and the circulating fluidized bed secondary combustion furnace 130 to recover the exhaust gas containing the waste heat generated during incineration in the circulating combustion furnace 123. Done.

The hot exhaust gas from the circulating fluidized bed combustion furnace 120 and the circulating fluidized bed secondary combustion furnace 130 is cooled in the heat recovery boiler 150 to produce steam.

In addition, the steam generated in the heat recovery boiler 150 is transferred to each place of use through the steam distribution pipe 160 to increase the utilization of two solid fuels (RPF) and petroleum coke, which is currently of low utility value, and waste energy It provides an integrated fluidized bed combustion apparatus 200 for expanding the spread of renewable energy business.

Hereinafter, an integrated fluidized bed combustion apparatus for producing and resourceizing steam having the above configuration will be described in detail.

First, Figure 2 is a block diagram showing a combustion device of an integrated fluidized bed combustion device for producing and recycling steam in accordance with the present invention.

As shown in the figure, the overall configuration of the combustion apparatus 200 of the present invention is a storage hopper (not shown) and a transfer screw capable of storing solid fuel (RPF) and petroleum coke for more than 3 days and automatically transporting them. Conveyors (not shown) and bucket elevators (not shown) are configured.

Supplying it again and supplying directly to the circulating fluidized bed combustion furnace 120 is provided with an intermediate storage hopper (not shown) and a screw conveyor (not shown) to store for 2-3 hours.

At this time, a lime storage hopper (not shown) for storing limestone used to remove SOx generated during combustion and a flow for storing a flow sand used as a heat medium in an oxidized fluidized bed combustion furnace (not shown). Yarn storage hopper 20 is configured.

In addition, the solid fuel (RPF) and the petroleum coke, which are fuels, are supplied to the circulating fluidized bed combustion furnace 120 that burns through the inlet 110.

Here, the flow nozzle (not shown), which is the main component of the circulating fluidized bed combustion furnace 120, a vibrator (not shown) for sorting unburned bottom ash and flow sand, and the selected flow sand are recovered and reused. A screw conveyor 34 and a flow yarn conveyor 36 that can be transported are configured.

At this time, the exhaust gas recirculation pressurized blower (not shown) installed at the lower end of the circulating fluidized bed combustion furnace 120 to partially circulate the exhaust gas generated after combustion and re-introduced into song to obtain a denitrification effect of about 20% or more. do.

And, to accelerate the combustion of the primary pressurized blower 124 and the solid fuel and petroleum coke to supply the combustion air for the combustion of solid fuel and petroleum coke to the burner 10 at the bottom of the circulating fluidized bed combustion furnace (120). The secondary press-fit blower 126 is configured to supply secondary combustion air.

In addition, the primary press-fit blower 124 and the second press-fit blower 126, which are required for combustion for the complete combustion of high calorific value fuel (RPF) and petroleum coke, are used for circulating fluidized bed combustion furnace. The air is supplied from the secondary press-fit blower 126 that supplies the secondary combustion air from the upper portion 120 to promote combustion and minimize the generation of carbon monoxide.

In addition, the circulating fluidized bed is a guided blower 128 for guiding a part of the solid fuel and the petroleum coke from the circulating fluidized bed combustion furnace 120 so that the solid fuel and the petroleum coke are not completely burned in the circulating fluidized bed combustion furnace 120. It is configured in the combustion furnace 120.

An exhaust gas recirculation pressurized blower (not illustrated) is provided, which is a device for partially circulating the exhaust gas generated after combustion in the circulating fluidized bed combustion furnace 120 and re-injecting the exhaust gas into the furnace.

In addition, the selective non-catalytic reduction device which is used to remove nitrogen oxides generated during combustion in the circulating fluidized bed combustion furnace 120 and the high-temperature exhaust gas from the circulating fluidized bed combustion furnace 120 are cooled to steam. Semi-dry reaction tower 42 for purifying and discharging harmful gases such as sulfur oxides and dust discharged from the heat recovery boiler 150, caustic soda tank (not shown) and liquid lime storage tank ( (Not shown in the drawing) and a filter dust collector 44 for removing dust and residual sulfur oxides contained in the exhaust gas from the semi-dry reaction tower 42 and a dry spraying powder lime and activated carbon in front of the filter dust collector 44. A reactor (not shown), an exhaust blower (46) for discharging the exhaust gas out of the chimney, and a water storage tank (52) and a pump for supplying water to the boiler All.

As such, there is a fuel storage unit (not shown) for storing solid fuel (RPF) and petroleum coke for at least three days each, while the lower portion of the feed screw conveyor is 55% to 45% solid fuel (RPF) and petroleum coke by weight ratio. And the bucket elevator will be configured to be mixed with each other to be a homogeneous raw material composition.

