The present invention relates generally to a gas burner, and more particularly to a combustion device capable of producing open fires and infrared rays.
Generally speaking, gas combustion devices are adapted to burn gas to generate flame for heating an object. When using gas combustion devices to heat an object, heat is conducted from a surface of the object to an inside of the object, such that the surface is heated greater while the interior gets less heat, resulting in the object not being heated uniformly.
To resolve the aforementioned problem, there is a known infrared ray heat source device as disclosed in Taiwan Utility Model patent M543657, which is characterized by penetrating objects with infrared rays and heating the surface as well as the interior simultaneously. At the patent, a mesh structure 1 and a guiding plate 2 form a gas returning space, so that gas is guided by a guiding surface 21 of the guiding plate 2 to form a recirculation gas, and gas enters a hole of the mesh structure 1 in a tangential direction of a first surface 11 of the mesh structure 1, and then gas penetrates a second surface 12, whereby the mesh structure 1 generates infrared rays.
However, the guiding plate 2 of the aforementioned patent is closed, so that in fact, gas cannot be returned to the first surface 11 of the mesh structure 1 along the guiding surface 21 of the guiding plate 2 as described in that patent. The reason is that after gas being outputted from a gas ejecting device 3, gas will form a back pressure between the mesh structure 1 and the guiding plate 2, and the back pressure will affect the flow of the gas so that the gas cannot return to the first surface 11 of the mesh structure 1 along the guiding surface 21, thereby most of the flame will concentrate on an area of the mesh structure 1 which is closer to the gas ejecting device 3, and cannot extend to a higher portion, resulting in uneven heating of the mesh structure 1, affecting the uniformity of the generated infrared rays.
In all aspects, the conventional infrared ray heat source device still has room for improvements.
In view of the above, the primary objective of the present invention is to provide a combustion device, which could allow the generated infrared rays to diverge evenly.
In addition, the another primary objective of the present invention is to provide a combustion device, which could enhance the intensity of the generated infrared rays.
The present invention provides a combustion device, which includes a first cover, a second cover, an infrared generating mesh, and a gas burner assembly, wherein the first cover has a first outer surface and a first inner surface which face opposite directions. A plurality of through holes penetrating through the first outer surface and the first inner surface are disposed on the first cover. The second cover has a second outer surface and a second inner surface which face opposite directions, wherein the second cover is disposed on the first cover. A chamber is formed between the second inner surface and the first inner surface. The second cover is divided into a first half portion and a second half portion. At least one hollow portion penetrating through the second outer surface and the second inner surface is disposed on the first half portion. The second half portion is closed. The infrared generating mesh is disposed between the first cover and the second cover and located in the chamber, wherein the infrared generating mesh is heated by a flame to generate infrared rays, and the generated infrared rays emit through the through holes. The gas burner assembly has a flame outlet for burning gas to generate the flame to act on the infrared generating mesh, wherein the flame outlet is located within a projection area of the second half portion.
By disposing the hollow portions on the first half portion of the second cover, the problem that the combustion device is unevenly burned due to a back pressure which causes unevenness of the emitted infrared rays could be solved. In addition, with the infrared ray generating net in the chamber, the intensity of the generated infrared rays could be effectively enhanced.
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
A combustion device of an embodiment according to the present invention is illustrated in
The first cover 10 is made of metal and includes a first body portion 12 and a first peripheral portion 14, wherein the first body portion 12 has a first outer surface 122 and a first inner surface 124 which face opposite directions. The first inner surface 124 is recessed toward the first outer surface 122 to be concave in shape. A plurality of through holes 12a penetrating through the first outer surface 122 and the first inner surface 124 are disposed on the first body portion 12. The first peripheral portion 14 is annular and extends outward from a periphery of the first body portion 12. The first cover 10 is disposed to be incline. An opening 18 penetrating through the first outer surface 122 and the first inner surface 124 is disposed on a lower position of the first body portion 12. In practice, the first body portion 12 is not limited to be concave in shape, but could be a rectangle with through holes or other shapes with through holes.
