CN211781059U - Low nitrogen oxide combustor and gas heater - Google Patents

Abstract

The utility model relates to a low nitrogen oxide combustor and gas heater, low nitrogen oxide combustor include the body. The body is provided with an injection channel, a thick flame shunting part, a light flame shunting channel, a light flame mixing cavity and two thick flame mixing cavities respectively arranged at two sides of the light flame mixing cavity. The utility model discloses can effectively realize reducing nitrogen oxide and discharge. Because only one injection channel is adopted, only one gas nozzle is needed in specific use, and a plurality of injection channels and a plurality of corresponding gas nozzles are adopted relatively, so that the reliability is high.

Description

Low nitrogen oxide combustor and gas heater

Technical Field

The utility model relates to a combustor technical field especially relates to a low nitrogen oxide combustor and gas heater.

Background

In the field of gas water heaters, various gas water heater manufacturers only reduce the emission of CO at present, and do not discharge low nitrogen oxidesThere is enough interest. Most of the conventional burner technologies are ordinary atmospheric burners, NO_XThe emission of gas (nitrogen oxides) is high, which is not favorable for the low-nitrogen environmental protection emission requirement. At present, the industry adopts a burner of a thick and thin combustion technology to realize low nitrogen oxide emission. However, the conventional burner has double injection channels and a relatively complex structure, and brings many challenges to manufacturing processes, circuit program control, product performance stability and the like.

SUMMERY OF THE UTILITY MODEL

The utility model provides a first technical problem provide a low nitrogen oxide combustor, it can realize low nitrogen oxide effectively and discharge.

The second technical problem solved by the present invention is to provide a gas water heater, which can effectively realize the emission of low nitrogen oxides.

The first technical problem is solved by the following technical scheme:

a low nitrogen oxide burner comprises a body, wherein an injection channel, a light flame diversion channel, a light flame mixing cavity and two thick flame mixing cavities respectively arranged at two sides of the light flame mixing cavity are arranged on the body; the thick flame mixing cavity is communicated with the ejection channel, the light flame diversion channel is communicated between the ejection channel and the light flame mixing cavity, the wall body of the light flame diversion channel comprises a diversion section, an air supplementing section and a mixing section which are sequentially connected and arranged along the airflow direction, the outer diameter of the mixing section is larger than that of the diversion section, and the air supplementing section is provided with a plurality of air supplementing through holes; the top end face of the dense flame mixing cavity is provided with a dense flame outlet, and the top end face of the light flame mixing cavity is provided with a light flame outlet.

Low nitrogen oxide combustor compare produced beneficial effect with the background art:

when the injection passage works, a gas nozzle can be correspondingly arranged at the gas inlet of the injection passage, the gas nozzle injects gas into the injection passage at certain pressure, and simultaneously air in the atmospheric environment at the gas inlet end of the injection passage is involved and fully mixed to form primary premixed gas; part of the primary premixed gas enters the dense flame mixing cavity, is further fully mixed in the dense flame mixing cavity, and is discharged from the dense flame outlet and is combusted to form a plurality of dense flames; the other part of the primary premixed gas is sent into the light flame mixing cavity through the light flame shunting channel, under the combined action of the blowing or exhausting of the fan and the ejecting of the primary premixed gas, the outside air enters the light flame shunting channel through the air supply through hole, the supplied air and the primary premixed gas are further fully mixed in the light flame shunting channel, and finally enter the light flame mixing cavity and are sprayed out from the light flame outlet to combust to form a plurality of light flames.

That is, the injection passage simultaneously provides air-fuel mixture for the rich flame mixing cavity and the lean flame mixing cavity, the air supply through hole additionally provides supply air for the lean flame mixing cavity, and the air-fuel ratio of the mixture in the lean flame mixing cavity is greater than that of the mixture in the rich flame mixing cavity because the lean flame mixing cavity is more mixed with air than the rich flame mixing cavity, so that the lean flame combustion is correspondingly formed at the lean flame outlet and the rich flame combustion is formed at the rich flame outlet; the light flame is burnt under the condition of excessive air, the light flame is wrapped by the excessive air to reduce the temperature, the thick flame is incompletely burnt under the anoxic condition to reduce the temperature of the thick flame, and the whole flame has a 'thick-light-thick' structure, so that the temperature of the flame is integrally reduced, and the nitrogen oxide NO is further reduced_XThe discharge amount of (c); the dense flame mixing chamber and the light flame mixing chamber can make fuel and air intensive mixing for the fuel burning is more abundant, and simultaneously, dense flame is located light flame both sides, and the fuel of insufficient burning in unnecessary air in the light flame and the dense flame further burns, thereby guarantees the fuel intensive burning, improves the utilization ratio of fuel when reducing CO and discharging. Thus, the reduction of nitrogen oxide emission can be effectively realized.

