The present invention relates generally to a heating apparatus, and more particularly to a combustor which could facilitate the mixing of gas and air, so as to make burning more evenly.
As shown in
However, the conventional combustor 1 fails to burn gas evenly due to the shape of the pipe 2a. In more details, the pipe 2a of the main body 2 has a bending section. When the flow of gas and air entering through the inlet 2b arrives at the bending section of the pipe 2a, most of the flow would turn to the left after bumping into the bending section. Moreover, because the diameter of the pipe 2a gradually reduces from the right to the left after the bending section, after passing through the bending section, most of the flow would flow along the wall of the pipe 2a to be exhausted through the flame holes 3a on the left half of the burner tray 3. As a result, the exhausted flow from the flame holes 3a of the burner tray 3 would be gradually decreased from the left to the right.
In view of the above, the primary objective of the present invention is to provide a combustor which can exhaust an even flow from the flame holes of the burner tray.
The present invention provides a combustor including a pipe and a burner tray. The pipe has a first pipe section and a second pipe section, wherein the first pipe section extends in a predetermined direction. The first pipe section has an inlet at an end thereof, and the second pipe section has a first end and a second end, wherein the first end is connected to another end of the first pipe section. The second pipe section is bent in a direction away from the another end of the first pipe section, and is provided over the first pipe section. The second pipe section has an outlet extending along an axial direction thereof, and a sectional area of the second pipe section is reduced from the first end to the second end. The second pipe section has at least one reduced section, wherein a smallest sectional area in the at least one reduced section is smaller than sectional areas on both sides of the reduced section. The burner tray is connected to the second pipe section, wherein the burner tray is provided over the outlet, and has a plurality of flame holes which communicate with the outlet.
Whereby, with the reduced section provided in the second pipe section of the combustor, the flow including gas could be evenly delivered to the burner tray. As a result, after the gas exhausted through the flame holes is ignited, the combustion range would be evener, which enhances the combustion efficiency.
The present invention will be best understood by referring to the following detailed description of some illustrative embodiments in conjunction with the accompanying drawings, in which
As shown in
The main body 10 consists of two symmetrical plates 102 formed by stamping into predetermined shapes, and has a pipe 12, two side plates 22, two inclined plates 24, and two vertical plates 26. The pipe 12 is transverse U-shaped, including a first pipe section 14 and a second pipe section 16. The first pipe section 14 extends along a predetermined direction D, and has an inlet 142 at an end thereof. The first pipe section 14 has a constricted section 144 between two ends thereof, wherein the inner diameter of the constricted section 144 is smaller than that of the other parts of the first pipe section 14. The sectional area in the constricted section 144 tapers off and then gradually increases along the predetermined direction D.
The second pipe section 16 has a first end 162 and a second end 164, wherein the first end 162 is connected to another end of the first pipe section 14, while the second pipe section 16 is bent in a direction away from the another end of the first pipe section 14, and is provided over the first pipe section 14. The second pipe section 16 inclines upward gradually after where the second pipe section 16 is bent, and the sectional area of the second pipe section 16 is reduced from the first end 162 to the second end 164. The second pipe section 16 has an outlet 166 on the top thereof, and extending along an axial direction thereof In this embodiment, the outlet 166 is elongated, and has a starting end 166a and a terminal end 166b, wherein the starting end 166a is located at where the second pipe section 16 is bent, near the first end 162 of the second pipe section 16, while the terminal end 166b is near the second end 164 of the second pipe section 16.
The second pipe section 16 has two opposite inner walls 168 and 168′ in the predetermined direction D at where the second pipe section 16 is bent, wherein one of the inner walls 168 near the inlet 142 has a turning point 168a. The second pipe section 16 has at least one reduced section between the turning point 168a and the second end 164, wherein the reduced section is formed by stamping, and the smallest sectional area in the reduced section is smaller than sectional areas on both sides of the reduced section. In this embodiment, the at least one reduced section includes two reduced sections, including a first reduced section 16a and a second reduced section 16b. The first reduced section 16a is located between and connects a first segment 16c and a second segment 16d, while the second reduced section 16b is located between and connects the second segment 16d and a third segment 166e.
As shown in
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As shown in
The two inclined plates 24 are respectively connected to the tops of the two side plates 22. The distance between the two inclined plates 24 gradually increases from the bottom to the top, and the degree of increasing thereof is greater than the that of the two side plates 22. The two vertical plates 26 are respectively connected to the tops of the two inclined plates.
