KR101284290B1 - Combustion apparatus - Google Patents

Abstract

PURPOSE: A combusting device is provided to position a flame to be far from an exit with a blow off state by supplying the reformate gas containing the hydrogen through reforming the fuel in center of the exit. CONSTITUTION: A combusting device comprises a reforming unit (100) and a supply unit (200). The reforming unit reforms the hydrocarbon fuel and the air and is formed to discharge the high temperature reformate gas containing the hydrogen to an exit. The supply unit sprays the fuel and the air to one side of the reformate gas discharged from the reforming unit and is formed to the outside of the exit for forming a flame by being separated from the exit. The supply unit is formed to spray the fuel and the air to the outside of the reformate gas discharged from the reforming unit. [Reference numerals] (AA) Fuel; (BB) Air; (CC) Hydrogen, Reformate gas

Description

Combustor {COMBUSTION APPARATUS}

The present invention relates to a combustion apparatus for reducing the amount of NOx generated by injecting a gas containing hot hydrogen produced by reforming a hydrocarbon-based fuel to form a flame at a position away from the outlet.

A general combustion apparatus is configured to meet a fuel and air supplied from inside or outside to form a diffusion flame. In this case, the amount of NOx generated may vary according to the mixing degree and the mixing speed of the fuel and air.

In order to reduce the amount of NOx generated, a combustion apparatus has been developed that injects air or fuel in multiple stages, or performs multiple stages of rich combustion and lean combustion. Multistage combustion, however, lengthens the length of the flame and complicates the structure of the combustion apparatus.

In order to solve this problem, a combustion apparatus that reduces the amount of NOx generated by rapidly mixing fuel and air has been developed. In this case, the combustion apparatus requires an igniter for ignition of the flame, and a pilot flame must be formed at the outlet of the combustion apparatus to fix and stabilize the flame in the combustion apparatus. That is, without a pilot flame, the flame blows off at the exit of the combustion apparatus.

SUMMARY OF THE INVENTION An object of the present invention is to provide a combustion apparatus that reduces the amount of NOx generated by forming a flame at a position away from an outlet to further secure a mixing time of fuel and air and to uniformly mix fuel and air.

It is also an object of the present invention to provide a combustion apparatus for reforming a fuel to supply reformed gas containing hydrogen at the center of the outlet to form flame at a position away from the outlet without blowing off.

Combustion apparatus according to an embodiment of the present invention, the reforming unit is formed on the center side to discharge the high-temperature reformed gas containing hydrogen to reform the supplied hydrocarbon-based fuel and air, and is discharged from the reforming unit And a supply part provided at least outside the outlet to inject fuel and air to one side of the reformed gas to form a flame at a position spaced apart from the outlet by a distance.

In the mixture of fuel and air supplied to the reforming unit, the liquefied natural gas (LNG) may have an O ₂ / C ratio of 0.7 to 1.9.

The reforming unit may include a first housing which supplies air and is grounded, and an electrode which is spaced apart from an inner center of the first housing and applied with a voltage.

The first housing extends in the discharge part to form a discharge gap between the electrode and to react the fuel and air under partial oxidation conditions, and to stabilize the gas discharged by the discharge part. It may include an extension.

The supply unit is formed to inject fuel and air to the outside of the reformed gas discharged from the reforming unit.

The supply unit includes a second housing spaced apart from the outer circumference of the first housing, a third housing spaced apart from the outer circumference of the second housing, and a fuel passage formed between the first housing and the second housing. And an air passage formed between the second housing and the third housing.

The air passage may be connected to the discharge part across the fuel passage by a passage connecting member connecting the second housing and the first housing.

The second housing may form sidewalls on one side of the fuel passage, and the first housing may be connected to the sidewalls by screwing or welding.

The first housing further forms a coupling part protruding toward the side wall of the second housing, wherein the fuel passage is an inflow side formed at the center of one side of the first housing, and a supply side connected to an outer circumferential side of the first housing. It includes, The coupling portion may form a through hole for connecting the inlet side and the supply side.