The second cover 20 is made of metal and includes a second body portion 22 and a second peripheral portion 24, wherein the second body portion 22 has a second outer surface 222 and a second inner surface 224 which face opposite directions. The second inner surface 224 is recessed toward the second outer surface 222 to be concave in shape and faces the first inner surface 124 of the first cover 10. The second peripheral portion 24 is annular and extends outward from a periphery of the second body portion 22. The second cover 20 is disposed on the first cover 10, and a chamber S is formed between the second inner surface 224 and the first inner surface 124. More specifically, the first cover 10 is fixed to the second cover 20 by engaging the second peripheral portion 24 and the first peripheral portion 14. The second cover 20 is divided into a first half portion 202 and a second half portion 204, wherein at least one hollow portion 22a penetrating through the second outer surface 222 and the second inner surface 224 is disposed on the second body portion 22 within the first half portion 202, and the second half portion 204 is closed. The second cover 20 is inclined downward from the first half portion 202 toward the second half portion 204. In the current embodiment, there are a plurality of hollow portions 22a being disposed, and the hollow portions 22a are holes.
As shown in
The infrared generating mesh 30 is disposed between the first cover 10 and the second cover 20 and is located in the chamber S. The infrared generating mesh 30 is heated by a flame to generate infrared rays, and the generated infrared rays emit through the through holes 12a of the first cover 10. In the current embodiment, the infrared generating mesh 30 has a third peripheral portion 32 disposed between the first peripheral portion 14 and the second peripheral portion 24, thereby to fix the infrared generating mesh 30 between the first cover 10 and the second cover 20, whereby the infrared generating mesh 30 is located on the first reference plane P1. A mesh density per unit area of the infrared ray generating net 30 is greater than a density of the through holes 12a per unit area of the first cover 10. The infrared generating mesh 30 could be made of metal, alloy, ceramic, etc.
The gas burner assembly 40 includes at least one burner 42, wherein the burner 42 has at least one flame outlet 422 for burning gas to generate a flame to act on the infrared generating mesh 30. The flame outlet 422 is located within a projection area of the second half portion 204 of the second cover 20. In the current embodiment, the gas burner assembly 40 includes a plurality of burners 42, and the flame outlet 422 of each of the burners 42 is located below the opening 18 of the first cover 10. The flame generated by the burners 42 acts on the infrared generating mesh 30 via the opening 18. In practice, the burner 42 of the gas burner assembly 40 is not limited to be located below the first cover 10, but could extends into the chamber S, as long as the flame is burned on the infrared generating mesh 30.
In the current embodiment, the combustion device further includes a support 50 for fixing the relative positions of the first cover 10, the second cover 20, and the gas burner assembly 40. The support 50 includes a first supporting plate 52, a second supporting plate 54, and a third supporting plate 56, wherein the third supporting plate 56 is located between the first supporting plate 52 and the second supporting plate 54. The second cover 20 is fixed on the first supporting plate 52 at where a junction of the second reference plane P2 and the third reference plane P3 (i.e., a central position of the second cover 20). The gas burner assembly 40 is fixed on the second supporting plate 54, and at least one of the first peripheral portion 14 and the second peripheral portion 24 is fixed on the third supporting plate 56.
As shown in
It is worth mentioning that, since the second half portion 204 of the second cover 20 is closed, and the flame outlet 422 of the gas burner assembly 40 is located within the projection area of the second half portion 204, the flame generated by the gas outputted from the flame outlet 422 flows toward the first half portion 202 along the second inner surface 224 within the second half portion 204. In addition, since the first half portion 202 has the hollow portions 22a, a part of the gas and a part of the flame could form an open flame outside of the chamber S along the second inner surface 224 within the first half portion 202, so that gas would not form a back pressure in the chamber S below the first half portion 202 to easily flow in the chamber S. In this way, the flame could uniformly act on the infrared ray generating net 30 and evenly act on the first cover 10, so that the intensity of the infrared rays generated by the combustion device could be increased and could be uniform.
By disposing the hollow portions on the first half portion of the second cover, the problem that the combustion device is unevenly burned due to a back pressure which causes unevenness of the emitted infrared rays could be solved. In addition, with the infrared ray generating net in the chamber, the intensity of the generated infrared rays could be effectively enhanced.
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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107123007 | Jul 2018 | TW | national |
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English abstract for KR101689089, Total of 1 page. |
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English abstract for KR20120080707, Total of 1 page. |
English abstract for TWI622738, Total of 1 page. |
Number | Date | Country | |
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20200011524 A1 | Jan 2020 | US |