KR101378040B1 - A apparatus of Bio gas flare stack - Google Patents

Abstract

The present invention relates to a biogas flare stack device. The present invention provides a gas flare stack apparatus for providing a biogas incinerator for low nitrogen oxide (NOx) discharge, comprising: a combustion apparatus formed of two or more combustion apparatuses for receiving biogas; An air inlet unit into which the combustion device is inserted and including a plurality of air inlets; An adiabatic combustion furnace that generates a flame generating low nitrogen oxides (NOx) using air introduced into the air inlet; And a gas outlet connected to the heat treatment combustion furnace and formed to have an inlet narrowed upwardly. And a control unit.
This provides an effect of designing a low nitrogen oxide (NOx) emission type biogas combustion furnace which requires little power and generates little nitrogen oxide (NOx).
In addition, the present invention not only requires power, but also can be used anywhere as long as the control power supply is used as a safety device required for control. .
In addition, the present invention, by the design of a plurality of air inlet path is low temperature, complete combustion with sufficient air inlet required for combustion, and provides the effect of reducing the amount of nitrogen oxides (NOx) generated.

Description

A apparatus of Bio gas flare stack

The present invention relates to a biogas flare stack apparatus, and more particularly, by the design of a plurality of air inlet paths to complete combustion with low temperature and sufficient air inlet required for combustion, and to reduce the amount of NOx generated A biogas flare stack device.

At present, mankind's main energy source is hydrocarbon-based fossil fuels. However, the problem of environmental pollution by the product after combustion of fossil fuels has been seriously raised. The main environmental pollutants include nitrogen oxides (NOx) and carbon dioxide (CO ₂ ), as well as carbon monoxide (CO) and soot caused by incomplete combustion of fuels. Nitrogen oxides are known to cause photochemical smog and acid rain and seriously affect plants and animals. For many years, many researchers have studied various ways to reduce NOx.

Because of this, currently tried NOx emissions methods include exhaust gas recirculation, water or steam injection, multistage combustion of air and fuel, selective non-catalytic reduction (SNCR) and selective catalytic reduction. Reactive combustion (SCR), selective catalytic reduction (SCR) and the like, have recently been attempted in advanced countries to remove NOx from the post-combustion zone, and are known to have high efficiency in terms of NOx reduction and economic efficiency.

On the other hand, the use of valuable fuel in terms of carbon dioxide generation suppression and oil price energy saving may adversely affect. As a result, there is a need for a new method that can achieve improved nitrogen oxide reduction effect compared to the existing reburn method while securing higher economics.

Accordingly, there is a need in the art to develop a technology for designing a low nitrogen oxide (NOx) emission type biogas combustion furnace with low generation of NOx without power.

[Related Technical Literature]

1. Nitrogen oxide removal method using a biofilter (Patent application No. 10-2007-0074786)

2. Nitrogen oxide reduction catalyst using multistage injection and its use (Patent application No. 10-2004-0020956)

3. Reburn apparatus including oxygen separation module (Patent application No. 10-2009-0124997)

4. Oxygen-enriched combustion-pyrolysis method by oxygen and circulating carbon dioxide gas (Patent application No. 10-1999-0008010)

The present invention has been made to solve the above problems, and to provide a biogas flare stack apparatus for designing a low nitrogen oxide (NOx) emission type biogas combustion furnace with low generation of nitrogen oxide (NOx) without the need for power.

In addition, the present invention not only requires power, but also can be used anywhere as long as the control power supply used as a safety device required for control, and the installation conditions are easy. To provide a gas flare stack device.

In addition, the present invention is to provide a biogas flare stack device for a low temperature and complete combustion with a sufficient air inlet required for the combustion by the design of a plurality of air inlet, and to reduce the amount of NOx generated.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the biogas flare stack apparatus according to the embodiment of the present invention is a gas flare stack apparatus for providing a biogas incinerator for low nitrogen oxide (NOx) emission, and is supplied with biogas for combustion Apparatus for the purpose, comprising two or more combustion apparatus; An air inlet unit into which the combustion device is inserted and including a plurality of air inlets; An adiabatic combustion furnace that generates a flame generating low nitrogen oxides (NOx) using air introduced into the air inlet; And a gas outlet connected to the heat treatment combustion furnace and formed to have an inlet narrowed upwardly. And a control unit.

According to another embodiment of the present invention, a biogas flare stack device includes: a biogas train set connected to the combustion device and configured to control the amount of biogas supplied to the combustion device by filtering biogas; And further comprising:

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In the biogas flare stack apparatus according to another embodiment of the present invention, the heat-insulated combustion furnace, the flame is used to sense whether the flame occurs by inserting obliquely upward to the flame generated in the lower portion of the heat-insulated combustion furnace Monitoring device; Further comprising:

In the biogas flare stack device according to another embodiment of the present invention, the thermal insulation combustion furnace, the overheat prevention device is formed on top of the flame monitor and used to sense whether overheating by the flame occurs; And further comprising:

Biogas flare stack device according to another embodiment of the present invention, when the signal sensed by the flame monitoring device and the overheating prevention device, it is characterized in that it is linked with the alarm system itself to output an alarm sound to the user.