On the opposite side of the side wall of the second housing, an end portion of the first housing protrudes outwardly in the radial direction of the second housing so as to be spaced apart from an end portion of the second housing in the longitudinal direction of the second housing. It further comprises a flange, wherein the interval set between the flange and the end of the second housing, the supply side of the fuel passage can be opened to the radially outer edge of the second housing.

An end of the second housing and an end of the third housing may be arranged on the same line in the radial direction.

The first housing may include an inner member forming an air injection hole for injecting air toward the electrode, and an outer member coupled to an outer circumference of the inner member to form a chamber for receiving and receiving air to be injected into the air injection hole. It may include.

The air injection holes may be disposed in plural and spaced apart from the inner member in the circumferential direction, and may have an angle inclined with respect to the radial direction of the inner member.

The supply unit may be formed to inject fuel and air in a direction parallel to the discharge direction of the reformed gas from the outside of the reformed gas discharged from the reformer.

The supply unit includes a second housing spaced apart from the outer circumference of the first housing, a third housing spaced apart from the outer circumference of the second housing, and a fuel passage formed between the first housing and the second housing. And an air passage formed between the second housing and the third housing, wherein an end portion of the first housing is disposed inside the end portion of the second housing and is moved inward from the radial direction of the first housing. The flange may be formed to protrude.

An end of the second housing and an end of the second housing are formed parallel to each other, a first swirler is installed between the end of the first housing and the end of the second housing, and the end of the second housing and A second swirler may be installed between the ends of the third housing.

Thus, one embodiment of the present invention, by reforming the fuel in the reforming unit to discharge the reformed gas containing hydrogen, and supplying fuel and air to the outside of the outlet to the supply, the flame at a position spaced apart by the distance set at the outlet Can be formed stably.

Therefore, the mixing time can be further secured to the fuel and air supplied from the supply unit corresponding to the distance between the outlet and the flame in the combustion device. With the extension of the mixing time, the mixing of fuel and air is made more uniform, whereby the amount of NOx generated can be reduced.

1 is a partial cross-sectional perspective view of a combustion apparatus according to a first embodiment of the present invention.
2 is a cross-sectional view of the combustion device shown in FIG.
3 is a sectional view taken along line III-III in Fig.
4 is a photograph showing a state of a flame when burning fuel with the combustion device of FIG. 1.
Figure 5 is a photograph showing the state of the flame when burning fuel with the combustion apparatus according to the prior art.
6 is a cross-sectional view of a combustion apparatus according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is a partial cross-sectional perspective view of a combustion apparatus according to a first embodiment of the present invention, FIG. 2 is a cross-sectional view of the combustion apparatus shown in FIG. 1, and FIG. 3 is a cross-sectional view taken along line III-III of FIG. 2.

1 to 3, the combustion device 1 of the first embodiment includes a reforming unit 100 for reforming a hydrocarbon-based fuel into a high temperature reforming gas containing hydrogen, and an outlet 101 of the combustion device 1. It includes a supply unit 200 for injecting fuel and air.

Hydrogen contained in the reformed gas has fast properties in combustion rate and diffusion rate. Therefore, the hot reformed gas and hydrogen supplied from the reforming unit 100 cause the flame F to be formed at a position spaced apart from the outlet 101 of the combustion apparatus 1, and also blows off the flame F ( blow off). That is, the reformed gas and hydrogen may stabilize the flame F at a position spaced apart from the outlet 101 of the combustion device 1.

To this end, the reforming unit 100 reacts the fuel supplied and provided at the center side of the combustion device 1 under partial oxidation conditions, reforming the gas containing hot hydrogen, and converting the hydrogen and the reforming gas into an outlet ( 101).

The reformed gas discharged from the reforming unit 100 is injected from the outlet 101 to the front side (the flame F side), thereby pushing the flame F by the combustion of fuel and air supplied from the supply unit 200 to burn the combustion apparatus. It is stably maintained at a position spaced apart from the outlet 101 of (1) by a predetermined distance (L).

