KR0139346Y1 - Radiation apparatus compulsion convector type rotary heater - Google Patents

Abstract

The heat dissipation device of the forced convection type rotary heater of the present invention is a heat dissipation device of a forced convection type rotary heater in which a radiator is installed on an upper side of a burner part, The radiator 80 has an outer periphery larger than the upper outer periphery of the burner unit 20 and at the same time an upper surface of the burner unit 20 to accommodate a plurality of salt holes 20a formed at the upper end of the burner unit 20. Since it is disposed in, it is possible to eliminate flame blowing, incomplete combustion, odor and uneven radiation, and to improve the heat radiation efficiency and heating efficiency.

Description

Heat dissipation device of forced convection rotary heater

1 is an overall cross-sectional view showing a conventional forced convection rotary heater.

Figure 2 is a cross-sectional view showing a forced convection rotary heater of the present invention.

* Explanation of symbols for main parts of the drawings

20: burner 20a: flame

80: radiator

The present invention relates to a heat dissipation device of a forced convection type rotary heater, and in particular, by placing the outer periphery of the radiator outside the position of a plurality of salt holes installed in the burner portion to increase the heat area and improve heat dissipation efficiency and heating efficiency. The radiating device of the forced convection rotary heater.

In the conventional forced convection rotary heater, as shown in FIG. 1, the burner part 20 which receives a fuel and forms a flame is provided in the upper center of the fuel tank 10, and this burner part 20 is provided. At the upper side of the heat sink is provided with a radiator 30 that conducts the direct heat radially when the direct heat by the flame generated from the flame hole (20a) formed around the upper end of the burner portion 20 is raised, The upper edge of the fuel tank 10 is provided with a base portion 40 so that the lower portion of the burner portion 20 is received inside.

In addition, a safety net 50 is installed at the upper middle circumference of the base part 40 so that the upper part of the burner part 20 and the radiator 30 are accommodated inside, and a top plate is provided at the upper end of the safety net 50. 60 is installed, the upper end of the safety net 50, the duct member 70 for adjusting the heat to prevent the top plate 60 is overheated by the radiant heat emitted from the radiator 30 rises ) Is installed.

At this time, the radiator 30 has a larger outer circumferential edge than the outer circumferential edge of the burner unit 20 to accommodate the plurality of salt holes 20a formed at the upper end of the burner unit 20.

That is, the radiator 30 includes a plurality of gap retaining pieces 31 installed on the top of the burner unit 20 to supply secondary combustion air with flames formed in the plurality of flame holes 20a, and the burner unit ( A guide plate 32 installed at a predetermined interval on the interval maintaining piece 31 to guide the direct heat (combustion heater) rising from 20) and the direct heat rising by the guide plate 32 is radially radiated. The heat radiating body 33 installed on the upper edge of the guide plate 32 so as to diffuse and dissipate therein, and the direct heat in the heat radiating body 33 is prevented from escaping and conducts direct heat to radiate radiant heat. Consists of a heat dissipation upper plate 34 installed on the top of the heat dissipation body (33).

However, according to the heat dissipation device of the conventional forced convection rotary heater configured as described above, the outer periphery of the radiator 30 is formed smaller than the upper outer periphery of the burner unit 20 and is formed at the top of the burner unit 20. Since it is disposed at a position that can not accommodate a plurality of flame holes (20a), the flame generated from the plurality of flame holes (20a) during combustion protrudes outward from the outer periphery of the radiator 30, causing sparks to fly Incomplete combustion, odor and nonuniform radiation were generated, which lowered the heat radiation efficiency and the heating efficiency.

Therefore, the present invention has been made to solve the above problems, and the object of the present invention is to prevent flames from escaping out of the radiator during combustion, eliminating sparking, incomplete combustion, odor and non-uniform radiation, thereby heat radiation efficiency And to provide a heat radiation device of the forced convection rotary heater to improve the heating efficiency.

In order to achieve the above object, the heat dissipation device of the forced convection type rotary heater of the present invention is a heat dissipation device of a forced convection type rotary heater in which a heat radiator is installed on an upper side of a burner, wherein the heat dissipator is larger than the outer periphery of the upper end of the burner part. It is characterized in that it is disposed on the upper surface of the burner portion to have a plurality of salt holes formed on the upper end of the burner portion at the same time.

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

In addition, in the figure, the same code | symbol is attached | subjected about the same structure as the conventional structure, and the detailed description is abbreviate | omitted.

The forced convection rotary heater of the present invention, as shown in Figure 2, the fuel tank 10 for storing liquid fuel (petroleum), the liquid fuel supplied from the fuel tank 10 and the air for combustion air The burner unit 20 installed in the upper center of the fuel tank 10 to ignite the mixed gas of the flame to form a flame through the plurality of flame holes (20a), and the direct heat rising from the burner unit 20 is conducted radially A radiator 80 installed on the upper side of the burner unit 20 so as to be diffused therein, a base unit 40 installed on the upper edge of the fuel tank 10 so that the burner unit 20 is received inside, and the burner A safety net 50 installed around the upper middle circumference of the base part 40 so that the upper part of the part 20 and the radiator 80 are received inward, and a top plate 60 installed on the upper end of the safety net 50; The top plate 60 by radiant heat emitted from the radiator 80 and raised. ) Consists of a duct member 70 installed on the inner top of the safety net 50 to prevent overheating.