Here, the uniform combination of fuel is a very important mechanical device before the circulating fluidized bed combustion furnace 120 is put into close contact with the uniform supply of combustion air and the amount of exhaust gas generated.

Meanwhile, an intermediate storage hopper and a screw conveyor capable of storing fuel for two to three hours immediately in front of the circulating fluidized bed combustion furnace 120 in order to solve the problem of fuel supply interruption caused by the failure of the primary fuel storage hopper, etc. Install to improve the continuity of combustion.

In addition, the circulating fluidized bed combustion furnace 120 for burning solid fuel (RPF) and petroleum coke is composed of an inlet 110 and a flow nozzle and burner 10 for mixing and injecting solid fuel and petroleum coke attached to the main body. do.

At this time, the circulating fluidized bed combustion furnace 120 is installed to extend the cooling pipe 122 to both inner walls of the lower end while forming the inlet 110 on all sides to burn safely.

Since the inlet 110 of the circulating fluidized bed combustion furnace 120 must withstand high temperature heat, it is installed as an air transfer type special fuel inlet 110.

The circulating fluidized bed combustion furnace 120 is provided with a fireproof material and a heat insulating material to withstand high temperature heat.

Here, the flow nozzle configured at the lower end of the circulating fluidized bed combustion furnace 120 is used to heat the flow yarn, and to withstand the high temperature of about 850 ℃ of the bed bed uses a heat-resistant wear-resistant material.

The circulating fluidized bed secondary combustion furnace 130 communicating with the upper portion of the circulating fluidized bed combustion furnace 120 secondary combustion of completely unburned solid fuel and petroleum coke attracted to the draw fan 128.

In addition, the circulating fluidized bed secondary combustion furnace 130 serves to secondarily burn solid fuel (RPF) and petroleum coke, which are primarily combusted in the circulating fluidized bed combustion furnace 120.

That is, the circulating fluidized bed secondary combustion furnace 130 is to completely burn the portion that is not completely burned in the circulating fluidized bed combustion furnace 120.

The waste heat recovery unit 140 is formed inside the circulating fluidized bed combustion furnace 120.

Here, the circulating fluidized bed combustion furnace 120 is heated to 800 ℃ ~ 900 ℃ solid fuel and petroleum coke so that only 50% of the solid fuel and petroleum coke is made, the circulating fluidized bed secondary combustion furnace 130 50% of the remaining solid fuel and petroleum coke by heating the solid fuel and petroleum cork burned only 50% in the circulation distribution bed combustion furnace 120 to 1100 ℃ in the solid fuel and petroleum coke transferred through the manned blower (128). % Will be burned out.

This is because the high temperature in the circulating fluidized bed combustion furnace 120 is combusted when the solid fuel and petroleum coke 100% combustion in the circulating fluidized bed combustion furnace 120, the fluidized bed is inhibited, so only 50% of the circulating fluidized bed combustion furnace 120 is combusted. And, the remaining 50% in the circulating fluidized bed secondary combustion furnace 130 that is secondary.

In addition, Figure 3 is a side view showing the waste heat recovery in the combustion device of the integrated fluidized bed combustion apparatus for producing and recycling steam according to the present invention, Figure 4 is a combustion device of the integrated fluidized bed combustion device for producing and recycling steam according to the present invention Top view.

As shown in the figure, when the solid fuel and petroleum coke are burned in the circulating fluidized bed combustion furnace 120 and the circulating fluidized bed secondary combustion furnace 130, the waste heat recovery unit 140 installed therein is a circulating combustion furnace ( 123) recovers the exhaust gas containing waste heat generated during incineration.

Then, the high temperature exhaust gas from the circulating fluidized bed combustion furnace 120 and the circulating fluidized bed secondary combustion furnace 130 is cooled to produce steam in the heat recovery boiler 150.

The heat recovery boiler 150 is connected to the lateral side of the circulating fluidized bed secondary combustion furnace 130, and serves to guide the discharge of the exhaust gas generated during incineration. In addition, the heat recovery boiler 150 recovers the heat generated during incineration and generates steam to generate resources.

The steam generated in the heat recovery boiler 150 is transferred and distributed to each place of use through the steam distribution pipe 160.

Here, at least one hopper is installed at the lower end of the heat recovery boiler 150.

The hopper is for discharging the fine dust generated during incineration to the bottom.

In this way, by using the heat recovery boiler 150 to recover the energy by the heat of steam, the solid fuel (RPF) and petroleum coke is to produce and recycle the steam as renewable energy.

In addition, in order to recover as much steam as possible from the circulating fluidized bed combustion furnace 120 at a high temperature exhaust gas of 950 ° C., a membrane water pipe pipe is installed on the surface of the steel bar constituting the upper part of the circulating fluidized bed combustion furnace 120 to obtain approximately 25% Promote heat recovery, and the heat recovery in the water pipe heat recovery boiler 150 mounted with the remaining three drums.

