KR200394730Y1 - Electric Fan Combined Hot Wind - Google Patents

Abstract

The present invention relates to a fan combined with a hot air that can be selectively used as a fan or a hot air according to the season, and more specifically, the far-infrared radiation with the radiant heat by the air forcedly blown from the rotary blades by inserting a heating element in the spiral far-infrared radiator It is a structure that can be radiated. At this time, the surface of the rotor blade is coated with a metal layer to reflect heat radiated from the heat transfer body, and to generate turbulence on the surface of the rotor blade to minimize the frictional resistance of air. A plurality of grooves are formed.

Description

Hot air combined electric fan {Electric Fan Combined Hot Wind}

The present invention relates to a fan that can be selectively used as a fan or a warmer according to the season, and more particularly, by inserting a heating element into the spiral far-infrared radiator, the far infrared rays are radiated together with the radiant heat by the air forcedly blown from the rotary blades. In this case, the surface of the rotor blade is coated with a metal layer to reflect the heat radiated from the heat transfer body, and also generates a turbulence on the surface of the rotor blade to minimize the frictional resistance of air It relates to a hot air combined electric fan, characterized in that the groove portion is formed.

Generally, fans are summer appliances that are used only from June to September, when the heat starts, and they are stored only in seasons outside of summer.

In addition, the electric fan-type electric fan used in winter is also used only in cold weather for 3 or 4 months and stored like a fan from spring to late autumn.

In order to secure this, a hot air combined use fan has recently been developed. However, such a hot air combined fan is a configuration in which only the heating element in front of the rotary blades.

This configuration cuts off the power of the heating element in the summer and functions as a general electric fan, and in winter, connects the power to the heating element so that the forcedly blown wind passes through the heating element and sends out the hot air. Therefore, in accordance with the well-being era these days, additional additional functions such as far-infrared emission are required.

On the other hand, general fans have been developed with great emphasis on the number and area of each rotor blade in consideration of wind blowing.

Therefore, the noise of the rotary blades due to the air resistance and there was a disadvantage that consumes a lot of power.

Therefore, the noise and power consumption of the rotor blade can be minimized, and the structure of the far-infrared radiator is required to emit far-infrared rays by minimizing the air resistance from the air sent out.

Therefore, the present invention was devised in view of the above-described conventional problems, and a first object of the present invention is to provide a combined hot air fan that can be selectively used as a fan or a hot air fan according to the season.

The second object of the present invention is to fix the far-infrared radiator of the spiral shape in front of the rotary blade, and insert the heating element into the fixed far-infrared radiator, and the far infrared rays will be radiated together with the radiant heat by the air forcedly blown from the rotary blade. It is to provide a hot air combined use fan having a structure that can be.

In addition, the third object of the present invention, the metal layer is coated on the surface of the rotary blade to reflect the heat radiated from the heating element, and also to generate turbulence on the surface of the rotary blade to minimize the frictional resistance of air It is to provide a hot air combined fan formed with a groove portion.

The objects of the present invention, in the fan,

It is fixed to the inner side of the safety net 20 of the fan so as to be disposed in front of the rotary blade 10, the far-infrared radiation body 30 of the polyhedral structure through which the front / rear surface is penetrated so that the wind forcedly blown from the rotary blade 10 is vented. ; And a heat transfer body 40 seated correspondingly to the inside of the far infrared radiation body 30 so that heat can be applied to the far infrared radiation body 30. The far infrared radiation body 30 includes the Take a spiral shape that gradually extends from the center to the outer shell so as to be arranged over the front of the safety net 20, and at both ends to fix the heat transfer body 40 and expose the terminals of the heat transfer body 40, respectively. It is achieved by the warm air combined electric fan characterized in that 31 is formed.

In the above, the far infrared ray emitter 30 preferably has a lattice structure.

In the above, the far-infrared radiator 30 preferably takes a radial structure.

The rotary blade 10 is preferably coated with a metal layer 12 on the surface to reflect the heat radiated from the heat transfer body (40).

The rotary blade 10 is preferably formed with a plurality of grooves 11 to minimize the frictional resistance of the air by generating turbulence on the surface.

In the above, the far-infrared radiator 30 is preferably processed by pulverizing and mixing at least one or more of ocher, charcoal, elvan, jade, ceramic, and germanium.

In the above, the far-infrared radiator 30 preferably protrudes in a triangular shape in contact with the blown wind in order to minimize resistance of the air blown from the rotary blade 10.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings with respect to the hot air combined electric fan according to the present invention will be described in detail.

Figure 1a is a perspective view of a hot-air combined electric fan according to a first embodiment of the present invention, Figure 1b is an exploded perspective view of the far-infrared radiator and the heating element extracted in Figure 1a, Figure 1c is a far-infrared ray radiator according to AA line of Figure 1b It is sectional drawing, FIG. 1D is the combined perspective view of FIG. 1B.

As shown in Figures 1a to 1d, the present invention is forced from the rotary blade 10 by inserting the heating element 40 in the spiral far-infrared radiator 30 to be selectively used as a fan or a hot air according to the season. It is a device having a structure in which far infrared rays can be radiated together with radiant heat by air blown.

The hot air combined electric fan is composed of two parts, which is composed of a far-infrared radiator 30 for generating far infrared rays, and a heat transfer body 40 for generating heat.

Here, the far infrared ray radiator is configured to be fixed to the inner side of the safety net 20 of the fan to be disposed in front of the rotary blade 10.

The far-infrared radiator 30 is a plastic working process by pulverizing and mixing at least one or more of ocher, charcoal, elvan, jade, ceramic and germanium. At this time, the shape has a structure of a rectangular parallelepiped through which the front / rear is penetrated so that the air forcibly blown from the rotary blade 10 can be smoothly ventilated, and gradually from the center to the outer shell to be arranged over the front of the safety net 20 of the fan. It is an enlarged spiral.

