Infrared hydrogen/oxygen combustor

Abstract

The present invention provides an infrared hydrogen/oxygen combustor. The structure of the combustor includes a sinus ring (1). A surrounding foot (12) of the angle-shaped sinus ring (1) wraps a material-containing basin (14). A first small tube (16) and a second small tube (7) are connected the material-containing basin (14) and the angle-shaped sinus ring (1). Water solution (3) is contained in the material-containing basin (14). A straight-hole ceramic water-absorbing board (5) is provided on the upper part of the water solution (3), a spacing ring (6) is provided above the side of the material-containing basin (14) and in the upward ring of the angle-shaped sinus ring (1), a two-stage material-containing box (9) with a separated brake is provide on one side of the angle-shaped sinus ring (1). The technical scheme of the invention reduces the production cost, the pollution and protects the environment.

Claims

1. An infrared hydrogen/oxygen combustor in the field of combustion heating, comprising: an angle-shaped sinus ring (1) with a surrounding foot for passing water and producing gas; a surrounding foot (12) of the angle-shaped sinus ring (1) wraps a material-containing basin (14); a gas-gathering chamber (17) is formed between an outer wall of the material-containing basin (14) and an inner wall of a lower part of the surrounding foot (12); a primary energy gas inlet (18) is provided on one side of the gas-gathering chamber (17); a first small tube (16) and a second small tube (7) are connected with the material-containing basin (14) and the angle-shaped sinus ring (1) for exchanging water, water vapor and air; water solution (3) is contained in the material-containing basin (14); a first catalytic material barrier (15) is arranged in the water solution (3) at the lower part of the material-containing basin (14); a straight-hole ceramic water-absorbing board (5) is provided on an upper part of the water solution (3) matching with an inner wall of the material-containing basin (14); a middle lower part of the water-absorbing board (5) is soaked in the water solution (3), that is, full range of solution positioning; a spacing ring (6) is provided above the rim of the material-containing basin (14) and inside the upward ring of the angle-shaped sinus ring (1); an infrared radiation board (2) is provided in the inner surface of the spacing ring (6) having a same number of holes and facing the straight-hole ceramic water-absorbing board (5) in the material-containing basin (14); a two-stage material-containing box (9) with a separated brake is provide on one side of the angle-shaped sinus ring (1); a second catalytic material barrier (10) is provided in each of the separated brake of the material-containing box (9); the two-stage material-containing box (9) is communicated with the angle-shaped sinus ring (1) and material-containing basin (14) respectively by a third small tube (8) and a forth small tube (13), so that the original water and the added water be controlled separately; the original water in the material-containing basin (14) can be supplied on demand, and the original water is separated from the added water, the water capacity in the material-containing basin (14) is controlled, and it overcomes the negative effect produced by entering too much or too little water, and the concentration of catalyst in aqueous solution is increased by putting the catalytic material in the material-containing box, decomposition of the reaction is increased.

2. The infrared hydrogen/oxygen combustor of claim 1, wherein a function of the gas-gathering chamber (17) is that: the primary energy gas is buffered at the corner of the angle-shaped sinus ring (1), and rise to the bottom side of the spacing ring (6) through a parietal suture (11) and are evenly distributed in a lateral gap (4) between the lower surface of the infrared radiation board (2) and the upper surface of the water-absorbing board (5), aqueous solution gas mixed contact reaction and infrared light irradiation can modify the thermal chemical reaction and realize decomposition of water vapor by the combination of light-ray electromagnetic.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further explanation is described in conjunction with the drawings.

(2) FIG. 1 is a schematic structural view of an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Embodiment 1

(3) The structure of the combustor is an angle-shaped sinus ring (1) with a surrounding foot can pass water vapor, the angle-shaped sinus ring (1) can take in water and product water vapor, a surrounding foot (12) of the angle-shaped sinus ring (1) is wrapped with a material-containing basin (14), a gas-gathering chamber (17) is formed between the outer wall of the material-containing basin (14) and the inner wall of the surrounding foot (12) at the lower part of the angle-shaped sinus ring (1), a primary energy gas inlet (18) is provided on one side of the gas-gathering chamber (17), the primary energy gas is buffered at the corner of the angle-shaped sinus ring (1), and rise to the bottom side of the spacing ring (6) through a parietal suture (11) and are evenly distributed in a lateral gap (4) between the lower surface of the infrared radiation board (2) and the upper surface of the water-absorbing board (5), aqueous solution gas mixed contact reaction and infrared light irradiation can modify the thermal chemical reaction and realize decomposition of water vapor by the combination of light-ray electromagnetic.

(4) A first small tube (16) and a second small tube (7) are connected with the material-containing basin (14) and the angle-shaped sinus ring (1), the first small tube (16) is used to introduce the steam in the ring into the material-containing basin (14) to heat and promote aqueous solution floating to create the decomposition condition, while the second small tube 7 is used to introduce the steam and at the same time empty effect the sinus ring (I) to support running water into the ring. A water solution (3) is provided in the material-containing basin (14), a first catalytic material barrier (15) is arranged in the water solution (3) at the lower part of the material-containing basin (14), the effect of the first catalytic material barrier (15) is to make pure water as a brine solution catalyst that supports the hydrogenolysis; a straight-hole ceramic water-absorbing board (5) is provided on the upper part of the water solution (3) and is matched with the inner wall of the material-containing basin (14), the middle lower part of the water-absorbing board (5) is soaked in the water solution (3), that is, full range of solution positioning, the solution (3) is heated and expanded by the heating source of the sinus ring (1) to move up to the optimum decomposition reaction zone close to the fire point for decomposition; a spacing ring (6) is provided above the side of the material-containing basin (14) and in the upward ring of the angle-shaped sinus ring (I), an infrared radiation board (2) is arranged relative to the inner surface of the spacing ring (6), and the hole number of the water-absorbing board (5) and the infrared radiation board (2) is identical, and the holes of the water-absorbing board (5) and the infrared radiation board (2) are corresponding, so that the infrared light below the board (2) transmits deeply to the water-absorbing board below by mesh-to-mesh and wall-to-wall and the large-area effect in the micro-wall pores is formed to cause a variety of chemical reactions to decompose.

(5) A two-stage material-containing box (9) with a separated brake is provided on one side of the angle-shaped sinus ring (1), the two-stage material-containing box (9) is communicated with the angle-shaped sinus ring (1) and material-containing basin (14) respectively by a third small tube (8) and a forth small tube (13), so that the original water and the added water can be controlled separately, and the original water in the material-containing basin (14) can be supplied on demand, the purpose is separating the original water from the added water, controlling the water capacity in the material-containing basin (14), and overcoming the negative effect produced by entering too much or too little water, and the concentration of catalyst in aqueous solution is increased by putting the catalytic material in the material-containing box, decomposition of the reaction is increased.