The air supply structure is arranged in a through hole mode, various tests in the research and development process are facilitated, the aperture and the number of the through holes can be selectively shielded and adjusted in the test process to carry out different tests, and therefore a proper product is designed.

The air supply through hole is arranged on the air supply section between the flow distribution section and the mixing section, so that air supply is facilitated, and leakage of primary premixed gas is effectively avoided.

Because only one injection channel is adopted, only one gas nozzle is needed in specific use, and a plurality of injection channels and a plurality of corresponding gas nozzles are adopted relatively, so that the reliability is high.

In one embodiment, the plurality of air supply through holes are arranged around the air outlet of the flow dividing section.

In one embodiment, the body is further provided with an air supply passage, an air inlet of the air supply passage is communicated with the atmospheric environment, and an air outlet of the air supply passage is communicated with the plurality of air supply through holes.

In one embodiment, the air supply channel encloses the flow dividing section with a ventilation gap, and the air outlet of the air supply channel is connected with the air supply section or the mixing section.

In one embodiment, the body comprises two light flame diversion channels, and the light flame mixing cavity is provided with two air inlets; the two light flame shunting channels are respectively arranged at two sides of the injection channel and are connected with two air inlets of the light flame mixing cavity.

In one embodiment, the air supply passage is provided with two air outlets, and the two air outlets are positioned at two sides of the injection passage and are correspondingly communicated with the air supply through holes of the two air supply sections;

the air supply channel encloses the injection channel and the flow dividing section with a ventilation gap, and is provided with three air inlets which are arranged in sequence, two air inlets positioned at the side parts are positioned at the two sides of the injection channel, and the air inlet positioned at the middle part surrounds the injection channel with a gap; or the like, or, alternatively,

the air supply channel encloses the flow dividing section with a ventilation gap, and is provided with two air inlets which are positioned at two sides of the injection channel; or the like, or, alternatively,

the air supply channel encloses the injection channel and the flow dividing section with a ventilation gap, and is provided with an air inlet which surrounds the injection channel with a gap.

In one embodiment, the injection passage extends between two rich flame mixing chambers, and two opposite walls of the injection passage are respectively provided with a plurality of rich flame shunting holes communicated with the rich flame mixing chambers.

In one embodiment, a plurality of first convex hulls which are convex towards the light flame mixing cavity are sequentially arranged on the top side surface of the thick flame mixing cavity at intervals along the thick flame fire outlet; a second convex hull protruding towards the light flame mixing cavity is further arranged in the middle of the side face of the thick flame mixing cavity; the inner wall of the light flame mixing cavity is provided with a third convex hull, and the third convex hull is arranged corresponding to the air outlet end of the light flame diversion channel; and more than one fourth convex hull is arranged on the side surface of the top of the light flame mixing cavity.

In one embodiment, the body comprises a fire hole plate arranged at the light flame fire outlet, and a light flame fire outlet is arranged on the fire hole plate; the fire hole plate and the wall forming the light flame mixing cavity are of an integrated structure.

In one embodiment, the low nox burner further includes an inner core body disposed in the light flame mixing chamber, the inner core body is provided with a plurality of gas flow channels extending in a longitudinal direction, a gas inlet is disposed on a bottom end surface of the gas flow channels, and a gas outlet located at the light flame outlet is disposed on a top end surface of the gas flow channels.

The second technical problem is solved by the following technical solutions:

a gas water heater comprises the low nitrogen oxide burner.