In addition, the far-infrared radiator 30 is configured to protrude in a triangular shape the surface in contact with the blown wind in order to minimize the resistance of the air blown from the rotary wing (10).

The far-infrared radiator 30 of this structure is fixed to the heat transfer body 40 through which the front and rear surfaces are penetrated, which insulates the heat transfer body 40 that is electrically heated and at the same time heat generated from the heat transfer body 40. This is to apply the to the far-infrared radiator 30 so that far-infrared rays can be radiated from the far-infrared radiator 30.

Meanwhile, the heat transfer body 40 has both terminals 41 of the heat transfer body 40 fitted to both ends of the far infrared radiation body 30 so as to be stably fixed to the far infrared radiation body 30. For this purpose, the far infrared radiation body 30 At both ends, the terminal port 31 is formed.

FIG. 1E is a perspective view of the rotating blade taken from FIG. 1A.

As shown in Figure 1e, the rotary blade 10 is coated with a metal layer 12 to the surface to radiate heat generated from the heat transfer body 40, it is possible to prevent deformation of the rotary blade 10 by the heat. It is configured to be. On the other hand, the rotary blade 10 may be composed of a metal material without having to coat the whole with a metal layer (12).

In addition, the rotary blade 10 may be configured by forming a plurality of grooves 11 on the surface of each wing to minimize the frictional resistance of the air by generating turbulence. In this case, the groove 11 is preferably disposed evenly on the surface of each wing of the rotary blade (10).

This structure is for generating turbulence in each groove 11 formed on the front surface when the rotary blade 10 rotates. This is to reduce the frictional resistance and noise by inducing a conflict of turbulence with the outer air layer of the rotary blade (10).

That is, the outer air layer of each wing is a vortex generated finely as the rotary blade 10 rotates. The vortex and turbulence are conflicted to reduce the noise, thereby reducing the frictional resistance, thereby allowing air to be blown with a relatively low power consumption.

2 is a plan view of a far infrared ray radiator and a heat transfer body according to a second embodiment of the present invention, and FIG. 3 is a plan view of a far infrared ray radiator and a heat transfer body according to a third embodiment of the present invention.

As shown in FIG. 2 and FIG. 3. First, as shown in FIG. 2, in the second embodiment, unlike the first embodiment, the far-infrared radiator 30 may have a lattice structure. At this time, the shape of the heat transfer body 40 also has a lattice structure corresponding to the shape of the far-infrared radiation body 30.

In addition, the far-infrared radiator 30 may have a radial structure as shown in the third embodiment of FIG.

As described above, the hot air combined electric fan according to the present invention can be configured with two, three, four, five, six, seven, and eight, in addition to one heating element 40.

As described above, according to the combined hot air fan, it may be selectively used as a fan or a hot air fan according to the season, and in particular, far infrared rays may be radiated together with the hot air radiant heat, and thus may be used as a functional hot air fan.

In addition, the metal layer is coated on the surface of the rotor blade to reflect the heat radiated from the heating element to maximize the effect of the warm air.

In addition, by generating turbulence on the surface of the rotor blades can minimize the frictional resistance of the air can bring noise reduction, thereby reducing the power consumption.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the present invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the present invention.

Figure 1a is a perspective view of a combined hot air fan according to a first embodiment of the present invention,

Figure 1b is an exploded perspective view of the far-infrared radiator and the heating element extracted in Figure 1a,

Figure 1c is a cross-sectional view of the far infrared radiation along the line A-A of Figure 1b,

Figure 1d is a perspective view of the combination of Figure 1b,

Figure 1e is a perspective view of the rotary blade extracted from Figure 1a,

2 is a plan view of a far infrared ray radiator and a heat transfer body according to a second embodiment of the present invention;

3 is a plan view of a far infrared ray radiator and a heat transfer body according to a third embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: rotary blade 11: groove

12: metal layer 20: safety net

30: far infrared radiator 31: terminal

40: heat transfer element 41: terminal

Claims (7)

In the fan, It is fixed to the inner side of the safety net 20 of the fan () to be disposed in front of the rotary blade 10, the far-infrared radiator of the polyhedral structure through which the front and rear surface is penetrated so that the wind forcedly blown from the rotary blade (10) ( 30); And And a heat transfer body 40 seated in a shape corresponding to the inside of the far infrared radiation body 30 so that heat can be applied to the far infrared radiation body 30. The far-infrared radiator 30 takes a spiral shape gradually extending from the center to the outer shell so as to be arranged over the front surface of the safety net 20, and at the same time the terminal of the heat transfer body 40 is fixed to the heat transfer body 40. Hot air combined use fan, characterized in that the terminal port 31 is formed at both ends to be exposed. The method of claim 1, The far-infrared radiator 30 is a combined hot air fan, characterized in that it takes a grid structure. The method of claim 1, The far-infrared radiator 30 is a combined hot air fan, characterized in that it takes a radial structure. The method of claim 1, The rotary blade 10 is a combined hot air fan, characterized in that the metal layer 12 is coated on the surface to reflect the heat radiated from the heat transfer body (40). The method according to claim 1 or 4, The rotary blade 10 has a plurality of grooves 11 is formed so that the turbulence on the surface to minimize the frictional resistance of the air fan combined hot air. The method according to any one of claims 1 to 3, The far-infrared radiator 30 is a hot-air combined fan, characterized in that the plastic processing by grinding at least one or more of ocher, charcoal, elvan, jade, ceramic and germanium. The method according to any one of claims 1 to 3, The far-infrared radiator (30) is a combined hot air fan, characterized in that the surface in contact with the air blown to project a triangular shape in order to minimize the resistance of the air blown from the rotary blade (10).