KR20160004256U - A hairdryer - Google Patents

Abstract

A hair dryer comprising: a primary fluid flow path extending from a primary fluid inlet to a primary fluid outlet; a fan unit for drawing a primary fluid into the primary fluid flow path; and a heater for heating the primary fluid in the primary fluid flow path, A hair dryer is disclosed wherein the primary fluid flowing through the heater has a slower rate than the primary fluid flowing through the fan unit. The heater may be located downstream of the fan unit. The cross-sectional area of the primary fluid flow path may vary along the primary fluid flow path. The cross-sectional area of the primary fluid flow path may be larger around the heater than at the periphery of the fan unit. The hair dryer can include a handle, which has a primary fluid inlet. The hair dryer may include a body, the primary fluid outlet is located within the body, and the primary fluid flow path extends from the primary fluid inlet to the body within the handle.

Description

Hair dryer {A HAIRDRYER}

The present invention relates to portable electrical appliances, and more particularly to hair care electrical appliances such as hair dryers or high temperature styling brushes.

Blowers, and in particular hot air blowers, are used in a variety of applications such as drying of materials such as paint or hair and cleaning or stripping of the surface layer. Hot air blowers, such as high temperature styling brushes, are also used to stylize wet or dry hair.

In general, a motor and a fan are provided to draw fluid into the body, and the fluid may be heated before it exits the body. A motor is traditionally provided with a filter at the fluid inlet end of the blower as it is prone to damage from foreign objects such as dust or hair. Conventionally, such an electric device has a nozzle which is detachably attached to the electric device to change the phase and velocity of fluid flow out of the electric device. These nozzles may be used to focus or diffuse the outlet of the appliance according to the requirements of the user.

According to a first aspect, the present invention provides a hair dryer.

In a preferred embodiment, the hair dryer includes a primary fluid flow path extending from the primary fluid inlet to the primary fluid outlet, a fan unit for drawing primary fluid into the primary fluid flow path, a fan unit for heating the primary fluid in the primary fluid flow path, The primary fluid that includes the heater and flows through the heater has a slower rate than the primary fluid that flows through the fan unit.

Preferably, the heater is downstream of the fan unit.

In a preferred embodiment, the cross-sectional area of the primary fluid flow path is varied along the primary fluid flow path.

Preferably, the cross-sectional area of the primary fluid flow path is larger around the heater than at the periphery of the fan unit.

In a preferred embodiment, the hair dryer includes a handle, within which there is a primary fluid inlet.

Preferably, the hair dryer includes a body having a primary fluid outlet, the primary fluid flow path extending from the primary fluid inlet to the body within the handle.

In a preferred embodiment, the handle is provided with a fan unit.

Preferably, the handle is substantially perpendicular to the body.

In a preferred embodiment, the primary fluid flow path extends in the first direction in the handle and in the second direction in the body.

Preferably, the first direction is substantially perpendicular to the second direction.

In a preferred embodiment, the primary fluid flowing through the primary fluid outlet has a higher velocity than the primary fluid flowing through the heater.

Preferably, the primary fluid entering the primary fluid inlet has a velocity similar to the primary fluid flowing through the heater.

In a preferred embodiment, the velocity of the primary fluid is increased from the primary fluid inlet towards the fan unit.

Preferably, the velocity of the primary fluid is reduced from the fan unit toward the body.

In a preferred embodiment, the hair dryer includes a fluid flow path extending from a fluid inlet into the body to a fluid outlet from the body.

Preferably, the primary fluid flow path in the body surrounds the fluid flow path.

In a preferred embodiment, the body includes an inner duct that separates the fluid flow path from the primary fluid flow path.

Preferably, the heater surrounds the inner duct.

In a preferred embodiment, the heater extends along the inner duct.

The hair dryer preferably includes a high speed motor. The hair dryer includes a fan unit for generating an air flow which includes an air inlet, an air outlet, an impeller, and a motor for rotating the impeller to generate an air flow from the air inlet to the air outlet , Which motor has a rotor that can rotate at a speed of at least 50,000 rpm in use. Preferably, the rotor can be rotated at a speed of at least 80,000 rpm. The rotor is preferably capable of rotating at a speed of up to 110,000 rpm. Preferably, the hair dryer is an amplifying hair dryer, so that the fan unit does not process all the flow rates discharged from the hair dryer, that is, some of the flow rate through the hair dryer is affected by the action of the motor It is entrained by. Preferably, the fan unit is received within the handle of the hair dryer.

The present invention provides a hair dryer including a fan unit including a high voltage motor. Preferably, the pressure generated by the motor is 1400 to 2250 Pa. For a motor installed within a cross-sectional area of 25 mm ² , this is equivalent to a flow rate of 9.4 to 12 l / sec and a motor speed of 84,000 to 105,000 rpm. Thus, the motor is preferably within a grippable handle with a diameter of 35 to 42 mm.

According to the present invention, the thickness of the outer wall is preferably less than 2 mm, more preferably less than 1 mm. Ideally, this thickness is about 0.7 mm.

In another embodiment, the handle diameter is 20 to 60 mm, preferably 30 to 50 mm. Most preferably, the handle diameter is 35 to 42 mm.

According to the present invention, the hair dryer has a handle including a motor, the wall of which is lined with a material. Typically, the lining material has a thickness of 4 to 6 mm.