In the biogas flare stack apparatus according to another embodiment of the present invention, the gas discharge port, the fifth air inlet is formed on the outer peripheral surface of the portion joined to the heat treatment combustion furnace of the lower end of the gas outlet; And further comprising:

The biogas flare stack apparatus according to the embodiment of the present invention provides an effect of designing a low nitrogen oxide (NOx) emission type biogas combustion furnace with low generation amount of nitrogen oxides (NOx) without requiring power.

In addition, the biogas flare stack device according to another embodiment of the present invention can be used anywhere as long as the control power source is used as a safety device required for control as well as no power, and the installation conditions are easy, and a low carbon policy The equipment conforming to has the optimum structural effect.

In addition, the biogas flare stack device according to another embodiment of the present invention, by the design of a plurality of air inlet paths to complete combustion with a low temperature and sufficient air inlet required for combustion, reducing the amount of NOx Provide effect.

1 illustrates a biogas flare stack device in accordance with an embodiment of the present invention.
FIG. 2 is a view for explaining a bottom coupling structure of the biogas flare stack device of FIG. 1. FIG.
3 is a view for explaining the upper coupling structure of the biogas flare stack device of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, 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.

1 is a view showing a biogas flare stack device 1 according to an embodiment of the present invention. FIG. 2 is a view for explaining a bottom coupling structure of the biogas flare stack device 1 of FIG. 1. 3 is a view for explaining the upper coupling structure of the biogas flare stack device 1 of FIG.

1 to 3, the biogas flare stack device 1 includes a biogas train set 10, a combustion device 20, an air inlet 30, and an adiabatic combustion furnace 40. ), Overheat prevention device (41), flame monitoring device (42), gas outlet (50), fifth air inlet (51) and gas outlet (52), low nitrogen oxides (NOx) emission type biogas Provide an incinerator.

The Bio Gas Train Set (10) consists of a gas filter (GAS FILTER: 11), a gas low press switch (GAS LOW PRESS SWITCH: 12), a gas governor (GAS GOVERNOR: 13), and a gas sole valve (GAS). SOL VALVE 14) and gas sole valve 15.

A gas filter 11 filters the biogas to be delivered to the gas governor 13.

The GAS LOW PRESS SWITCH 12 is a switch for supplying power to operate the biogas flare stack 1 so that the flame density is controlled to discharge the low oxides (NOx) to the biogas by adjusting the flame density.

GAS GOVERNOR 13 adjusts the amount of biogas supplied to combustion device 20 with a gas regulator.

GAS SOL VALVE 14 and GAS SOL VALVE 15 are formed in duplicate by solenoid valves installed as fuel shutoff valves at the inlet.

The gas solenoid valves 14 and 15 need to be operated slowly when the valve is opened and momentarily when the valve is opened due to the nature of the gaseous fuel. Use an electrically open solenoid valve. According to the safety technical indicators of the gas combustion plant, the gas shutoff valves must be double so-called double shut-offs.

The combustion device 20 is a device for burning and receiving biogas, and as shown, may be formed in two, and may be modified into two or more as necessary.

The air inlet part 30 is located under the heat treatment combustion furnace 40 and includes a plurality of air inlet paths. More specifically, the air inlet part 30 includes the first air inlet path 31, the second air inlet path 32, the third air inlet path 33, and the fourth air inlet path 34. It is designed to be produced by low-burning NOx emission type biogas combustion with low temperature of flame and inlet of sufficient air inlet for combustion.

When the combustion device 20 is inserted into the air inlet 30, the first air inflow path 31 is formed as an internal space into which air enters the center of the combustion device 20.

The first air inflow path 31 is a space for firstly introducing natural air for combustion by the combustion device 20, and is a place where primary air flows due to the blowing speed of biogas.

Therefore, when the pressure of the biogas is low, the air inflow is low, and when the pressure of the biogas is high, the air inflow is large, which naturally serves as the primary air supply.

The second air inflow path 32 is formed as a space in which the combustion device 20 is inserted and remains in a compartment in which the combustion device 20 is inserted into the air inlet 30, and the combustion device 20 is inserted into the space. It is formed by spaces at both edges.

The second air inflow path 32 is a secondary natural inflow path of combustion air, and the flame is formed by the primary air inflow amount into the biogas and the second air inflow path 31. It is designed to supply the incoming air to promote combustion as a supplement to the scarce air.

The third air inflow path 33 is formed in the outer compartment of the compartment in which the combustion device 20 is inserted. The third air inflow path 33 may be formed in such a manner as to surround a compartment inserted into the air inlet 30 with the combustion apparatus 20 as an outer compartment of the compartment into which the combustion apparatus 20 is inserted.

The third air inflow path 33 is a third natural inflow path for combustion air. The third air inflow path 33 serves to supply air to the unburned gas coming out of the main flame through flame formation. Is formed.

