KR20160060314A - Hair dryer using Coanda effect - Google Patents

Abstract

The present invention relates to a hair dryer using a coanda effect, and comprising: a blowing fan formed on a handle unit; a coanda nozzle disposed at the upper portion of the blowing fan; a discharge nozzle coupled to an air discharge unit of the coanda nozzle; a discharge nozzle coupled to an air discharge unit of the coanda nozzle; and a main heater disposed to pass through the inside the coanda nozzle, or disposed on an air suction unit of the coanda nozzle. The coanda nozzle is connected to the blowing fan so that the air compressed by the blowing fan can be introduced inside thereof to be sprayed, and outer air is introduced inside thereof by the compressed air sprayed inside thereof to be sucked through the air suction unit, and then to be discharged through the air discharge unit. Accordingly, the hair dryer of the present invention can freely dispose the heater by using the coanda nozzle, thereby reducing the length of the hair dryer to manufacture the same in a compact size.

Description

[0002] Hair dryer using Coanda effect [0003]

The present invention relates to a hair dryer having a Coanda effect, in which a heater can be freely arranged by using a Coanda nozzle, and thus a compact hair dryer can be manufactured.

Generally, the hair dryer has a long nozzle body 10 as shown in FIG. The grip body 20 is formed at the rear end of the nozzle body 10 so that the grip portion 23 is extended to the lower side of the grip body 20.

The nozzle body 10 and the grip body 20 are provided with a heating unit 40 for heating air to be discharged and an air blowing unit 30 at the rear of the heating unit 40, The air is sucked in from the rear side of the air blowing unit 30 and the air is conveyed to the discharge unit 12 side by the blowing unit 30 and heated through the heating unit 40 while being conveyed.

However, since the conventional hair dryer uses a blowing fan formed of a plastic material, the arrangement of the heaters is limited. That is, if the heater is disposed behind the blowing fan, the air heated by the heater is transmitted to the discharge port side through the blowing fan, so that the fan and the motor may be overheated and damaged or fire may occur. The length of the hair dryer becomes long and the arrangement of the heaters is limited.

KR 10-2013-0115845 (2013.10.22)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a hair dryer in which a heater can be freely arranged using a coanda nozzle, Of the hair dryer.

In order to achieve the above-mentioned object, the hair dryer of the present invention has a blower fan formed in a handle portion, The air compressed by the blowing fan is blown in and blown into the inside by the blowing fan, the outside air is drawn into the inside by the compressed air injected into the inside, and is sucked through the air suction part to be discharged to the air discharging part, A coanda nozzle disposed at an upper portion of the blowing fan; A discharge nozzle coupled to the air discharge portion of the Coanda nozzle; And a main heater provided to pass through the inside of the Coanda nozzle or on the air intake side of the Coanda nozzle; And a control unit.

In addition, the Coanda nozzle includes a compressed air inflow part connected to the blowing fan, through which air compressed by the blowing fan flows; A compressed air direction guiding part for spraying compressed air in an inclined direction toward the air discharge part on the side of the air suction part; A curved portion protruding from the inner circumferential surface so as to form a gap with the compressed air direction guiding portion and formed so as to narrow the diameter of the inner flow path; Further comprising a gap adjusting handle screwed to the air discharging portion of the Coanda nozzle and having the curved portion coupled to one side and the discharge nozzle coupled to the other side, And the size of the gap is adjusted by the gap.

Further, an insertion groove is formed in the air discharge portion of the Coanda nozzle, and a spring is interposed in the insertion groove, and the spring is brought into close contact with the gap adjustment nozzle and the gap adjustment handle.

In addition, a core is further provided inside the Coanda nozzle so that the inner space of the Coanda nozzle is narrowed, and the main heater is coupled to the outer circumferential surface of the core.

The main heater is provided on the side of the air intake portion of the Coanda nozzle, and an auxiliary heater is further provided between the compressed air inflow portion into which the compressed air flows into the Coanda nozzle and the blowing fan.

Further, the main heater is characterized in that the heating value is larger than that of the auxiliary heater.

In addition, the main heater is formed in a cylindrical shape, and a through hole is formed to penetrate the inside of the main heater to allow air to pass therethrough.

Further, the side where the outside air of the through-hole is sucked is formed to be inclined or round.

The hair dryer of the present invention uses a Coanda nozzle to place a heater so as to pass through the inside or inside of the Coanda nozzle or to place the heater behind the Coanda nozzle and between the compressed air inlet of the Coanda nozzle and the blower fan It is possible to reduce the length of the hair dryer and to manufacture the hair dryer in a compact size.