According to the present invention, the hair dryer includes a handle for receiving the fan unit, which is lined with a lining material. Preferably the lining material comprises at least one of an inlet sound insulation and an outlet sound insulation. The length of the outlet sound insulation material (S _o ) from the downstream end of the fan unit to the downstream end of the handle 20 is preferably at most 100 mm. From the upstream end of the fan unit length of insulating material inlet (S _I) to the downstream side end portion of the inlet is preferably 10-200 mm. The ratio between the inlet sound insulating material (S _I ) and the outlet sound insulating material (S ₀ ) preferably exceeds 1.2. In a hair dryer 10 with a handle 20 of constant diameter, this ratio preferably exceeds 0.1.

According to the present invention, the length Lx from the fluid inlet to the upstream side edge of the handle and the length Lz from the downstream side edge of the handle to the fluid outlet at the downstream end of the body are relevant. Ideally Lz ≤ 40 mm and Lx ≤ 20 mm. Preferably, 2Lx = Lz.

According to the present invention, the hair dryer has an association between the diameter d _a of the outer wall of the body and the diameter d _b of the inner duct. The ratio of d _b: d _a is preferably from 0.49 to 0.6 in a hair dryer having a handle of a constant diameter.

According to the present invention, the ratio of d _b : d _a is preferably 0.4 to 0.9 in a hair dryer with a handle of a diameter that is not constant or varies.

According to the present invention, the hair dryer has a relationship between the length (l ₂ ) of the body and the diameter (d _h ) of the handle. The ratio of l ₂ : d _h is preferably 1.9 to 2.5 in a hair dryer with a handle of a constant diameter. The ratio of l ₂ : d _h is preferably 1.9 to 2.5 in a hair dryer having a handle with a diameter that is not constant or varies.

According to the present invention, the hair dryer has _a relation between the diameter d _a of the outer wall of the main body and the diameter d _h of the handle. The ratio of d _a : d _h is preferably 1.6 to 3.4 in a hair dryer with a handle of a constant diameter.

According to the present invention, the hair dryer has _a relation between the length l ₂ of the main body and the diameter d _{a of the} main body. The ratio of l ₂ : d _a is preferably 1.1 to 1.6 in a hair dryer having a fan unit in the handle within the handle. In the case of a hair dryer in which the heater is in the main body and the fan unit is in the handle, the ratio of l ₂ : d _a is preferably 0.8 to 1.6.

According to the present invention, the hair dryer has a relationship between the length l ₂ of the body and the diameter d _b of the inner duct. and the ratio of l ₂ : d _b is preferably 1.8 to 3.4. In the case of a hair dryer in which the heater is in the main body and the fan unit is in the handle, the ratio of l ₂ : d _a is preferably 1 to 3.4.

According to the present invention, the hair dryer has an inner duct connected to the outer wall through the side wall. In one embodiment, the sidewall is perpendicular to the outer wall.

According to the present invention, the hair dryer includes a handle and a body, wherein the flow in the primary fluid flow path in the body is at 90 [deg.] With respect to the flow in the primary fluid flow path in the handle. Preferably, the primary fluid flow in the body is parallel to the fluid flowing through the fluid flow path.

According to the present invention, the hair dryer includes a body having an inner duct comprising a conical part and a tubular part, wherein the radius between the conical part and the tubular part of the inner duct is 0.5 to 50 mm.

According to the present invention, the hair dryer includes a body having an inner duct comprising a conical part and a tubular part, wherein the conical part at least partially defines a fluid inlet, the tubular part at least partially forming a fluid outlet , The inner duct increases in diameter from the conical part toward the fluid outlet.

According to the present invention, the hair dryer includes a body including an outer wall, an inlet end and an outlet end, wherein the outlet end is provided with a chamfer, wherein the diameter of the outer wall at the chamfer is reduced toward the center of the outer wall AA And the chamfered portion has an angle of 30 to 60 degrees. Ideally, the chamfer has an angle of between 30 and 60 degrees. Preferably, a forward chamfer portion of 35 to 55 degrees, more preferably a forward chamfer portion of 45 degrees is provided.

According to the present invention, a hair dryer has a body, the body including a primary fluid outlet formed by a first surface and a second surface of the body, the first surface and the second surface defining a respective exterior Is a substantially parallel surface that forms an annular limit and an inner annular limit. Preferably, the body includes an inner duct, wherein the first surface and the second surface are also substantially parallel to the inner duct.

According to the present invention, a hair dryer has a body, the body including a primary fluid outlet formed by a first surface and a second surface of the body, the first surface and the second surface defining a respective exterior Are substantially parallel surfaces that form annular limits and internal annular limits. Preferably, the body includes an inner duct, wherein the first surface and the second surface are also inclined toward the inner duct adjacent the primary fluid outlet.

According to the present invention, a hair dryer has a body, the body including a primary fluid outlet formed by a first surface and a second surface of the body, the first surface and the second surface defining a respective exterior Are substantially parallel surfaces that form annular limits and internal annular limits. Preferably, the body includes an inner duct, wherein the first surface and the second surface are also inclined toward a direction away from the inner duct adjacent the primary fluid outlet.

According to the present invention, a hair dryer includes a body having a tubular outer wall and a handle substantially orthogonal to the body, the handle having a fluid inlet at least partially defined by a sidewall extending from the tubular outer wall toward the center of the tubular outer wall, Wherein the sidewall has an angle of 1 to 90 relative to the tubular outer wall. Preferably, this angle is between 30 and 60 degrees. More preferably, this angle is 45 degrees.

Hereinafter, the present invention will be described by way of example with reference to the accompanying drawings.