At this time, the temperature of the exhaust gas passing through the heat recovery boiler 150 is maintained at 250 ° C.

In addition, the dust is easily discharged to the bottom of the boiler by screen filtering the inlet of the chute blower and heat recovery boiler 150 using steam to effectively remove the dust generated during combustion.

On the other hand, the fly ash falling to the bottom is stored in the fly ash reservoir (not shown) by the air transfer device.

Sulfur oxides and dust that are not removed from the heat recovery boiler 150 are subjected to semi-dry reaction tower 42 to be secondary desulfurized and dust is partially removed.

At this time, the 3% caustic soda supplied from the caustic soda tank into the semi-dry reaction tower 42 and the 1% liquid lime from the liquid lime storage tank to increase the desulfurization effect and the injection nozzle on top of the semi-dry reaction tower 42 Is installed. The exhaust gas temperature at this time is to maintain about 240 ℃.

A filter dust collector 44 for removing unremoved dust and residual sulfur oxides contained in the exhaust gas discharged from the semi-dry reaction tower 42 is installed, and sprays powdered lime and activated carbon on the front of the filter dust collector 44. Install a dry reactor to purify the exhaust gas.

A discharge blower 46 for discharging the exhaust gas out of the chimney is installed to install an inverter for energy saving.

In addition, other auxiliary facilities include a water storage tank 52 and a pump for supplying water to the heat recovery boiler 150, and is installed unmanned by installing a fly ash storage for storing fly ash.

As such, the integrated fluidized bed combustor 200 for producing and recycling the steam of the present invention burns solid fuel (RPF) and petroleum coke, which are landfilled or simply incinerated, in the circulating fluidized bed combustor 120 to produce steam. It regenerates excess heat, and the generated harmful gases are treated with two stages of dust collection, desulfurization (dehydrogen chloride), and denitrification to prevent secondary environmental pollution and provide energy recovery effect of low carbon green growth.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

110: inlet 120: circulating fluidized bed combustion furnace
122: cooling pipe 123: circulating combustion furnace
124: 1st press blower 126: 2nd press blower
128: manned blower 130: circulating fluidized bed secondary combustion furnace
140: waste heat recovery unit 150: heat recovery boiler
160: steam distribution pipe 200: combustion device

Claims (4)

In the combustion device to generate steam by using the high temperature heat generated after incineration of the combustible waste by using an incinerator to incinerate the combustible waste, and to use the steam to be released,
An inlet 110 for mixing solid fuel and petroleum coke;
A circulating fluidized bed combustion furnace (120) for safely burning by installing the inlet (110) on all sides and extending the cooling pipes (122) to both inner walls of the lower end;
A circulating fluidized bed secondary combustion furnace (130) communicating with an upper portion of the circulating fluidized bed combustion furnace (120) for secondary combustion of completely unburned solid fuel and petroleum coke, which are attracted to the draw fan (128);
A waste heat recovery unit (140) installed inside the circulating fluidized bed combustion furnace (120) and the circulating fluidized bed secondary combustion furnace (130) for recovering exhaust gas containing waste heat generated during incineration in the circulating combustion bed (123);
A heat recovery boiler (150) for producing steam by cooling the high-temperature exhaust gas from the circulating fluidized bed combustion furnace (120) and the circulating fluidized bed secondary combustion furnace (130);
A steam distribution pipe 160 for distributing steam generated by the heat recovery boiler 150 to each user; An integrated fluidized bed combustor for producing and resourceizing steam comprising a.
The method of claim 1,
The circulation distribution bed combustion furnace 120,
A primary pressurized blower 124 for supplying combustion air for combustion of solid fuel and petroleum coke to the burner 10 at the bottom;
A secondary press-fit blower 126 which supplies secondary combustion air to accelerate combustion of the solid fuel and petroleum coke;
And a drawer blower 128 for guiding a portion of the solid fuel and the petroleum coke from the circulating fluidized bed combustion furnace 120 so that the solid fuel and the petroleum coke are not completely burned in the circulating fluidized bed combustion furnace 120. An integrated fluidized bed combustor for producing and recycling steam characterized in that.
The method of claim 1,
The circulating fluidized bed combustion furnace 120,
An integrated fluidized bed combustor for producing and refining steam, comprising heating the solid fuel and petroleum coke to 800 ° C. to 900 ° C. such that only 50% of the solid fuel and petroleum coke are burned.

The method of claim 1,
The circulating fluidized bed secondary combustion furnace 130,
An integrated fluidized bed combustor for producing and recycling steam, comprising heating 50% of the remaining solid fuel and petroleum coke to solid fuel and petroleum coke transferred to the manned blower 128 at 1100 ° C. .

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