Gas heater, compare produced beneficial effect with the background art: because include low nitrogen oxide combustor, its technical effect by low nitrogen oxide combustor bring, beneficial effect is the same with low nitrogen oxide combustor, do not give unnecessary details.

Drawings

Fig. 1 is a schematic structural diagram of a low nox burner according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a low nox burner according to an embodiment of the present invention with a portion of the area missing;

fig. 3 is a front view of a low nox burner according to an embodiment of the present invention;

FIG. 4 is a cross-sectional view at A-A of FIG. 3;

FIG. 5 is another view of FIG. 3 taken at A-A;

FIG. 6 is a cross-sectional view at B-B of FIG. 3;

fig. 7 is a schematic structural diagram of a portion of a low nox burner according to an embodiment of the present invention;

fig. 8 is another schematic structural diagram of a low nox burner according to an embodiment of the present invention;

fig. 9 is a schematic structural view of a low nox burner according to an embodiment of the present invention with a portion of the area missing;

fig. 10 is a schematic structural diagram of a low nox burner according to an embodiment of the present invention;

fig. 11 is a schematic structural view of an inner core body according to an embodiment of the present invention.

Reference numerals:

10. a body; 11. an injection passage; 12. a dense flame splitter orifice; 13. a light flame diversion channel; 131. a flow splitting section; 132. a gas supplementing section; 1321. an air supply through hole; 133. a mixing section; 14. a light flame mixing chamber; 141. a light flame outlet; 144. a third convex hull; 145. a fourth convex hull; 15. a dense flame mixing chamber; 151. a dense flame outlet; 152. a first convex hull; 153. a second convex hull; 17. an air supply passage; 18. fire hole plates; 181. a light flame fire outlet; 300. an inner core body; 301. and a gas flow passage.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of 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, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

In the description of the present invention, it is to be understood that the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the description of the present invention, it is to be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly connected" to another element, there are no intervening elements present.

In one embodiment, referring to fig. 1-6, a low nox burner includes a body 10. The body 10 is provided with an injection channel 11, a light flame diversion channel 13, a light flame mixing cavity 14 and two thick flame mixing cavities 15 respectively arranged at two sides of the light flame mixing cavity 14.

The ejection passage 11 is used for introducing air and fuel gas, the dense flame mixing cavity 15 is communicated with the ejection passage 11, a dense flame fire outlet 151 is arranged on the top end face of the dense flame mixing cavity 15, and a light flame fire outlet 141 is arranged on the top end face of the light flame mixing cavity 14.

The light flame diversion channel 13 is communicated between the injection channel 11 and the light flame mixing cavity 14, namely, the air inlet end of the light flame diversion channel 13 is arranged on the wall of the injection channel 11 and communicated with the injection channel 11, the light flame mixing cavity 14 is also provided with an air inlet, and the air outlet end of the light flame diversion channel 13 is arranged at the air inlet of the light flame mixing cavity 14.

The wall body of the light flame shunting passage 13 comprises a shunting section 131, an air supplementing section 132 and a mixing section 133 which are sequentially connected and arranged along the airflow direction, the outer diameter of the mixing section 133 is larger than that of the shunting section 131, and the air supplementing section 132 is provided with a plurality of air supplementing through holes 1321.

When the low-nitrogen oxide combustor works specifically, a gas nozzle can be correspondingly arranged at the gas inlet of the injection passage 11, the gas nozzle injects gas into the injection passage 11 at a certain pressure, and simultaneously air in the atmospheric environment at the gas inlet end of the injection passage 11 is involved and fully mixed to form primary premixed gas; part of the primary premixed gas enters the dense flame mixing cavity 15, is further fully mixed in the dense flame mixing cavity 15, and is discharged from the dense flame fire outlet 151 and is combusted to form a plurality of dense flames; the other part of the primary premixed gas is sent into the light flame mixing cavity 14 through the light flame shunting passage 13, under the combined action of blowing or air draft of the fan and ejection of the primary premixed gas, the outside air enters the light flame shunting passage 13 through the air supply through hole 1321, the supplied air and the primary premixed gas are further fully mixed in the medium and light flame shunting passage 13, the uniform mixing effect is enhanced by the light flame shunting passage 13, and then the supplied air enters the light flame mixing cavity 14 and is ejected from the light flame fire outlet 141 and is combusted to form a plurality of light flames.