1 shows a perspective view of a hair dryer according to the present invention;
Figure 2 shows a cross-sectional view of the hair dryer of Figure 1;
Figure 3a shows a side view of the inner wall of the hair dryer;
Figure 3b shows a cross-sectional view of the inner duct of the hair dryer;
Figure 4 shows a side view of the hair dryer;
Figure 5 shows a rear end view of the hair dryer;
Figure 6 shows another side view of the hair dryer;
Figure 7 shows a front end view of the hair dryer;
Figure 8 shows a bottom view of the hair dryer;
Figure 9 shows a front end view of the hair dryer;
10 shows a graph of the length of the sound insulation material in the handle of the hair dryer;
11a-11d show an end view of an alternative hair dryer according to the present invention;
12 shows a side view of the hair dryer according to the present invention;
13A and 13B show a side view of a hair dryer according to the present invention;
Figures 14A and 14B show end views of some other hair dryers according to the present invention;
Figures 15A, 15B and 15C show side views of some of the hair dryers according to the present invention;
Figures 16A, 16B, 16D and 16E show side views of an alternative hair dryer according to the present invention;
Figures 16c and 16f show end views corresponding to the alternative hair dryers of Figures 16a, 16b, 16d and 16e;
17A shows a side sectional view of a hair dryer according to the present invention;
18A-18D show side cross-sectional views of another hair dryer according to the present invention;
19A and 19B show an alternative front chamfer for a hair dryer according to the present invention;
20A-20C illustrate alternative outlet configurations for a hair dryer in accordance with the present invention;
21 shows a side cross-sectional view of the hair dryer in use;
Figure 22A shows a graph of the velocity profile through the hair dryer according to the present invention;
Figure 22b schematically illustrates the cross-sectional area of the primary fluid flow path.

Figures 1 and 2 illustrate a hair dryer 10 having a handle 20 and a body 30. The handle has a first end 22 that is connected to the body 30 and a second end 24 that is circular from the body 30 and that includes a primary fluid inlet 40. The electric power is supplied to the hair dryer 10 through the cable 50.

The body 30 has a first end 32 and a second end 34 and extends from the first end 32 and extends from the generally tubular first part 36 and the second end 34 It can be considered to have two parts of the second part 38 that are joined to the first part 36. The second part 38 is conical in shape and has a diameter varying along its length from a diameter of the first part 36 of the body 30 to a smaller diameter at the second end 34 of the body. In this embodiment, the second part 38 has a constant gradient, and the angle? Of the first part 36 of the body 30 with respect to the outer wall 360 is about 40 degrees.

The handle 20 has an outer wall 200 extending from the main body 30 to the distal end of the handle 20. [ At the distal end (24) of the handle, the end wall (210) extends across the outer wall (200). The cable 50 enters the hair dryer through the end wall 210. The primary fluid inlet 40 of the handle 20 has a first opening extending around the outer wall 200 along the outer wall 200 of the handle and a second opening extending through the end wall 210 of the handle 20, And a second opening extending over the entire surface. The cable 50 extends from the center of the handle 20 because it is located approximately at the center of the end wall 210. The end wall 210 is perpendicular to the outer wall 200 and the inner wall 220 of the handle.

A fan unit (70) is provided upstream of the primary fluid inlet (40). The fan unit 70 includes a fan and a motor. The fan unit 70 draws fluid from the primary fluid inlet 40 through the primary fluid flow path 400 toward the body 30 and the fluid flow path 400 from the primary fluid inlet 40 to the handle 20 And the main body 30 extend into the joint portion 90. The fluid fluid flow path 400 continues through the body 30 to the second end 34 of the body until it reaches the periphery of the heater 80 and the primary fluid outlet 440, Fluid is discharged from the primary fluid flow path 400 at the primary fluid outlet 440. The primary fluid flow path 400 is nonlinear and extends in a first direction through the handgrip 20 and in a second direction perpendicular to the first direction through the body 30.

The body 30 includes an outer wall 360 and an inner duct 310. The primary fluid flow path 400 extends from the abutment 90 of the handle 20 and the body 30 through the gap between the outer wall 360 and the duct 310 to the primary fluid outlet ≪ RTI ID = 0.0 > 440 < / RTI >

Another fluid flow path is provided in the body, which is not directly handled by the fan unit or heater, but is drawn into the hair dryer by the action of a fan unit that generates a primary flow through the hair dryer. This fluid flow is conducted into the hair dryer by the fluid flowing through the primary fluid flow path 400.

The first end 32 of the body includes a fluid inlet 320 and the second end 34 of the body includes a fluid outlet 340. Both the fluid inlet 320 and the fluid outlet 340 are at least partially formed by a duct 310 which is the inner wall of the body 30 extending along the body in the body. Fluid flow path 300 extends from fluid inlet 320 to fluid outlet 340 in the duct. At the first end 32 of the body 30 a sidewall 350 extends between the outer wall 360 and the duct 310. The sidewall 350 at least partially defines a fluid inlet 320. At the second end 34 of the body, a gap is provided between the outer wall 360 and the duct, which defines the primary fluid outlet 440. The primary fluid outlet 440 is annular and surrounds the fluid flow path. The primary fluid outlet 440 may be positioned inwardly such that the primary fluid flow path 400 merges with the fluid flow path 300 within the body 30. Alternatively, the primary fluid outlet 440 is located outside and performs discharge from the body 30 separately from the fluid from the fluid flow path 300 at the fluid outlet 340.