In this embodiment, since the reforming unit 100 is integrally provided in the combustion device 1, the reforming unit 100 can stably supply hydrogen toward the air and the fuel supplied from the supply unit 200 to the outlet 101. Therefore, the reforming unit 100 can supply hydrogen with a simple configuration, that is, it does not require a separate device for supplying hydrogen.

The supply unit 200 is provided at least outside the outlet 101 and is configured to inject fuel and air to the outside of the reformed gas discharged to form the flame F. The supply unit 200 of the present embodiment is formed in a structure that accommodates the reforming unit 100. Fuel and air supplied from the supply unit 200 are pushed by the distance L set at the outlet 101 by the reformed gas supplied from the reforming unit 100.

However, due to the fast combustion and diffusion rates of the hot reformed gas and hydrogen supplied from the reforming unit 100, the fuel and air supplied from the supply unit 200 blow at a position spaced apart by a distance L from the outlet 101. The flame (F) is kept stable while burning without being turned off.

The separation distance L set between the outlet 101 and the flame F ensures a longer mixing time of the fuel and air supplied from the supply unit 200. Therefore, the fuel and air can be more uniformly mixed while the separation distance (L) in the state leaving the outlet 101.

As described above, the combustion device 1 of the present embodiment can greatly reduce the amount of NOx generated by utilizing the fast combustion and diffusion performance of the hot reformed gas and hydrogen generated in the reforming unit 100 during fuel combustion.

If the mixing ratio of fuel and air in the reforming unit 100 is too high, partial oxidation does not occur and hydrogen is not generated. On the contrary, if the mixing ratio of fuel and air in the reforming unit 100 is too close to the combustion ratio, the flame is maintained only in the reforming unit 100 and no hydrogen is generated.

As such, if hydrogen is not generated in the reforming unit 100, the flame formed by combustion of fuel and air supplied to the supply unit 200 is turned off at the outlet 101 of the combustion device 1. Therefore, the mixture of fuel and air should have an appropriate equivalence ratio.

For example, since the theoretical equivalent ratio of partial oxidation in a hydrocarbon fuel is 0.5 and the theoretical equivalent ratio of combustion is 2.0, in the reforming unit 100, in the case of liquefied natural gas (LNG) whose main component is methane in a mixture of fuel and air, O _{The 2} / C ratio ranges between 0.7 and 1.9.

In more detail with respect to the combustion apparatus 1, the reforming unit 100 is spaced mounted in the inner center of the first housing 10 and the first housing 10, which supplies air and is electrically grounded, to supply fuel. And an electrode E to which it is supplied and to which a voltage HV is applied.

When the voltage HV is applied to the electrode E, plasma discharge is generated in the fuel and air mixed between the electrode E and the first housing 10. The fuel is then partially oxidized to form a hot reformed gas containing hydrogen.

The first housing 10 includes a discharge part 111 and an expansion part 112 set along a discharge direction of the reformed gas in which fuel and air are introduced and reformed. The discharge part 111 forms a discharge gap G between the first housing 10 and the electrode E, generates a plasma discharge in the discharge gap G, and reacts the supplied fuel and air under partial oxidation conditions. To reform.

The expansion part 112 is formed to extend larger than the diameter of the discharge part 111 at one side of the discharge part 111, and stabilizes and discharges the gas discharged by being reacted under the partial oxidation condition in the discharge part 111. That is, the reformed gas reacted in the partial oxidation condition in the discharge part 111 is stabilized while being recycled in a wide space of the expansion part 112.

The supply unit 200 includes a second housing 20 spaced apart from the outer circumference of the first housing 10 and a third housing 30 spaced apart from the outer circumference of the second housing 20. In this case, the first housing 10 is accommodated in the second housing 20, and the second housing 20 is gradually accommodated in the third housing 30. For example, the first, second, and third housings 10, 20, and 30 may form concentric circles.