That is, the injection passage 11 provides air-fuel mixture for the rich flame mixing chamber 15 and the lean flame mixing chamber 14 at the same time, and the air supply through hole 1321 additionally provides supply air for the lean flame mixing chamber 14, because the lean flame mixing chamber 14 is mixed with more air than the rich flame mixing chamber 15, the air-fuel ratio of the mixture in the lean flame mixing chamber 14 is greater than that of the mixture in the rich flame mixing chamber 15, so that the lean flame combustion is formed at the lean flame outlet 141 correspondingly, and the rich flame combustion is formed at the rich flame outlet 151; the light flame is burnt under the condition of excessive air, and the light flame is wrapped by the excessive airThe temperature is reduced, the thick flame is incompletely combusted under the anoxic condition, so that the temperature of the thick flame is reduced, the whole flame has a thick-light-thick structure, the temperature of the flame is integrally reduced, and nitrogen oxide NO is reduced_XThe discharge amount of (c); the rich flame mixing chamber 15 and the light flame mixing chamber 14 can make fuel and air intensive mixing for the fuel burning is more abundant, and simultaneously, the rich flame is located light flame both sides, and the fuel of insufficient burning in unnecessary air in the light flame and the rich flame further burns, thereby guarantees that the fuel fully burns, improves the utilization ratio of fuel when reducing CO and discharging. Thus, the reduction of nitrogen oxide emission can be effectively realized.

The air supply structure is arranged in a through hole mode, various tests in the research and development process are facilitated, the aperture and the number of the through holes can be selectively shielded and adjusted in the test process to carry out different tests, and therefore a proper product is designed.

The air supply through hole 1321 is formed in the air supply section 132 between the flow dividing section 131 and the mixing section 133, so that air can be supplied conveniently and leakage of primary premixed gas can be effectively avoided.

Because only one injection channel 11 is adopted, only one gas nozzle is needed in specific use, and a plurality of injection channels 11 and a plurality of corresponding gas nozzles are adopted relatively, so that the reliability is high.

The term "a number" as used herein means two or more in number.

The through holes can be in a circular shape, a rectangular shape or other shapes, and the shapes of the through holes can be partially the same, totally the same or different.

In one example, the gas supply section 132 is a flat plate.

Further, the plurality of air supply through holes 1321 are arranged around the air outlet of the flow dividing section 131. The scheme can enable air to enter the light flame shunting passage 13 from different angles, so that the air is more fully contacted and mixed with the primary premixed gas.

Further, referring to fig. 3, fig. 5 and fig. 8, an air supply passage 17 is further disposed on the body 10, an air inlet of the air supply passage 17 is communicated with the atmosphere, and an air outlet of the air supply passage 17 is communicated with the plurality of air supply through holes 1321. Thus, on the one hand, a certain amount of make-up air can be supplemented into the light flame mixing cavity 14 through the air inlet of the air make-up channel 17; on the other hand, the leakage of the primary premixed gas in the light flame diversion channel 13 to the outside in the process of entering the air inlet of the light flame mixing cavity 14 can be effectively avoided.

In one embodiment, the air supply channel 17 encloses the flow dividing section 131 with a ventilation gap, and the air outlet of the air supply channel 17 is connected to the mixing section 133. This embodiment provides a specific implementation of the air supply passage 17 in communication with a plurality of air supply through holes 1321, which is relatively simple in structure, easy to implement, and relatively small in space occupation.

Of course, the air outlet of the air supply channel 17 can also be designed and connected to the air supply section 132.

Further, referring to fig. 3, 5 and 7, the body 10 includes two light flame diversion channels 13, the light flame mixing cavity 14 is provided with two air inlets, and the air outlet ends of the two light flame diversion channels 13 and the two air inlets of the light flame mixing cavity 14 are respectively disposed at two sides of the injection channel 11. Naturally, one the end of giving vent to anger of light flame reposition of redundant personnel passageway 13 with an air inlet of light flame mixing chamber 14 corresponds the setting, so, draws the two air inlets that the primary premixed gas in the passageway 11 of penetrating flows into light flame mixing chamber 14 respectively through two light flame reposition of redundant personnel passageways 13 to finally enter into light flame mixing chamber 14, can be favorable to supplying air and the abundant homogeneous mixing of primary premixed gas. In addition, the number of the light flame diversion channel 13 and the number of the air inlets of the light flame mixing cavity 14 are one, three or more, which is also a feasible scheme.