The outer wall 360 of the main body is converged toward the center line A-A of the duct 310 and the main body 30. [ There is an advantage that the primary fluid discharged from the primary fluid outlet 440 is directed toward the center line A-A of the main body 30 when the outer wall 360 converging toward the duct 310 is present. The fluid exiting the primary fluid outlet 440 is caused by the movement of the fluid from the primary outlet 440 to some extent inducing fluid externally from the exterior of the hair dryer. This effect is enhanced by the outer wall 360 converging towards the duct 310. This is partly due to the inclination of the outer wall 360 of the body 30 towards the second end 34 of the hair dryer, partly because the primary flow is focused and not scattered.

The duct 310 is an inner wall of a hair dryer that can be accessed from the outside of the hair dryer. Thus, the duct 310 is the outer wall of the hair dryer. Since the duct 310 is embedded in the main body 30, the side wall 350 connecting between the outer wall 360 and the duct 310 is inclined with respect to the outer wall 360.

A PCB 75 containing a control electronics for the hair dryer is located in the body 30 in the vicinity of the sidewall 350 and the fluid inlet 320. The PCB 75 is ring shaped and extends between the duct 310 and the outer wall 360 around the duct 310. The PCB 75 is in fluid communication with the primary fluid flow path 400. The PCB 75 extends around the fluid flow path 300 and is isolated from the fluid flow path 300 by the duct 310.

The PCB 75 controls parameters such as the temperature of the heater 80 and the rotational speed of the fan unit 70. The internal wiring (not shown) electrically connects the PCB 75 to the heater 80, the fan unit 70, and the cable 50. Control buttons 62 and 64 are provided to the PCB 75 so that the user can select, for example, various temperature settings and flow rates.

In use, the fluid is drawn into the primary fluid flow path 400 by the action of the fan unit 70, selectively heated by the heater 80, and discharged from the primary fluid outlet 440. This processed flow causes the fluid to flow into the fluid flow path 300 at the fluid inlet 320. This fluid is integrated with the flow processed at the second end 34 of the body. In the embodiment shown in Figure 2, the treated flow is an annular flow that flows out of the primary fluid outlet 440 and the hair dryer, and the annular flow surrounds the entrained flow out of the hair dryer through the fluid outlet 340 . Thus, the fluid processed by the fan unit and the heater is augmented by the entrained flow.

The handle 20 has an inner wall 250 and an outer wall 200 that at least partially define a primary fluid flow path 400 through which the handle 20 is passed. The inner wall 250 extends from the body 30 toward the downstream end 254 toward the second end 24 of the handle 20. [ The handle 20 is tubular and the outer wall 200 of the handle 20 is a cylindrical sleeve made of any suitable material such as molded plastic or rolled metal (e.g., aluminum, aluminum alloy or steel) plates. The handle is connected to the body 30 at a first end 22 and the distal second end 24 is provided with a primary fluid inlet 40. The primary fluid inlet 40 is the first means for filtering the fluid entering the primary fluid flow path 400.

Referring now to FIG. 3, a lining material 270 is positioned between the inner wall 250 and the outer wall 200. This lining material 270 is a foam or felt which at least attenuates the noise generated when the fluid is sucked into the handle 20 by the fan unit 70 (it has a soundproofing effect). For clarity, the lining material 270 is shown only around a portion of the inner wall 250. In order to enable contact between the lining material 270 and the fluid flowing in the primary fluid flow path 400 and thus the attenuation of the noise, the inner wall 250 is provided with an inner wall 250 around this inner wall 250, A perforation 256 extending along the length of the inner wall 250 is provided.

The lining material 270 is provided to reduce the noise generated when the fluid is drawn into the primary fluid inlet 40 by the action of the fan unit 70.

The perforations 256 of the inner wall 220 have diameters that are selected to most effectively attenuate noise. A diameter of 1 mm to 10 mm is appropriate, a smaller diameter is better to obtain a good acoustic output (which reduces the sound over the human main acoustic range), and a larger diameter is good for high frequency attenuation. Preferably, the perforations form at least 40% of the surface area of the inner walls 220,250.

By placing the lining material 270 behind the inner wall 250, it becomes possible to use a thicker lining material than when the lining material 270 is directly exposed to the primary fluid flow path 400. This is because the diameter of the primary fluid flow path 400 is determined by the inner wall 250 that presses the lining material 270 into the gap between the inner wall 250 and the outer wall 200 of the handle 20. [ Typically, the lining material has a thickness of 4 to 6 mm, but is compressed between the outer wall 200 and the inner wall 250.

An important feature of the multi-layered handle 20 is that it can be used to improve the relaxation of the noise generated by the product. The air flow noise generated by the fan unit 70 and the fluid entering the primary fluid flow path 400 is attenuated by the lining material 270 but some noise is transmitted through the lining material 270.

A further feature required of the handle 20 is that it must be sufficiently rigid to provide a grippable handle that does not readily form a bend introducing restriction into the primary fluid flow path. Thus, materials such as aluminum or carbon fiber reinforced composites that provide lightweight rigid tubes are ideal. Alternatively, the outer wall is made of a plastic material. Those skilled in the art will recognize that there are other materials that provide similar advantages.

To ensure that the diameter of the handle 20 is not excessively large for the user, the thickness of the outer wall 200 is preferably less than 2 mm, more preferably less than 1 mm. Ideally, this thickness is about 0.7 mm. Also, the relatively thin outer wall 200 of the handle 20 reduces the weight of the product.

When using high-speed motors, the generated noise is high frequency, and some of them can stimulate the human auditory sense. However, this is advantageous because it can attenuate higher frequencies more effectively.