1 is a schematic view of a conventional hair dryer;
2 is a front sectional view showing a hair dryer of the Koanda effect according to the first embodiment of the present invention.
3 is a partially enlarged view showing a structure for controlling the gap of the Coanda nozzle according to the present invention.
4 is a partially enlarged view showing a gap adjustment handle portion according to the present invention.
5 is a front sectional view showing a hair dryer of the Koanda effect according to a second embodiment of the present invention.
FIG. 6 and FIG. 7 are cross-sectional views showing a cross section of the main heater portion of FIG. 5;

Hereinafter, the hair dryer of the Koanda effect of the present invention will be described in detail with reference to the accompanying drawings.

≪ Example 1 >

2 is a front sectional view showing a hair dryer of the Koanda effect according to the first embodiment of the present invention.

As shown in the drawing, the hair dryer 1000 of the Koanda effect according to the first embodiment of the present invention includes a blowing fan 100 formed in the handle 110; The air compressed by the blowing fan 100 is blown into the blowing fan 100 and blown into the inside of the blowing fan 100. The outside air is drawn into the inside by the compressed air injected into the inside of the blowing fan 100, (200) disposed above the blowing fan (100) so as to be sucked and discharged to the air discharge part (240); A discharge nozzle 300 coupled to the air discharge portion 240 of the Coanda nozzle 200; And a main heater 400 provided to pass through the interior of the Coanda nozzle 200 or provided on the air intake part 230 side of the Coanda nozzle 200; . ≪ / RTI >

First, the blowing fan 100 may be formed in the handle 110, and serves to supply compressed air to the coanda nozzle 200 by sucking and compressing the outside air. The blowing fan 100 may be various types of fans or compressors such as an axial flow fan and a centrifugal fan. The blowing fan 100 is connected to the operation switch 120 formed on the handle 110, And the rotational speed can be controlled to control the pressure of the compressed air.

The coanda nozzle 200 is disposed on the upper part of the air blowing fan 100 and the air blowing fan 100 and the coanda nozzle 200 are connected to each other so that the compressed air supplied from the blowing fan 100 is supplied to the coanda nozzle The outside air is drawn into the inside by the coanda effect and the outside air is sucked into the air suction part 230 which is one side of the coanda nozzle 200 and the air discharged from the air discharge part 240 Can be discharged. The detailed structure of the coanda nozzle 200 will be described in detail below.

The discharge nozzle 300 is coupled to the air discharge portion 240 of the coanda nozzle 200 so that the air having passed through the coanda nozzle 200 is discharged to the discharge port 320 through the discharge nozzle 300. At this time, the discharge nozzle 300 is formed with a taper 310 having an inner diameter larger toward the air flow direction, so that the dynamic pressure caused by the air to be flowed is changed to a constant pressure so that more of the outside air can be introduced. In addition, the discharge port 320, which is the end of the discharge nozzle 300, can be formed as a linear tube having a constant inner diameter to increase the flow rate of discharge.

The main heater 400 may be provided so as to pass through the inside of the coanda nozzle 200. The main heater 400 may be disposed on the side of the coanda nozzle 200 on the side of the air suction portion 230 of the coanda nozzle 200, As shown in FIG. In this case, when the main heater 400 is provided so as to pass through the inside of the coanda nozzle 200, the main heater 400 may be spaced apart from the inner periphery of the coanda nozzle 200 and disposed along the center in the longitudinal direction . When the main heater 400 is provided on the side of the air suction part 230 of the coanda nozzle 200, the main heater 400 is separated from the surface of the coanda nozzle 200 on the air suction part 230 side . Further, the main heater 400 may be connected to the operation switch 120 and controlled ON / OFF.

A plurality of holes or a mesh-shaped cover 700 may be coupled to the air intake part 230, which is a rear part of the coanda nozzle 200, to allow external air to flow in.

Thus, the hair dryer of the present invention uses a Coanda nozzle, so that a heater is disposed to pass through the inside or inside of the Coanda nozzle, or the rear of the Coanda nozzle and the compressed air inlet of the Coanda nozzle, It is possible to reduce the length of the hair dryer and to manufacture the hair dryer in a compact size.