The hole plate 28 is connected to the two vertical plates 26, and has a first end 28a and a second end 28b. The first end 28a is near the starting end 166a of the outlet 166, while the second end 28b is near the terminal end 166b of the outlet 166. Additionally, the hole plate 28 has a plurality of flame holes which communicate with the outlet 166 of the second pipe section 16, wherein the flame holes includes a plurality of first flame holes 282 and a plurality of second flame holes 284. The first flame holes 282 are aligned along the long axial direction of the burner tray 20. The second flame holes 284 are distributed to two sides of the first flame holes 282 in the short axial direction of the burner tray 20, wherein the second flame holes 284 on each of the two sides of first flame holes 282 are aligned along the long axial direction of the burner tray 20. In this embodiment, the second flame holes 284 are aligned in the long axial direction of the burner tray 20 in pairs, and at least one of the first flame holes 282 is provided between each two adjacent pairs of the second flame holes 284. In this embodiment, four first flame holes 282 are provided between each two adjacent pairs of the second flame holes 284, while in other embodiments, the number of the first flame holes 282 is not limited to four. Each pair of the second flame holes 284 is aligned on the same axis in the short axial direction of the burner tray 20. In practice, the second flame holes 284 could also be distributed to two sides of the first flame holes 282 in a staggered manner.
A room 202 is formed between the hole plate 28 and the two vertical plates 26. The splitting member 30 is provided in the room 202, and has a passage 302 and a plurality of perforations 304, wherein the passage 302 extends along the long axial direction of the burner tray 20; the perforations 304 are aligned in the long axial direction of the burner tray 20, and are distributed to two sides of the passage 302 in the short axial direction.
As shown in FID. 12, with the aforementioned structures, when the flow of gas and air enters the first pipe section 14 of the pipe 12 through the inlet 142, and then passes through the constricted section 144, the flow rate of the flow is increased because the sectional area of the constricted section 144 passage sectional area tapers off first and then gradually increases. Next, after the flow is delivered to where the second pipe section 16 of the pipe 12 is bent, a part of the flow runs upward and out of the second pipe section 16 through the region between the starting end 166a of the outlet 166 and the first reduced section 16a. In more details, before running out of the second pipe section 16 through the region near the starting end 166a of the outlet 166, the flow runs upward against the wall of the side plate 22, and thus is affected by the protrusion 222 above the starting end 166a. Therefore, the part of the flow runs toward the first end 28a of the hole plate 28, and sufficient flow is exhausted through the first flame holes 282 and second flame holes 284 between the protrusion 222 and the first end 28a of the hole plate 28.
Additionally, after the flow is delivered to where the second pipe section 16 is bent, another part of the flow runs toward the second end 164 of the second pipe section 16. Because the sectional area of the first reduced section 16a reduces, the flow running toward the second end 164 is confined by the first reduced section 16a. The resistance to the flow before the first reduced section 16a is less. As a result, a part of the flow runs upward and is exhausted from the outlet 166 before the first reduced section 16a. Accordingly, sufficient flow is exhausted through the first flame holes 282 and second flame holes 284 between the first reduced section 16a and the protrusion 222.
Next, a part of the flow passing through the first reduced section 16a would run upward and is exhausted from the outlet 166 before the second reduced section 16b because the sectional area of the second reduced section 16b decreases. Thus, sufficient flow is exhausted through the first flame holes 282 and second flame holes 284 between the first reduced section 16a and the second reduced section 16b.
In addition, after passing through the second reduced section 16b and running toward the outlet 166, the flow is affected by the protrusion 224 between the second reduced section 16b and the terminal end 166b of the outlet 166, and thus would run toward the second end 28b of the hole plate 28. Therefore, sufficient flow is exhausted through the first flame holes 282 and second flame holes 284 between the protrusion 224 and the second end 28b of the hole plate 28. The second flame holes 284 are used to adjust partial flame.
In the abovementioned embodiment, the number of the reduced sections is two. However, the problem of uneven flow exhaust could be improved by the first reduced section only, without the second reduced section. In other embodiments, the second pipe section could have more than two reduced sections. In addition, one of the two pairs of protrusion 222, 224 on the walls of the side plates 22 can be selectively provided depending on the desired combustion efficiency. However, if the desired combustion efficiency has been met, the protrusions protrusion 222, 224 can be omitted. In addition, the splitting member 30 can be omitted practically.
In conclusion, with the reduced section in the second pipe section, the flow including gas could be evenly delivered to the burner tray. As a result, after the gas exhausted through the flame holes is ignited, the combustion range would be evener, which enhances the combustion efficiency.
It must be pointed out that the embodiments described above are only some preferred embodiments of the present invention. All equivalent structures which employ the concepts disclosed in this specification and the appended claims should fall within the scope of the present invention.
Number | Date | Country | Kind |
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105131036 | Sep 2016 | TW | national |