Ideally, the diameter of the handle is 20 to 60 mm, preferably 30 to 50 mm. Most preferably, the handle diameter is 35 to 42 mm. To maximize noise mitigation and provide a grip that can be gripped, the present inventors have used a combination of materials within the grip 20. First of all, the outer layer 200 is rigid but also thin, so that acoustic damping in the knob 20 by the lining material 270 is maximized by maximizing the thickness of the lining material 270 in the knob 20 . In order to attenuate high frequency noise (typically about 1.8 to 2 Khz) produced by a high-speed motor, ideally a lining material 270 or soundproofing medium of 6 mm or more is required.

7, the length of the lining material 270 is also important. It is ideal for the lining material 270 to be installed both upstream and downstream of the motor 70 because the motor generates noise when the fluid enters the motor and when the fluid is discharged from the motor.

10, there is shown a graph of the noise produced by the high-speed motor in the handle 20 relative to the distance of the fan unit 70 from the inlet 40. Generally, the longer the length of the soundproofing lining material is, the more the sound is attenuated, but the length and practicality of the product are limited. Thus, in the case of a hair dryer having a motor in the handle 20, there is an optimum position of the motor within the length of the handle in terms of noise. As can be seen in the graph, as the motor is moved in a direction away from the inlet along the x-axis, the noise of the inlet 280 is reduced, so that the longer the inlet sound insulation is, the more noise is attenuated. However, for a given length of the handle (l _h), the length of the inlet sound-proofing material (S _I) The long path length of the outlet sound-proofing material (S _O) is to be shortened.

For the insulating material outlet (S _O), when the motor is located at the inlet (x- axis value of 0), the outlet noise level 282 of the insulating material outlet (S _O) is minimized for a given length of the handle (l _h), As the motor moves along the handle, the length of the outlet sound insulation material (S _o ) decreases and the sound level rises, thereby reducing the noise attenuation. There is therefore an optimum distance from the inlet for the motor. In an amplifying hair dryer in which a primary fluid flow path 400 extends from the handle 20 into the body 30, the primary fluid flow path 400 extends from the circular cross section 400a in the handle to the annular or toroidal cross section 400b in the body. Shape and size are changed. For this reason, some of the noise generated by the fluid discharged from the motor is attenuated by the fluid flowing into the main body 30, so that the inlet sound insulation and the outlet sound insulation in the handle are not the same in terms of sound.

The combined noise output 284 from both the inlet sound insulation material (S _I ) and the outlet sound insulation material (S _O ) is the value of the compressor on the graph, which means that the motor moves in the direction away from the inlet to the sweet point , And at this sweet point, the noise level of the inlet sound insulation material (S _I ) and the noise level of the outlet sound insulation material (S _O ) are crossed and then rise again.

The total noise output 288 of the hair dryer is the sum of the noise value 286 and the compressor value 284, which is the noise generated in the body 30 of the hair dryer. This value is determined by the position of the motor in the handle 20 It is not affected. For this particular hair dryer 10, the optimal inlet sound insulating material S _I is 70 to 100 mm. However, if any of the characteristics of the motor speed, the diameter of the handle, or the inlet are changed, this value will change, for example.

The length of the outlet sound insulation material S _o from the downstream side end portion 70b of the fan unit 70 to the downstream side end portion 22 of the handle 20 is preferably at most 100 mm. The length of the inlet sound insulating material S _I from the upstream end 70a of the fan unit to the downstream end 40b of the inlet 40 is preferably 10-200 mm. The ratio between the inlet sound insulating material (S _I ) and the outlet sound insulating material (S ₀ ) preferably exceeds 1.2. In a hair dryer 10 with a handle 20 of constant diameter, this ratio preferably exceeds 0.1.

5 and 11A to 11D, the hair dryer 10 has _a relationship between the diameter d _a of the outer wall 360 of the main body 30 and the diameter d _b of the inner duct 310 . As shown in Figs. 11C to 11D, it is preferable that the ratio of d _b: d _a is 0.49 to 0.6 in the hair dryer 10 having the handle 20 of a constant diameter. As shown in Figs. 11A and 11B, it is preferable that the ratio of d _b : d _a is 0.4 to 0.9 in the hair dryer 130 having the handle 132 of a diameter that is not constant or varies.

12, the length Lx from the fluid inlet 320 to the upstream side edge 202 of the handle 20 and the length Lx from the downstream side edge 204 of the handle 20 to the downstream side of the body 30 And the length Lz to the fluid outlet 340 of the side end portion. Ideally Lz ≤ 40 mm and Lx ≤ 20 mm. Preferably, 2Lx = Lz.

13A and 13B, the hair dryers 132 and 134 have a relationship between the length l ₂ of the main body 30 and the diameter d _h of the handle 20. The ratio of l ₂ : d _h is preferably in the range of 1.9 to 2.5 in the hair dryer 10 having the handle 20 of a constant diameter. As shown in Figure 13c and 13d, l _2: d _h of the non-uniform or are preferably in the 1.9 to 2.5 from the hair dryer 160 and 162 with the handle 164 of the change that diameter.

14A and 14B, the hair dryers 136 and 138 have a relationship between the diameter d _a of the outer wall 360 of the main body 30 and the diameter d _h of the handle 20. The ratio of d _a : d _h is preferably 1.6 to 3.4 in the hair dryer 10 having the handle 20 of a constant diameter.

Referring to FIGS. 15A to 15C, the hair dryers 140 and 142 have a relation between the length l ₂ of the main body 30 and the diameter d _a of the main body 30. The ratio of l ₂ : d _a is preferably 1.1 to 1.6 in the hair dryer 10 with the fan unit 70 in the handle 20. As shown in Figure 15c, the heater 80 is the case of the main body 30 in, and the fan unit 70, a hairdryer 144 that is within the handle (20), l _2: the ratio of d _a is 0.8 To 1.6.