The first housing 10 and the second housing 20 form a fuel passage P1 between the spaced apart from each other, and the second housing 20 and the third housing 30 form a reservoir between the spaced apart from each other. The furnace P2 is formed. The fuel passage P1 and the air passage P2 supply fuel and air supplied to one side to the reforming unit 100 and the supply unit 200.

For example, the air passage P2 is crossed by the fuel passage P1 by the passage connecting member 21 penetrating the second housing 20 and connected to the first housing 10. It is connected to the discharge unit 111. The air passage P2 supplies air to the discharge part 111. In addition, the air passage P2 supplies air between the end portions E2 and E3 of the second and third housings 20 and 30 of the supply unit 200.

For example, the second housing 20 forms a side wall 21 on one side of the fuel passage P1, and the first housing 10 is screwed or welded to the side wall 21 of the second housing 20. It can be connected in a variety of ways. For screwing, the first housing 10 further forms a joining portion 11 protruding toward the side wall 21 of the second housing 20. In other words, the male screw of the coupling portion 11 is screwed to the female screw of the side wall 21.

In this case, the fuel passage P1 set between the first and second housings 10 and 20 has an inflow side P11 formed at the center of one side of the first housing 10 and an outer periphery of the first housing 10. And a supply side P12 connected to the side.

The coupling part 11 of the first housing 10 forms a through hole 12 connecting the inflow side P11 and the supply side P12 of the fuel passage P1. The air flowing into the inflow side P11 is supplied to the discharge unit 111, and is also supplied to the air side P12 through the through hole 12 of the coupling unit 11.

On the opposite side of the side wall 21 of the second housing 20, the first housing 10 has a flange 13 at an end E1 which is set at one side of the second housing 20 in the longitudinal direction (left-right direction in FIG. 2). ).

The flange 13 protrudes outwardly in the radial direction of the second housing 20 to form a gap C between the flange 13 and the end E2 of the second housing 20. The interval C opens the supply side P12 of the fuel passage P1 toward the radially outer side of the second housing 20, so that the supplied fuel can be supplied in the outer direction of the second housing 20.

At this time, the end portion E2 of the second housing 20 and the end portion E3 of the third housing 30 are arranged on the same line in the radial direction, so that air supplied to the air passage P2 is received at both ends E2. , E3) to mix with the fuel supplied.

That is, the fuel supplied to the fuel passage (P1) is supplied to the end of the air passage (P2) through the gap (C), mixed with the air supplied to the air passage (P2) of the outlet 101 in the combustion device (1) Discharged forward to form flame (F).

According to the coupling range of the coupling part 11 of the first housing 10 to the side wall 21 of the second housing 20 can be adjusted to the size of the interval (C). The mixing ratio of air and fuel may be set by controlling the supply amount of the fuel supplied to the fuel passage P1 to the supply amount of the air supplied to the air passage P2 according to the size of the gap C.

In addition, the first housing 10 includes an inner member 14 and an outer member 15 which are coupled to each other and partially overlap each other in the longitudinal direction. The inner member 14 forms an air injection port 16 for injecting air toward the electrode E of the discharge part 111.

The air injection holes 16 are plurally spaced apart from the inner member 14 in the circumferential direction, and have an inclination angle θ with respect to the radial direction of the inner member 14 (see FIG. 3). Therefore, the air supplied to the air injection port 16 is supplied while rotating in the circumferential direction between the electrode E and the first housing 10 and in the gap G.

The outer member 15 is coupled to the outer circumference of the inner member 14 to form a chamber 17 for receiving and receiving air to be injected into the air injection port 16. Therefore, the chamber 17 maintains the pressures of the supplied air uniformly so as to equalize the amount of air injected into the plurality of air injection holes 16.

On the other hand, the electrode E which forms the discharge part 111 with the inner member 14 forms the fuel injection hole 26 which injects fuel. The fuel injection hole 26 injects the fuel supplied connected to the inflow side P11 of the fuel passage P1 to the inner wall of the inner member 14 around the gap G.

