KR0125473Y1 - Rotary Heater Burner Fuel Diffusion System - Google Patents

Abstract

A fuel diffusion device for a rotary heater burner according to the present invention is a fuel diffusion device for a rotary heater burner, in which a spray plate and a cover plate are rotated by a driving means to diffuse and spray liquid fuel. A plurality of gap holding protrusions 50b are integrally formed on the first flange 50a of the spray plate 50 to form uniform fine particles when the liquid fuel is diffused and sprayed through a predetermined gap formed between the plates 60. Because of this structure, it is possible to reduce the generation of ungassed gas to eliminate tar, odor and initial ignition failure, and to improve combustion conditions.

Description

Rotary Heater Burner Fuel Diffusion System

1 is a full longitudinal cross-sectional view of a typical rotary heater burner.

2 is an exploded perspective view showing a conventional fuel diffusion means.

3 is a partial perspective view showing a conventional fuel diffusion means.

4 is an exploded perspective view showing a fuel diffusion means of the present invention.

Figure 5 is an enlarged cross-sectional view showing the main portion showing the gap maintaining projection of the present invention.

6 is a partial cross-sectional view showing a rotary heater burner to which the fuel diffusion means of the present invention is applied.

* Explanation of symbols for main parts of the drawings

50: spray plate 50a: flange

50b: gap retaining projection 60: cover plate

The present invention relates to a fuel diffusion device of a rotary heater burner by a rotary atomization method, in particular, to maintain a uniform interval between the spray plate and the cover plate to form a uniform fine particles of the liquid fuel when the liquid fuel is radially diffused therebetween. It relates to a fuel diffusion device of a rotary heater burner.

In the typical rotary heater burner, as shown in FIG. 1, the main switch (not shown) is turned on so that the preheat heater 12, which is interposed between the internal burner body 10 and the sheath burner body 11, is several seconds. When the internal burner body 10 and the sheath burner body 11 are preheated, the thermistor (not shown) detects the normal condition vaporization temperature by the preheating and controls the detected signal (e.g., microcomputer; not shown). By inputting to the control means, the control means converts the input detection signal into data to operate the electronic pump 13 and the blower motor 14.

At this time, the liquid fuel stored in the fuel tank 15 is installed in the spray plate 17 through the nozzle pipe 16 along the path indicated by the white arrow by the pumping force of the electronic pump 13. After spraying from the, the driving force of the motor 19 is received by the centrifugal force by the rotation of the spray plate 17 and the cover plate 20 to be interlocked and raised upward along the inner circumferential wall surface of the spray plate 17 It is evaporated radially through a minute gap formed between the spray plate 17 and the cover plate 20 to be vaporized in contact with the inner circumferential wall of the sheath burner body 11 heated by the heat of the preheat heater 12. .

On the other hand, the air required for combustion is displayed by the black and white arrows through the air filter 22, the blower case 23, and the blower body 24 by the blowing fan 21 is rotated by receiving the driving force of the blower motor (14) After being supplied to the mixed space chamber (H) along one path, the liquid in the vaporized state is vaporized as described above while being heated in contact with the inner circumferential wall of the sheath burner body 11 heated by the exothermic heat of the preheat heater 12. By mixing with the fuel, mixed gasification is achieved.

The mixed gas is guided by the upper burner member 25 by the supply pressure of the combustion air that is continuously supplied and the rotational force of the spray plate 17 and the cover plate 20, and thus the upper portion of the induction burner member 26. The igniter 29 is diffused radially by the venturi action by the rounding part 27 concave on the upper surface of the induction burner member 26 when it is rapidly raised to the center and is ejected to the outside through a plurality of salt holes 28. It is initially ignited by the discharge of and forms a flame.

At this time, the secondary combustion air in the blower body 24 is raised through the gap formed between the outer burner body 30 and the lower circumference of the heater cover member 32 and at the same time the discharge hole 10a of the inner burner body 10. High temperature progressive heat that is discharged at intervals formed between the guide member 35 for guiding the air for combustion and the inclined surface of the cover burner body 36 to supply the flame, thereby completely burning the flame and removing toxic gases. It is supplied to the heat sink (not shown).

However, the rotary heater burner configured as described above maintains a constant interval between the spray plate 17 and the cover plate 20 so that the liquid fuel diffuses radially toward the mixed space chamber H therebetween. In order to form uniform fine particles, the gap between the spray plate 17 and the cover plate 20 acts as an important factor.

2 is an exploded perspective view showing a conventional fuel diffusion means, and FIG. 3 is a combined partial perspective view showing a conventional fuel diffusion means. In addition, the same code | symbol is attached | subjected to the same part as FIG. 1, and the overlapping description is abbreviate | omitted.

That is, the spray plate 17 of the fuel diffusion means 40 has a first flange 17a formed to be bent outward on the upper side, and a plurality of grooves 17b are bent on the first flange 17a. At the same time, the support 17c is attached to the other portion where the groove 17b is not formed by means of spot welding or the like.

At this time, the support piece 17c has the support piece 17d bent in the many direction of the outer side, and the some processus | protrusion 17e is formed in the center at regular intervals.