16A to 16C, the hair dryers 146 and 148 are related to each other between the length l ₂ of the main body 30 and the diameter d _b of the inner duct 310. and the ratio of l ₂ : d _b is preferably 1.8 to 3.4. A d _a: no less the case of 16d to Referring to Figure 16f, the heater 80 is within the body 30, the fan unit 70, the hair dryer (150, 152) in the handle (20), l ₂ The ratio is preferably 1 to 3.4.

Another feature of the present invention is that the flow in the primary fluid flow path 400b in the body 30 forms 90 [deg.] With the flow in the primary fluid flow path 400a in the handle 20. [ The primary fluid flow in the body 30 is parallel to the fluid flowing through the fluid flow path 300.

2, 3B and 9, the inner duct 310 includes a generally tubular part 312 extending from the fluid outlet 340 toward the fluid inlet 320, and a generally tubular part 312, And a generally conical part 314 defining a side wall 350 connecting the outer wall 360 of the body 30.

The sidewall 352 may be perpendicular to the outer wall 360 as shown in Fig. 17A. In practice, the separate sidewalls 350 and 352 may be omitted, and the inner duct 354 may be a cylinder having a diameter that progressively decreases toward the fluid outlet 340 in the form of a truncated cone from the fluid inlet 320 Can be extended.

18A, the inner duct 354a is curved from the outer wall 360 at the first end 32 toward the tube forming the circular duct at the second end 36. As shown in Fig. The shape formed by the inner duct 354a is a trumpet shape. 18B shows an inner duct 354b similar to that of FIG. 18A, but the conical portion 358 of the inner duct 354b is shorter to provide a more urgent slope toward the fluid inlet 320. FIG.

The progressively curved inner duct has the advantage that the noise is reduced since less turbulence is generated when the fluid enters the fluid flow path at the fluid inlet 320. The use of curved sidewalls is acoustically advantageous because the flow introduced into the fluid flow path 300 does not encounter sharp edges, does not introduce vortexes, and does not increase the generation of noise. This side wall is incorporated into the tubular part of the inner duct 310.

Figure 18c shows the combination of the inner duct 354a and the bellows 354c of Figure 18a. The inner duct extends 362 from the first end 32 to the transition point 364 and the cylinder having a diameter that gradually decreases in transition is varied to slightly increase in diameter toward the second end 34 . This pulling of the fluid into the fluid inlet 320 due to this flaring of the inner duct is increased.

Fig. 18d shows the combination of the conical portion 358 of Fig. 18b and the retractable inner duct 354d. If the inner duct 354d of the shorter conical region is used, the length of the widening portion can be longer.

In practice, any angle between 1 and 90 degrees may be selected for the angle [beta] between the outer wall 360 and the inner ducts 350, 354a, 354b, 354c and 354d.

18c and 18, the radius r between the conical part 358, 362 and the tubular part 312 of the inner duct 354d, 354c can be varied. The radius is preferably 0.5 to 50 mm.

Alternatively, the inner duct 310 can be increased in diameter from the side wall 366 toward the fluid outlet 340, as shown in Figs. 17B and 17C. This is advantageous because it increases the flow rate passed through the fluid flow path 300. Thus, the total discharge of fluid from the fluid outlet 340 and the primary fluid outlet 440 may be increased, or the fan unit 70 may be operated at a slower rate to produce an equivalent total output, Can be reduced. The increase in the diameter of the inner duct 310 is more pronounced in Fig. 17C, which causes more pulling through the inner duct 310.

7, the length of the lining material in the handle 20 can be varied. The length of the inlet lining S _I from the downstream end 40b of the inlet 40 to the upstream end 70a of the fan unit 70 is preferably between 10 and 200 mm.

The front portion 38 (Figure 2) of the hair dryer may have various chamfered portions 372, 374, 376 as shown in Figures 1, 2, 6, 19a and 19b, The chamfered portions 372, 374 and 376 are formed by changing the diameter of the outer wall 360 of the main body 30. This diameter is reduced toward the center A-A of the outer wall 360. This front chamfered portion 372, 374, 376 affects the external impingement 490 from the outside of the hair dryer due to the movement of the fluid from the primary outlet 440. The blunt front surface of the body 30 limits both the flow rate of the externally provided 490 and the flow rate through the fluid flow path 300. Ideally, a front chamfer is selected between 30 [deg.] As shown in Figure 19a and 60 [deg.] As shown in Figure 19b. Preferably, a forward chamfer portion of 35 to 55 degrees and more preferably a forward chamfer portion of 45 degrees are provided to provide a reasonable amount of external engagement 490. [

The direction of flow exiting the primary fluid outlet is variable depending on the desired result. Figures 20a, 20b and 20c illustrate different air outlets for the primary fluid. Referring first to Figure 20A, the primary fluid outlet 440 includes a substantially parallel first surface 442 and a second surface 444, respectively, forming an outer annular limit and an inner annular limit for the primary fluid outlet 440, respectively. ). The substantially parallel first surface 442 and second surface 444 are also substantially parallel to the inner duct 310. This configuration provides a balance between the externally conducted flow 490 and the fluid 492 carried internally, i.e., the fluid being drawn into the fluid flow path 300.