The fuel injected into the gap G of the discharge part 111 is mixed with the rotating air injected into the air injection port 16 and is driven by the voltage HV set between the electrode E and the inner member 14. It reacts under partial oxidation conditions, causing a rotating arc. In other words, the fuel is reformed into a hot gas containing hydrogen.

Hydrogen and reformed gas reformed in the discharge part 111 are stabilized and discharged to the outlet 101 while being recycled in the expansion part 112. The discharged hydrogen and the reformed gas act as a pushing force within the distance L in the range set in front of the outlet 101 to push the fuel and air supplied to the supply unit 200 out of the range L.

Therefore, the fuel and air supplied to the supply unit 200 reach outside the range of the distance L through the outside of the region of hydrogen and the reforming gas. At the same time, the reforming gas maintains a high temperature and hydrogen has a fast combustion and diffusion rate. Therefore, the fuel and air supplied to the supply unit 200 maintains the flame F stably while implementing lean combustion outside the distance L range.

The fuel and air supplied to the supply unit 200 are mixed in a more uniform state with an additional mixing time while traveling by the distance L, thereby implementing lean combustion. Therefore, when the fuel is burned, the amount of NOx generated can be reduced.

4 is a photograph showing the state of the flame when burning fuel with the combustion device 1 of FIG. 1, and FIG. 5 is a state of the flame when burning fuel with the combustion device 2 according to the prior art. It is a photograph shown.

4 and 5, the conventional combustion apparatus 2 forms flame F2 in proximity to the outlet. In contrast, the combustion apparatus 1 of the present invention stably forms the flame F at positions spaced apart by the distance L from the outlet 101. It can be seen that the flame F is not formed at the central portion of the outlet 101.

A second embodiment of the present invention will be described below. Compared with the first embodiment, the description of the same configuration will be omitted and different configurations will be described.

6 is a cross-sectional view of a combustion apparatus according to a second embodiment of the present invention. Referring to FIG. 6, in the combustion apparatus 3 of the second embodiment, the supply unit 300 is connected to the fuel in a direction parallel to the discharge direction of the reformed gas on the outside of the reformed gas containing hydrogen discharged from the reformer 100. It is formed to inject air.

For example, the end portion E21 of the first housing 10 may be disposed inside the end portion E22 of the second housing 20 to protrude inward in the radial direction of the first housing 10. It is provided.

The flange 23 may reduce or control the rate of the reformed gas containing hydrogen ejected through the outlet 102 by narrowly forming the outlet 102 in the discharge part 111.

The end E23 of the third housing 30 is disposed side by side with the outlet 102 together with the end E22 of the second housing 20. The first swirler S1 is provided between the end portions E21 and E22 of the first and second housings 10 and 20 forming the fuel passage P1 to rotate the discharged fuel. The second swirler S2 is provided between the end portions E22 and E23 of the second and third housings 20 and 30 forming the air passage P2 to rotate the discharged air.

Accordingly, the air discharged between the fuel discharged between the end portions E21 and E22 of the first and second housings 10 and 20 and the end portions E22 and E23 of the second and third housings 20 and 30 may be discharged between the first and second housings 10 and 20. It may be mixed while turning by the second swirler (S1, S2), it may be discharged while turning in a direction parallel to the discharge direction of the reformed gas,

The fuel and air mixed by the first and second swirlers S1 and S2 may form the flame F without being turned off by a distance L from the outlet 102 according to the discharge speed of the reformed gas. .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And it goes without saying that the invention belongs to the scope of the invention.