For the solution with two light flame diversion passages 13, in an embodiment, referring to fig. 3, 5 and 8, the air supply passage 17 has two air outlets, and the two air outlets are located at two sides of the injection passage 11 and are correspondingly communicated with the air supply through holes 1321 of the two light flame diversion passages 13. In general, in design, the air supply passage 17 is arranged to enclose the injection passage 11 and the light flame diversion passage 13 with a ventilation gap, and a circulation space of air is formed outside the injection passage 11 and the light flame diversion passage 13 by using the air supply passage 17.

As to the arrangement scheme of the air inlets of the air supply passage 17, in an embodiment, referring to fig. 9, the air supply passage 17 encloses the injection passage 11 with a ventilation gap, and three air inlets are sequentially arranged, two air inlets located at the side portions are located at two sides of the injection passage 11, and an air inlet located at the middle portion surrounds the injection passage 11 with a ventilation gap.

In another embodiment, referring to fig. 3, 5 and 8, the air supply passage 17 encloses the injection passage 11 with a ventilation gap, and is provided with two air inlets, and the two air inlets are located at two sides of the injection passage 11.

In a further embodiment, the air supply channel 17 encloses the injection channel 11 with a ventilation gap, and only one air inlet may be provided, which surrounds the injection channel 11 with a ventilation gap.

Further, referring to fig. 1 to 5, a plurality of first convex hulls 152 protruding toward the light flame mixing chamber 14 are sequentially arranged on the top side surface of the rich flame mixing chamber 15 at intervals along the rich flame outlet 151. Therefore, the first convex hulls 152 can effectively divide the rich flame fire outlet 151 into a plurality of spaced rich flame fire outlet holes, so that the shape and size of the rich flame can be effectively ensured, and the combustion stability of the rich flame can be ensured.

In one example, referring to fig. 1 to 5, a second convex hull 153 protruding toward the light flame mixing chamber 14 is further provided on a middle portion of a side surface of the rich flame mixing chamber 15. Therefore, after the premixed gas in the injection passage 11 flows into the rich flame mixing cavity 15 through the rich flame shunting part 12, under the guiding and shunting action of the second convex hull 153, the premixed gas is shunted to the two sides of the second convex hull 153, is further uniformly mixed in the flowing process, and is finally discharged and combusted from the rich flame fire outlet 151, that is, the discharge flow rate of the premixed gas at each part of the rich flame fire outlet 151 is basically the same by the second convex hull 153.

In one example, referring to fig. 5 and 8, the inner wall of the light flame mixing chamber 14 is provided with a third convex hull 144. The third convex hull 144 is disposed corresponding to the gas outlet end of the light flame diversion channel 13. Thus, in the flowing process of the premixed gas in the light flame shunting passage 13, under the guiding action of the third convex hull 144, the flow velocity of the premixed gas changes, and is further uniformly mixed in the flowing process, and finally is discharged from the light flame fire outlet 141 for combustion, that is, the third convex hull 144 can make the discharge flow velocity of the premixed gas at each part of the light flame fire outlet 141 basically the same.

In one example, referring to fig. 5 and 8, the top side of the light flame mixing chamber 14 is provided with more than one fourth convex hull 145. As such, the fourth convex hull 145 facilitates more uniform mixing of the premixed gas within the lean flame mixing chamber 14.

In one embodiment, referring to fig. 4 and 5, the injection passage 11 extends between two of the rich flame mixing chambers 15, and two opposite walls of the injection passage 11 are respectively provided with a plurality of rich flame shunting holes 12 communicating with the rich flame mixing chambers 15. This scheme does benefit to compact structure, material saving.

Of course, from a design point of view, the injection passage 11 may not extend between the two rich flame mixing chambers 15, and the rich flame split portion is provided in a passage manner.