In FIG. 20B, the primary fluid outlet 440a faces the center of the outer wall 360 of the body 30. In this embodiment, both the first surface 446 and the second surface 448 forming the primary fluid outlet 440a are substantially parallel to each other, but are inclined relative to the inner duct 310. The primary fluid outlet 440a faces the center of the outer body 360 and the inner duct 310. Fluid 494, which is discharged from primary fluid outlet 440a, is directed to fluid that is discharged from fluid outlet 340, such as externally conducted fluid 490. This results in a more concentrated output from the hair dryer as the fluid is directed into the fluid flowing through the interior duct 310 and flows through it, thus allowing the fluid jet ejected from the hair dryer to flow into the smaller cross- I feel stronger because I concentrate. This configuration provides a relatively more externally entrained flow rate 490 and a lesser internal flow in the interior duct 310 than the non-aerosol embodiment described with reference to Figure 20A.

20C, the primary fluid outlet 440b faces away from the center of the outer wall 360 of the main body 30. [ In this embodiment, both the first surface 450 and the second surface 452 forming the primary fluid outlet 440a are substantially parallel to each other, but are inclined in a direction away from the inner duct 310. The primary fluid outlet 440b faces the outer wall 360. The fluid 496 exiting the primary fluid outlet 440b is directed away from the fluid leaving the fluid outlet 340 and toward the externally conducted fluid 490. This provides a more diffused output from the hair dryer, since the fluid is all directed outward, and thus the hair dryer feels less powerful, as the fluid jet emitted from the hair dryer is dispersed into a larger cross-sectional area. This configuration provides a relatively less externally entrained flow rate 490 as compared to the non-aerosol embodiment described with reference to Figure 20A and a flow rate traversed internally along more internal ducts 310. [

Figure 21 shows the easy accessibility and ergonomic advantages (see Figure 2) of the control button of the hair dryer 10, which places the control button 64 on the inclined surface of the body of the hair dryer. When the hair dryer is normally gripped by the hand 500, the thumb is conventionally positioned with the index finger 502 around the handle to form a complete circle or partial circle. In the present hair dryer 10, the thumb 504 can be grasped in a conventional manner and can also be grasped by a control button 64 located on the side wall 350 forming part of the fluid inlet 320 at the rear of the product A thumb can be used to change settings such as flow rate and / or temperature through the hair dryer. Thus, the user can change the setting of the hair dryer 10 by moving the thumb radially from the handle 20 to the side wall 350 without adjusting the gripping state. The side wall 350 is preferably inclined relative to the outer wall 360 of the body 390. This angle? Is ideally 1 to 90 degrees, preferably 30 to 60 degrees. An angle [gamma] of 45 [deg.] Is most preferable.

Figure 22 shows a graph of the velocity profile through the hair dryer 10. At the fluid inlet 40, the fluid entering the fluid inlet 40 is at a relatively low speed 402 and as the fluid flows through the inlet sound insulation material, the cross-sectional area within the handle 20 is reduced to increase the velocity 404 . Further, as the fluid enters the fan unit, the speed 406 is again increased due to the additional limitation of the fluid flow path 400 passing through the impeller and motor of the fan unit 70 upstream of the fan unit 70 And the velocity 408 through the outlet sound insulation decreases as the restriction of the fluid flow path is relaxed again. Reaches a minimum velocity 410 when fluid enters the body 30 of the hair dryer 10 from the handle 20. [ This is because the body 30 has a larger cross-sectional area than the handle and acts as a fluid-filled plenum that reduces the flow rate of the fluid. The velocity 410 in the body is similar to the velocity at the inlet 402. When the fluid passes through the heater 80, the velocity 412 slightly increases because the heater element has less restriction on fluid flow. As the fluid approaches the primary fluid outlet 440, the cross-sectional area within the body 30 is reduced to an annular ring that forms the primary fluid outlet 440 and the velocity within the body is reduced to the maximum velocity at the primary fluid outlet 440 (414).

The reduction in speed as fluid is transferred from the fan unit 70 to the heater 80 has many advantages. The body 30 acts as a plenum that stabilizes the flow as it moves from the circular flow 400a in the handle 20 to the annular flow 400b in the body 30 and this reduces the flow rate of the fluid Permits more uniform flow through the heater 80, reduces speed and turbulence; The noise produced by the hair dryer is reduced; A more uniform flow rate is provided around the annular ring forming the primary fluid outlet 440.

The main reason that the speed is reduced from fan unit speed 406 to heater speed 412 is that the cross sectional area of the fluid flow path increases from the cross sectional area A ₁ of the circular flow 400a in the handle to the annular Sectional area A ₂ of the flow 400b, which is schematically shown in Fig. 22B as A ₂ > A ₁ .

Although the outer wall 200 of the handle 20 has been described as being made of a rolled metal sheet, other manufacturing methods and materials may be used, including but not limited to extrusion tubes, plastic extrusion / cast tubes, But is not limited thereto.

Although the present invention has been described in detail with respect to a hair dryer, it can also be applied to any electric apparatus that guides the discharge of the fluid from the electric apparatus by sucking the fluid.

The electric appliance can be used with or without a heater, and the discharge action of high speed fluid has a drying effect.

The fluid flowing through the electrical device is generally air, but it can be a different combination of gases or a gas, and in relation to one purpose, for example, directing the effluent to the hair and styling the hair And an additive for improving the performance of the electric device or the influence of the electric device on the electric device.

The present invention is not limited to the above detailed description. Modifications will be apparent to those skilled in the art.