Also, the Coanda nozzle 200 includes a compressed air inflow part 210 connected to the blowing fan 100 and through which air compressed by the blowing fan 100 flows; A compressed air direction inducing unit 250 for injecting compressed air in an inclined direction toward the air discharging unit 240 at the air suction unit 230 side; A curved portion 260 projecting from the inner circumferential surface so as to form the compressed air direction guiding portion 250 and the gap 255 to narrow the inner flow path 220; A gap adjustment handle (not shown) which is screwed to the air discharge portion 240 of the Coanda nozzle 200 and has the curved portion 260 coupled to one side and the discharge nozzle 300 coupled to the other side, The size of the clearance 255 can be adjusted by rotating the gap adjusting handle 600. In addition,

As shown in FIG. 3, the Coanda nozzle 200 is an air discharge unit 240, one side of which is sucked and sucked with external air, and the other side of which discharges the sucked air, An internal flow path 220 is formed in the inside of the air. A compressed air inflow part 210 through which compressed air flows from the blowing fan 100 is formed on the outer peripheral surface of the coanda nozzle 200. The compressed air inflow part 210 is formed inside the outer peripheral surface along the circumferential direction It can be formed as an empty space. The compressed air direction inducing part 250 is formed in an inclined direction toward the air discharging part 240. The compressed air direction guiding part 250 is formed on the inner circumferential surface side to be connected to the air suction part 230, do. The curved portion 260 is formed so as to protrude from the inner circumferential surface so as to form the compressed air direction guiding portion 250 and the gap 255 so that the diameter (inner diameter) of the inner flow path 220 is narrowed.

Thus, when the compressed air is injected through the gap 255 into the inside of the coanda nozzle 200, the air flows along the inner circumferential surface where the curved portion 260 is formed, so that the outside air can be attracted and sucked.

A male screw 610 is formed on an outer circumferential surface of the gap adjusting handle 600 and a female screw 270 is formed on an inner circumferential surface of the air discharging portion 240 of the coil inner nozzle 200, The curved portion 260 is screwed to the air discharging portion 240 of the main body 200 and the curved portion 260 is coupled to one side of the gap adjusting handle 600 to rotate the gap adjusting handle 600, The size of the clearance 255 can be adjusted.

As the size of the gap 255 is adjusted, the amount of outside air introduced into the inside of the coanda nozzle 200 can be adjusted. More specifically, the amount of compressed air supplied by being compressed by the air blowing fan 100 The clearance 255 is narrowed by rotating the gap adjusting handle 600 as the pressure of the air is increased, so that the static pressure is lowered in a portion where the inner diameter of the curved portion 255 is small, so that the dynamic pressure of the flowing air is increased, The air volume to be discharged can be increased. That is, according to the capacity of the blowing fan 100, the size of the gap 255 can be adjusted by using the gap adjusting handle 600 to obtain a desired air volume.

An insertion groove 241 is formed in the air discharging portion 240 of the Coanda nozzle 200 and a spring 280 is inserted into the insertion groove 241. The spring 280 is inserted into the insertion hole 241, Can be brought into close contact with the gap adjusting handle (600).

4, when the gap adjusting handle 600 is spaced apart from the right side surface of the air discharging portion 240 of the coanda nozzle 200 by the rotation of the gap adjusting handle 600 to widen the gap 255, The elasticity of the spring 280 prevents the gap adjusting handle 600 from being easily rotated by vibration or an external force.

The core 290 is further provided inside the Coanda nozzle 200 so that the inner space of the Coanda nozzle 200 is narrowed and the main heater 400 is coupled to the outer circumferential surface of the core 290 .

At this time, the core 290 facilitates the coanda effect by allowing the compressed air injected through the gap 255 to flow into the coil nozzle 200 along the inner circumferential surface where the curved portion 260 is formed, Accordingly, the outside air can be easily drawn into the inside of the coanda nozzle 200. The core 290 may be disposed at the center of the internal flow path 220 and the side corresponding to the air intake part 230 which is one side of the core 290 may be inclined or rounded, Can be smoothly sucked. The main heater 400 may be coupled to the outer circumferential surface of the core 290 and the main heater 400 may be formed into a coil shape wound around the outer circumferential surface of the core 290, .

≪ Example 2 >

5 is a front sectional view showing a hair dryer of the Koanda effect according to the second embodiment of the present invention.

As shown in the figure, the hair dryer 1000 according to the second embodiment of the present invention includes the main heater 400 disposed on the air suction portion 230 side of the Coanda nozzle 200, An auxiliary heater 500 may be further provided between the compressed air inflow part 210 through which the compressed air flows into the Coanda nozzle 200 and the blowing fan 100.

That is, the main heater 400 is not disposed inside the coanda nozzle 200 but is disposed on the air suction portion 230 side of the Coanda nozzle 200, which is the rear side in the air flow direction, The auxiliary heater 500 is disposed between the blowing fan 100 and the compressed air inlet 210 so that the temperature at which the air is heated can be reduced It can be maintained at a desired temperature. In the absence of the auxiliary heater 500, since the unheated compressed air is injected into the inside of the coanda nozzle 200 and mixed with the air heated by the main heater 400, The auxiliary heater 500 can prevent the temperature of the air from being lowered.