Referring to fig. 7, generally, the light flame diversion channel 13 and the rich flame diversion holes 12 are sequentially arranged on the wall of the injection channel 11 along the airflow direction of the injection channel 11, and the flow area of the light flame diversion channel 13 is larger than the flow areas of the rich flame diversion holes 12, so that the primary premixed gas flows to the light flame mixing chamber 14 providing the main flame better.

In one embodiment, referring to fig. 4 and 5, the body 10 includes a fire hole plate 18 disposed at the light flame outlet 141, and the fire hole plate 18 is provided with a light flame outlet 181. The fire orifice plate 18 is integral with the wall forming the weak flame mixing chamber 14. Thus, the fire hole plate 18 can effectively divide the light flame fire outlet 141 into a plurality of spaced light flame fire outlet holes 181, thereby effectively ensuring the shape and size of the light flame and ensuring the combustion stability of the dense flame.

In an embodiment, referring to fig. 10 and 11, the low nox burner further includes an inner core 300 disposed in the light flame mixing chamber 14, the inner core 300 is provided with a plurality of gas channels 301 extending in a longitudinal direction, the longitudinal direction is a direction in which the bottom of the body 10 points to the top, the bottom end surface of the gas channels 301 is provided with a gas inlet, and the top end surface of the gas channels 301 is provided with a gas outlet located at the light flame outlet 141. Therefore, the air-fuel mixture in the light flame mixing cavity 14 is respectively output outwards through the plurality of gas flow channels of the inner core body, the mixed gas is divided, the combustion noise is reduced, and the light flame combustion effect is good.

In an embodiment, the low nox burner is a catalytic burner with an additional catalyst, and the catalytic burner is a combustion device or combustion equipment using a catalyst, and the operating principle of catalytic combustion is to make organic waste gas undergo flameless combustion at a lower ignition temperature by means of the catalyst, so that the organic waste gas is decomposed into nontoxic carbon dioxide and water vapor, the catalyst has the function of reducing activation energy, and simultaneously the surface of the catalyst has an adsorption function, so that reactant molecules are enriched on the surface, the reaction rate is increased, and the reaction is accelerated. Compared with the traditional burner, the catalytic burner needs less auxiliary fuel, has low energy consumption and small volume of equipment and facilities, is favorable for further reducing the generation of nitrogen oxides, and is more environment-friendly.

In one embodiment, a gas water heater comprises the low nitrogen oxide burner of any one of the above embodiments.

The gas water heater comprises the low nitrogen oxide combustor, the technical effect of the gas water heater is brought by the low nitrogen oxide combustor, and the beneficial effects of the gas water heater are the same as those of the low nitrogen oxide combustor, so that the description is omitted.

It should be noted that: as described herein, "light flame combustion" and "rich flame combustion" are relative terms in that the fuel-to-air equivalence ratio required for "light flame combustion" and "rich flame combustion" deviates from the normal equivalence ratio. I.e. the same gas quantity, the "light flame combustion" requires a larger air quantity, while the "rich flame combustion" requires a smaller air quantity.

In order to reduce NOx emission, experiments verify that when the primary air coefficient (injection section primary air coefficient) of the rich flame is equal to 0.5-0.6, the NOx amount generated by the rich flame is low, mainly because the primary air is insufficient, the combustion is in an incomplete state, the combustion temperature is low, the generation of NOx is not facilitated, meanwhile, the fuel which is not completely combusted can be subjected to secondary combustion through air supply, and the generation of CO is effectively controlled; when the primary air coefficient of the light flame is 1.6, because oxygen is rich in the primary combustion process of the fuel, the heat released by the fuel combustion is taken away by redundant air and discharged outdoors, so that the combustion temperature of the light flame is lower, the combustion of the thick flame is stable, the light flame can be effectively prevented from leaving the flame, and the stable combustion of the combustor is ensured.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (11)