On the other hand, the cover plate 20 of the fuel diffusion means 40 has a plurality of insertion holes (20b) is formed in the upper surface (20a) so that the plurality of projections (17e) are inserted, the edge of the second flange ( 20c is bent downwardly, and the inclined groove 20d is positioned on the second flange 20c at a position corresponding to the groove 17b of the first flange 17a to enlarge the spraying range. At the same time, the lower protrusion 20e is formed on the bottom surface of the support 17c to maintain a predetermined interval of the first flange 17a.

That is, when the cover plate 20 is seated on the upper part of the support plate 17c deposited on the spray plate 17, the groove 17b and the inclined groove 20d are formed as shown in FIG. As the injection port 41 is formed at one side while being in contact with each other, it is possible to spread the injection range of the fuel.

However, according to the conventional fuel diffusion device of the rotary heater burner configured as described above, the fuel diffusion means 40 has the groove 17b of the spray plate 17 and the inclined groove 20d of the cover plate 20 mutually match each other. Since the gap between them is not constant and the inclined nozzle 41 is formed, the liquid fuel injected through the nozzle 41 is not formed in a certain amount of uniform particles, but is formed of non-uniform particles. As a result, a large amount of microgas is generated to cause tar, odor, failure of initial ignition, and at the same time, worsen combustion conditions.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to maintain a constant gap between the spray plate and the cover plate so that uniform fine particles are formed when the liquid fuel is radially diffused through the gap therebetween. It is to provide a fuel diffusion device of a rotary heater burner to reduce the generation of micro-gas, thereby eliminating tar, odor and initial ignition failure, and to improve the combustion conditions.

In order to achieve the above object, the fuel diffusion device for a rotary heater burner according to the present invention is a fuel diffusion device for a rotary heater burner configured to diffuse and spray liquid fuel by rotating a spray plate and a cover plate by a driving means. A plurality of gap holding protrusions are integrally formed on the first flange of the spray plate to form uniform fine particles when the liquid fuel is diffused and sprayed through a predetermined gap formed between the plate and the cover plate.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 is an exploded perspective view showing the fuel diffusion means of the present invention, and FIG. 5 is an enlarged sectional view of the main portion showing the gap maintaining protrusion of the present invention, and FIG. 6 is a rotary heater burner to which the fuel diffusion means of the present invention is applied. Partial section view. In addition, the same code | symbol is attached | subjected to the same part as FIG. 1 thru | or FIG. 3, and the overlapping description is abbreviate | omitted.

As shown in FIG. 4 and FIG. 5, in the fuel diffusion means 40, the spray plate 50 is formed with the first flange 50a flattened on the upper side thereof and bent outward. On the flange 50a, a plurality of gap holding protrusions 50b are formed at a predetermined interval, and the support 50c is spot welded to a portion of the first flange 50a without the gap holding protrusions 50b. It is attached by means of.

At this time, the support 50c is formed to be bent the support piece 50d in the plurality of directions of the outer side, the plurality of projections 50e are formed at regular intervals in the center thereof.

On the other hand, the cover plate 60 of the fuel diffusion means 40 has a plurality of insertion holes (60b) is formed in the upper surface (60a) so that the plurality of projections (50e) are inserted, the edge of the first flange The second flange 60c is bent downwardly so as to maintain a gap via the gap holding protrusion 50b so as to inject uniform fine particles.

Next, the operation and effects of the present invention configured as described above will be described.

The spray plate 50 and the cover plate 60 of the fuel diffusion means 40 configured as shown in FIGS. 4 and 5 are rotated in accordance with the driving force of the motor 19 as shown in FIG. It is coupled to the tip of the and rotates together.

At this time, the liquid fuel stored in the fuel tank 15 is pumped along the nozzle pipe 16 by the pumping force of the electromagnetic pump 13 and at the same time through the nozzle 18 mounted at the tip of the nozzle pipe 16. When the liquid fuel is supplied to the inner circumferential wall of the spray plate 50 by the centrifugal force of the spray plate 50 and the cover plate 60 which are rotated by receiving the driving force of the above-described motor 19, the spray plate is formed in the upper and lower narrow shape. Ascending on the inner circumferential wall of 50, radially diffused in the mixing space chamber H through a gap formed uniformly between the first flange 50a and the second flange 60c by the gap holding protrusion 50b. By spraying, the particles are formed into uniform fine particles.

When the uniform fine particles in the atomized state are diffused and contacted on the wall surface of the mixed space chamber H, the fine particles are brought into contact with the mixed space chamber H that has already been heated to the normal vaporization condition temperature by the preheat heater 12. The gas is vaporized and is continuously blown out through the plurality of flame holes 28 as described above, and is initially ignited by the discharge of the igniter 29 to form a flame.

As described above, according to the fuel diffusion device of the rotary heater burner according to the present invention, the second flange of the cover plate abuts on the upper portion of the first flange by a plurality of gap holding protrusions formed on the first flange of the spray plate. Since it has a structure in which a certain gap is formed between them, the liquid fuel diffused and sprayed through this gap is formed of uniform fine particles, thereby reducing the generation of ungassed gas, resulting in tar, odor and initial ignition failure. It has the effect of improving the combustion conditions and at the same time.

Claims (1)

In the fuel diffusion device of the rotary heater burner configured to rotate the spray plate and the cover plate by the drive means to diffuse the injection of liquid fuel, the liquid through a predetermined gap formed between the spray plate 50 and the cover plate 60 And a plurality of gap holding protrusions (50b) integrally formed on the first flange (50a) of the spray plate (50) so as to form uniform particles when the fuel is diffused and sprayed.