At this time, the outer periphery of the radiator 80 is formed to be larger than the upper outer periphery of the burner unit 20 and is disposed to accommodate a plurality of salt holes 20a.

That is, the radiator 80 has a plurality of intervals installed in the upper portion of the burner unit 20 to supply air for secondary combustion with flames generated from the plurality of flame holes 20a formed at the upper end side of the burner unit 20. Retaining piece 81 and the guide plate 82 provided at regular intervals on the upper portion of the gap retaining piece 81 to guide the direct heat rising from the plurality of salt holes (20a) to the center, the guide of the guide plate 82 The heat radiating body 83 installed on the upper edge of the guide plate 82 so as to radiate and radiate the direct heat rising radially and the direct heat in the heat radiating body 83 are blocked and the direct Consists of a heat shield plate 84 installed on the top of the heat radiating body 83 to receive heat and radiate radiant heat.

On the other hand, the base portion 40 is the lower plate 41 is fixed to the upper edge of the fuel tank 10, the body 42 fixed to the outer peripheral surface of the lower plate 41, and the burner unit 20 The upper plate 43 is fixed to the upper portion of the body 42 with a through hole 43a in the center so that the upper side of the burner unit 20 is upwardly projected while maintaining a predetermined interval with the outer circumferential surface.

In addition, the duct member 70 has a lower hole duct 71 fixed to the upper inner circumferential surface of the safety net 50 so that radiant heat rising from the radiator 80 is guided to the center and passed therethrough. And a plurality of brackets 72 which are fixed to the upper surface of the lower duct 71 at regular intervals along the circumference of the passage hole 71a, and the passage hole 71a of the lower duct 71. It consists of an upper duct (73) installed through the plurality of brackets 72 on the upper side of the through hole (71a) to prevent the radiated heat is radiated diffused to prevent the top plate (60) from overheating.

In the drawing, reference numeral 90 denotes a liquid fuel supply means for pumping and supplying liquid fuel stored in the fuel tank 10 into the burner unit 20, and 100 denotes the burner unit 20 during combustion. It is a blocking plate that prevents heat radiating from the radiator 80 from being conducted to the lower side of the burner unit 20.

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

As shown in FIG. 2, when the burner unit 20 is operated by operating a main control unit (not shown) installed in the base unit 40, all of the high-temperature direct heat generated from the burner unit 20 is radiator ( While rapidly rising to 80, and radially diffused through a plurality of heat dissipation holes (not shown) formed in the heat dissipation body 83 of the heat dissipator 80, the air is discharged to the center of the product through the safety net 50 to heat the indoor air. It is heated by air.

At this time, the guide plate 82, the heat dissipation body 83 and the heat dissipation top plate 84 of the radiator 80 is mounted on the top of the burner unit 20 by a plurality of gap retaining pieces 81 burner unit 20 Since the outer periphery of the radiator 30 is larger than that of the outer periphery, and is configured to accommodate a plurality of salt holes 20a, it is generated from a plurality of salt holes 20a formed around the upper end of the burner unit 20 during combustion. The flame does not escape to the outside of the radiator 80 and at the same time easily flows in the arrow direction indicated by the secondary combustion air to the inside of the radiator 80 through the flames formed around the plurality of flame holes 20a. It flows smoothly.

Because of this, the flame formed in the plurality of flame holes (20a) can be eliminated flame blowing, incomplete combustion, odor and non-uniform radiation as the secondary combustion in the radiator 30 can improve the heat radiation efficiency and heating efficiency .

On the other hand, the high temperature radiant heat radiated from the heat radiating upper plate 84 of the radiator 80 hits the edge of the lower duct 71 and is primarily blocked, so that some radiant heat is formed in the center of the lower duct 71. ) And at the same time hit the upper duct (73) is blocked secondarily, and the radiant heat hit the upper duct (73) between the lower duct (71) and the upper duct (73) by a plurality of brackets (72). The top plate 60 is prevented from being overheated by the radiant heat rising by being radially diffused through a predetermined interval formed at the same time and being discharged to the upper edge of the set through the safety net 50.

As described above, the heat dissipation device of the forced convection rotary heater of the present invention prevents flames generated from a plurality of flame holes from burning out of the radiator, thereby eliminating sparks, incomplete combustion, odor and uneven radiation. It can be effective to improve the heat radiation efficiency and heating efficiency.

Claims (1)

In the heat dissipation device of the forced convection type rotary heater in which the radiator is installed on the upper side of the burner, the radiator 80 has an outer periphery larger than the outer periphery of the upper end of the burner unit 20 and at the same time the upper end of the burner unit 20. Heat dissipation device of the forced convection-type rotary heater, characterized in that disposed on the upper surface of the burner portion 20 to accommodate a plurality of salt holes (20a) formed in the.