10, 20, 30: 1st, 2nd, 3rd housing 11: coupling part
12: through hole 13, 23: flange
14: inner member 15: outer member
16: air nozzle 17: chamber
21: side wall 100: modified part
101, 102: outlet 111: discharge part
112: expansion unit 200: supply unit
C: spacing E1, E2, E3, E21, E22, E23: end
F: Flame L: Distance
P1: fuel passage P11: inflow side
P12: Supply Side P2: Air Path
1, 2, 3: combustion device

Claims (16)

A reforming unit formed at the center side to reform the supplied hydrocarbon-based fuel and air to discharge hot reformed gas containing hydrogen to the outlet; And
A supply unit provided at least outside the outlet to inject fuel and air to one side of the reformed gas discharged from the reforming unit to be spaced apart from the outlet to form a flame
Including;
Wherein the supply unit includes:
And a combustion device configured to inject fuel and air to the outside of the reformed gas discharged from the reformer.
The method of claim 1,
Combustion apparatus of O ₂ / C ratio in the case of liquefied natural gas (LNG) in the mixture of fuel and air supplied to the reforming unit is 0.7 ~ 1.9.
The method of claim 1,
The reforming part
A first housing which supplies air and is grounded, and
Electrodes spaced apart from the inner center of the first housing to which a voltage is applied
Combustion apparatus comprising a.
The method of claim 3,
The first housing includes:
A discharge portion for forming a discharge gap between the electrode and reacting the fuel and air under a partial oxidation condition, and
Expansion portion formed to expand in the discharge portion to stabilize the gas discharged by the reaction in the discharge portion
Combustion apparatus comprising a.
delete The method according to claim 3 or 4,
Wherein the supply unit includes:
A second housing spaced apart from an outer circumference of the first housing,
A third housing spaced apart from an outer circumference of the second housing
/ RTI >
A fuel passage formed between the first housing and the second housing, and
An air passage formed between the second housing and the third housing
Combustion apparatus further comprising.
The method according to claim 6,
The air passage,
And a passage connecting member connecting the second housing and the first housing to be connected to the discharge unit across the fuel passage.
The method according to claim 6,
The second housing includes:
A side wall is formed on one side of the fuel passage,
The first housing includes:
Combustion apparatus connected to the side wall by screwing or welding.
9. The method of claim 8,
The first housing includes:
A coupling portion protruding toward the side wall of the second housing,
The fuel passage,
An inflow side formed at the center of one side of the first housing, and
A supply side connected to an outer circumferential side of the first housing,
The coupling portion
And a through hole connecting the inflow side and the supply side.
10. The method of claim 9,
On the opposite side of the side wall of the second housing, the end of the first housing,
And a flange protruding outwardly in the radial direction of the second housing to form a gap with an end portion of the second housing in a longitudinal direction of the second housing,
The gap set between the flange and the end of the second housing,
And a supply side of the fuel passage to a radially outer side of the second housing.
The method of claim 10,
And an end portion of the second housing and an end portion of the third housing are disposed on the same line in the radial direction.
The method of claim 3,
The first housing includes:
An inner member forming an air injection hole for injecting air toward the electrode, and
An outer member coupled to an outer circumference of the inner member to form a chamber for receiving and receiving air to be injected into the air injection hole;
Combustion apparatus comprising a.
The method of claim 12,
The air injection port,
The inner member is disposed in a plurality spaced apart in the circumferential direction,
And a combustion device having an inclined angle with respect to the radial direction of the inner member.
The method according to claim 3 or 4,
Wherein the supply unit includes:
And a fuel and air are injected in a direction parallel to a discharge direction of the reformed gas from the outside of the reformed gas discharged from the reformer.
The method of claim 12,
Wherein the supply unit includes:
A second housing spaced apart from an outer circumference of the first housing,
A third housing spaced apart from an outer circumference of the second housing
/ RTI >
A fuel passage formed between the first housing and the second housing, and
An air passage formed between the second housing and the third housing
Further comprising:
An end of the first housing,
And a flange disposed inside the end of the second housing to protrude inwardly in the radial direction of the first housing.
16. The method of claim 15,
The end of the second housing and the end of the second housing are formed parallel to each other,
A first swirler is installed between an end of the first housing and an end of the second housing,
And a second swirler is installed between the end of the second housing and the end of the third housing.

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