1. The low-nitrogen oxide combustor is characterized by comprising a body (10), wherein an injection channel (11), a light flame diversion channel (13), a light flame mixing cavity (14) and two thick flame mixing cavities (15) which are respectively arranged on two sides of the light flame mixing cavity (14) are arranged on the body (10); the thick flame mixing cavity (15) is communicated with the injection channel (11), the light flame diversion channel (13) is communicated between the injection channel (11) and the light flame mixing cavity (14), the wall body of the light flame diversion channel (13) comprises a diversion section (131), an air supplementing section (132) and a mixing section (133) which are sequentially connected and arranged along the airflow direction, the outer diameter of the mixing section (133) is larger than that of the diversion section (131), and the air supplementing section (132) is provided with a plurality of air supplementing through holes (1321); the top end face of the dense flame mixing cavity (15) is provided with a dense flame fire outlet (151), and the top end face of the light flame mixing cavity (14) is provided with a light flame fire outlet (141).

2. The burner according to claim 1, wherein the plurality of air make-up through holes (1321) are arranged around the air outlet of the flow dividing section (131).

3. The burner of claim 1 or 2, wherein an air supply channel (17) is further disposed on the body (10), an air inlet of the air supply channel (17) is communicated with the atmosphere, and an air outlet of the air supply channel (17) is communicated with the plurality of air supply through holes (1321).

4. The burner according to claim 3, characterized in that the air supply channel (17) encloses the flow-dividing section (131) with a ventilation gap, and the air outlet of the air supply channel (17) is connected to the air supply section (132) or the mixing section (133).

5. The burner according to claim 3, characterized in that said body (10) comprises two of said light flame branch channels (13), said light flame mixing chamber (14) being provided with two air inlets; the two light flame shunting channels (13) are respectively arranged at two sides of the injection channel (11) and are connected with two air inlets of the light flame mixing cavity (14).

6. The low NOx burner of claim 5,

the air supply channel (17) is provided with two air outlets which are positioned at two sides of the injection channel (11) and correspondingly communicated with a plurality of air supply through holes (1321) of the two air supply sections (132);

the air supply channel (17) encloses the injection channel (11) and the flow dividing section (131) with a ventilation gap, and is provided with three air inlets which are arranged in sequence, two air inlets positioned at the side parts are positioned at two sides of the injection channel (11), and the air inlet positioned at the middle part surrounds the injection channel with a gap; or the like, or, alternatively,

the air supply channel (17) encloses the flow dividing section (131) with a ventilation gap, and is provided with two air inlets which are positioned at two sides of the injection channel (11); or the like, or, alternatively,

the air supply channel (17) encloses the injection channel (11) and the flow dividing section (131) with a ventilation gap, and is provided with an air inlet which surrounds the injection channel with a gap.

7. The burner of claim 1 or 2, wherein the injection passage (11) extends between two rich flame mixing chambers (15), and two opposite walls of the injection passage (11) are respectively provided with a plurality of rich flame splitter holes (12) communicated with the rich flame mixing chambers (15).

8. The burner of claim 1 or 2, wherein a plurality of first convex hulls (152) protruding towards the light flame mixing chamber (14) are arranged on the top side of the rich flame mixing chamber (15) at intervals along the rich flame outlet (151);

a second convex hull (153) protruding towards the light flame mixing cavity (14) is further arranged at the middle part of the side surface of the strong flame mixing cavity (15);

a third convex hull (144) is arranged on the inner wall of the light flame mixing cavity (14), and the third convex hull (144) is arranged corresponding to the air outlet end of the light flame diversion channel (13);

more than one fourth convex hull (145) is arranged on the side surface of the top of the light flame mixing cavity (14).

9. The burner of claim 1 or 2, wherein the body (10) comprises a fire hole plate (18) arranged at the light flame outlet (141), the fire hole plate (18) being provided with a light flame outlet (181); the fire hole plate (18) and the side wall forming the light flame mixing cavity (14) are of an integrated structure.

10. The burner of claim 1 or 2, further comprising an inner core (300) disposed in the light flame mixing chamber (14), wherein the inner core (300) is provided with a plurality of gas flow channels (301) extending in a longitudinal direction, a gas inlet is disposed on a bottom end surface of the gas flow channels (301), and a gas outlet is disposed on a top end surface of the gas flow channels (301) at the light flame outlet (141).

11. A gas water heater comprising a low nox burner as claimed in any one of claims 1 to 10.

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