In addition, the main heater 400 may generate a larger amount of heat than the auxiliary heater 500.

That is, when the temperature of the compressed air compressed by the air blowing fan 100 and injected into the inside of the coil nozzle 200 is high, the density decreases and the amount of movement (density and flow velocity) of the air decreases, The amount of heat generated by the main heater 400 may be larger than that of the auxiliary heater 500 so that the air can be heated to a high temperature while reducing the effect of the attraction of the outside air. At this time, only the main heater 400 or the auxiliary heater 500 can be operated or both can be operated by the operation switch 120 formed on the handle 110.

One third of the air volume discharged through the discharge port 320 of the discharge nozzle 300 is compressed through the air blowing fan 100 to be air injected into the inside of the coanda nozzle 200, 500) can be used to heat the air to be used at low or moderate temperatures. When the temperature is raised to a higher temperature, the main heater 400 can be operated together. In addition, when the main heater 400 is disposed behind the coanda nozzle 200, the coanda nozzle 200 can be heated and deformed. Therefore, the coanda nozzle 200 can be made of a metal material such as aluminum or a heat resistant plastic material .

In addition, the main heater 400 may be formed in a cylindrical shape and may have a through-hole 420 through which the air passes.

6, when the main heater 400 is disposed on the side of the air intake part 230 of the coanda nozzle 200, the plurality of through holes 420 are formed in a cylindrical shape or a donut shape, A plurality of slots 420 are formed along the circumferential direction of the cylindrical body 410 and a plurality of heating elements 430 are fixed to the body 410 to form a shape As shown in FIG. 7, a heating element 430 (heating coil) is wound around a body 410 formed in a radial shape to form a cylindrical shape or a curved shape, Donut type, and the like.

In addition, the side of the through-hole 420 where the outside air is sucked may be formed in an inclined or rounded shape so that the outside air can be sucked and flow smoothly.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1000: Hair dryer with Coanda effect
100: blowing fan
110: Handle 120: Operation switch
200: Coanda Nozzle
210: Compressed air inflow part 220: Internal flow path
230: air suction part 240: air discharge part
241: insertion groove 250: compressed air direction guide portion
255: gap 260:
270: female thread 280: spring
290: Core
300: Discharge nozzle
310: Taper 320: Outlet
400: main heater
410: body 420: through-hole
430: Heating Elements
500: auxiliary heater
600: Clearance adjustment handle
610: Male thread
700: cover

Claims (8)

A blowing fan formed in the handle portion;
The air compressed by the blowing fan is blown in and blown into the inside by the blowing fan, the outside air is drawn into the inside by the compressed air injected into the inside, and is sucked through the air suction part to be discharged to the air discharging part, A coanda nozzle disposed at an upper portion of the blowing fan;
A discharge nozzle coupled to the air discharge portion of the Coanda nozzle; And
A main heater provided to pass through the interior of the Coanda nozzle or disposed on the air intake side of the Coanda nozzle; Wherein the hair dryer comprises a hair dryer.
The method according to claim 1,
Wherein the Coanda nozzle comprises:
A compressed air inflow part connected to the blowing fan and through which air compressed by the blowing fan flows; A compressed air direction guiding part for spraying compressed air in an inclined direction toward the air discharge part on the side of the air suction part; A curved portion protruding from the inner circumferential surface so as to form a gap with the compressed air direction guiding portion and formed so as to narrow the diameter of the inner flow path; And,
And a gap adjusting handle screwed to the air discharging portion of the Coanda nozzle, the curved portion being coupled to one side and the discharge nozzle being coupled to the other side,
And the size of the gap is adjusted by rotation of the gap adjusting handle.
3. The method of claim 2,
An insertion groove is formed in the air discharge portion of the Koanda nozzle,
A spring is interposed in the insertion groove,
Characterized in that the spring is in close contact between the coanda nozzle and the gap adjustment handle.
The method according to claim 1,
A core is further provided inside the Coanda nozzle so that the inner space of the Coanda nozzle is narrowed,
Wherein the main heater is coupled to an outer peripheral surface of the core.
The method according to claim 1,
Wherein the main heater is provided on an air intake side of the Coanda nozzle,
And an auxiliary heater is further provided between the blower and a compressed air inflow portion into which compressed air flows into the Coanda nozzle.
6. The method of claim 5,
Wherein the main heater has a larger calorific value than the auxiliary heater.
6. The method of claim 5,
Wherein the main heater is formed in a cylindrical shape and is formed with a through hole penetrating through the main heater to allow air to pass therethrough.
8. The method of claim 7,
Wherein a side of the through hole on which the outside air is sucked is formed in an inclined or rounded shape.

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