The fourth air inflow path 34 may be formed in the space between the combustion device 20, as shown when there are two or more combustion devices 20.

The fourth air inflow path 34 is the fourth natural inflow path for combustion air. When the main flame is formed in a state where several single flames are combined, the middle portion of the flame has a high flame density, which causes the generation of nitrogen oxides (NOx). However, a large amount of air is introduced due to the flame speed and the temperature difference in the combustion device 20, and the air acting to lower the flame temperature in the middle portion is naturally introduced to supply air that reduces the generation of NOx. Used for.

The adiabatic treatment furnace 40 includes a flame monitoring device 41 and an overheat prevention device 42 and forms a low temperature flame. Here, the low temperature flame refers to a flame generating low nitrogen oxides (NOx).

Flame monitoring device 41 is used to sense whether the flame is generated by inserting obliquely upward in the bottom of the adiabatic combustion furnace 40, the flame occurs.

The overheat prevention device 42 is formed at the end of the last stage where the flame occurs on the top of the flame monitoring device 41 is used to sense whether overheating by the flame occurs.

Meanwhile, when a signal sensed by the flame monitoring device 41 and the overheat prevention device 42 is generated, the alarm sound may be output to the user by interlocking with the alarm system.

The gas discharge port 50 is formed in a shape in which the inlet is narrowed upward and includes a fifth air inflow path 51.

The fifth air inlet passage 51 is formed on the outer circumferential surface of the portion that is joined to the heat treatment combustion furnace 40 at the lower end of the gas outlet 50. The fifth air inlet passage 51 supplies oxygen to the nitrogen oxide NOx combusted in the adiabatic combustion furnace 40 so that the lower nitrogen oxide NOx is finally discharged to the gas outlet 52. Do this.

The fifth air inflow path 51 is a fifth natural inflow path for combustion air, and a large amount of air is introduced at a completely burned exhaust gas speed and temperature difference to lower the exhaust gas temperature to protect the equipment and to generate NOx. It serves to reduce.

The gas discharge part 52 includes the first air inflow path 31, the second air inflow path 32, the third air inflow path 33, the fourth air inflow path 34, and the fifth air inflow path. Low oxide (NOx) is discharged by the action of (51).

As described above, the biogas flare stack device 1 according to the present invention does not require power. In other words, if there is no power and only the control power used as a safety device required for control, it can be used anywhere, so installation conditions are easy.

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they have been used only in a general sense to easily describe the technical contents of the present invention and to facilitate understanding of the invention , And are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10: biogas train set 11: gas filter
12: gas low press switch 13: gas governor
14, 15: gas brush valve 20: combustion device
30: air inlet 31: first air inlet
32: second air inlet passage 33: third air inlet passage
34: fourth air inlet furnace 40: adiabatic combustion furnace
41: overheat protection device 42: flame monitoring device
50: gas outlet 51: fifth air inlet
52: gas discharge unit

Claims (7)

An apparatus for supplying and burning biogas to provide a biogas incinerator for low nitrogen oxide (NOx) emission, comprising: two or more combustion apparatuses; An air inlet part positioned below the adiabatic combustion furnace and configured to include a first air inflow path, a second air inflow path, a third air inflow path, and a fourth air inflow path and to which the combustion device is inserted; An adiabatic combustion furnace that generates a flame generating low nitrogen oxides (NOx) using air introduced into the air inlet; A gas outlet connected to the heat treatment combustion furnace and formed to have an inlet narrowed upwardly; And a biogas train set connected to the combustion device and configured to filter the biogas to control the amount of biogas supplied to the combustion device, wherein the first air inlet passage is inserted into the air inlet. When the combustion air by the combustion device is naturally introduced into the central portion of the combustion device so that the first natural inflow of the combustion device, the second air inlet path is a second natural inlet path of the combustion air into the combustion device air inlet A combustion device is inserted into a compartment inserted into the unit and is formed as a remaining space. The third air inlet path is configured to supply air to unburned gas coming out of the main flame by forming a flame as a third natural inflow path of combustion air. The combustion apparatus is configured to be formed in the outer compartment of the compartment inserted, the heat treatment combustion furnace, the upward side where the flame is generated in the lower portion of the heat treatment combustion furnace In the biogas flare stack device comprising a flame monitoring device which is inserted obliquely into the flame monitoring device used to sense whether the flame occurs and the overheat prevention device formed on the flame monitoring device used to sense whether the overheating occurs by the flame In
The fourth air inlet path
If there are two or more combustion devices, it is formed in the space between the combustion devices and is the 4th natural inflow path of combustion air. If the main flame is formed with the combination of several individual flames, the flame density in the middle part of the flame is high and the nitrogen oxides ( It acts as a cause of the generation of NOx), so that a large amount of air flows into the flame speed and the temperature difference in the combustion device, thereby lowering the flame temperature in the middle part, thereby reducing the generation of nitrogen oxides (NOx). Biogas flare stack device, characterized in that configured to be supplied with air. delete delete delete delete delete delete

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