Claims (43)

As a hair dryer,
A primary fluid flow path extending from the primary fluid inlet to the primary fluid outlet, a fan unit for drawing primary fluid into the primary fluid flow path, and a heater for heating the primary fluid in the primary fluid flow path, Wherein the primary fluid flowing through the fan unit has a velocity that is slower than the primary fluid flowing through the fan unit,
Hair dryer. The method according to claim 1,
Wherein the heater is located downstream of the fan unit,
Hair dryer. 3. The method according to claim 1 or 2,
Wherein the cross-sectional area of the primary fluid flow path is varied along the primary fluid flow path,
Hair dryer. The method of claim 3,
Wherein the cross-sectional area of the primary fluid flow path is larger around the heater than at the periphery of the fan unit,
Hair dryer. 5. The method according to any one of claims 1 to 4,
Wherein the primary fluid inlet is located within the handle,
Hair dryer. 6. The method of claim 5,
Wherein the primary fluid outlet is located within the body and the primary fluid flow path extends from the primary fluid inlet to the body within the handle,
Hair dryer. The method according to claim 5 or 6,
Wherein the fan unit is located within the handle,
Hair dryer. 8. The method according to any one of claims 5 to 7,
Said handle being substantially perpendicular to said body,
Hair dryer. 9. The method of claim 8,
Said primary fluid flow path extending in a first direction within said handle and in a second direction within said body,
Hair dryer. 10. The method of claim 9,
Wherein the first direction is substantially perpendicular to the second direction,
Hair dryer. 11. The method according to any one of claims 1 to 10,
Wherein the primary fluid flowing through the primary fluid outlet has a higher velocity than the primary fluid flowing through the heater,
Hair dryer. 12. The method according to any one of claims 6 to 11,
Wherein the primary fluid entering the primary fluid inlet has a velocity similar to the primary fluid flowing through the heater,
Hair dryer. 13. The method of claim 12,
Wherein the velocity of the primary fluid is increased from the primary fluid inlet towards the fan unit,
Hair dryer. The method according to claim 12 or 13,
Wherein the velocity of the primary fluid is reduced from the fan unit toward the body,
Hair dryer. 15. The method according to any one of claims 1 to 14,
And a fluid flow path extending from a fluid inlet into the body to a fluid outlet from the body.
Hair dryer. 16. The method of claim 15,
Wherein the primary fluid flow path within the body surrounds the fluid flow path,
Hair dryer. 17. The method according to claim 15 or 16,
Wherein the body includes an inner duct separating the primary fluid flow path and the fluid flow path.
Hair dryer. 18. The method of claim 17,
Wherein the heater surrounds the inner duct,
Hair dryer. The method according to claim 17 or 18,
Wherein the heater extends along the inner duct,
Hair dryer. 20. The method according to any one of claims 1 to 19,
Wherein the fan unit comprises a high speed motor,
Hair dryer. 21. The method according to any one of claims 1 to 20,
And a handle for receiving the fan unit, the handle being lined with a lining material,
Hair dryer. 22. The method of claim 21,
The lining material has a thickness of 4 to 6 mm,
Hair dryer. 23. The method of claim 22,
Wherein the lining material comprises at least one of an inlet sound insulation material and an outlet sound insulation material.
Hair dryer. 24. The method of claim 23,
The outlet sound insulation material (S ₀ ) has a length of at most 100 mm,
Hair dryer. 24. The method of claim 23 or 24,
The inlet sound insulation material (S _I ) has a length of 10-200 mm,
Hair dryer. 17. The method of claim 16 dependent on claim 6,
The length Lz from the fluid inlet to the upstream side edge of the handle and the length Lz from the downstream side edge of the handle to the fluid outlet of the downstream end of the body have a relationship of 2Lx = ,
Hair dryer. 18. The method of claim 17, dependent on claim 6,
The diameter of the outer wall of the main body in the hair dryer with a handle of constant diameter (d _a) and the ratio of the diameter (d _b) of the inner duct is 0.49 to 0.6,
Hair dryer. 28. The method of claim 27,
The ratio of d _b : d _a in a hair dryer with a handle of a diameter that is not constant or varied is 0.4 to 0.9,
Hair dryer. 18. The method of claim 17, dependent on claim 6,
Wherein the ratio between the length ( ₁₂ ) of the body and the diameter (d _h ) of the handle in a hair dryer having a constant diameter handle is 1.9 to 2.5,
Hair dryer. 30. The method of claim 29,
The ratio of l ₂ : d _h in hair dryers with non-uniform or varying diameter handles is preferably between 1.9 and 2.5,
Hair dryer. 18. The method of claim 17, dependent on claim 6,
Wherein the body has an outer wall and the ratio between the diameter d _a of the outer wall of the body and the diameter d _h of the handle is 1.6 to 3.4 in a hair dryer having a handle with a constant diameter,
Hair dryer. The method according to claim 6,
Wherein _a ratio between _a length ( ₁₂ ) of the main body and a diameter (d _a ) of the main body in the hair dryer having the fan unit in the handle is 1.1 to 1.6,
Hair dryer. 33. The method of claim 32,
Wherein _a ratio of l ₂ : d _a in a hair dryer having a heater in the main body is 0.8 to 1.6,
Hair dryer. The method according to claim 6,
Wherein _a ratio between _a length ( ₁₂ ) of the main body and a diameter (d _a ) of the main body in the hair dryer having the fan unit in the handle is 1.1 to 1.6,
Hair dryer. 35. The method of claim 34,
In the hair dryer having the heater in the main body, the ratio of l ₂ : d _a is preferably 0.8 to 1.6,
Hair dryer. 18. The method of claim 17, dependent on claim 6,
Wherein the ratio of the length (l ₂ ) of the main body to the diameter (d _b ) of the inner duct is 1.8 to 3.4,
Hair dryer. 37. The method of claim 36,
The ratio of l ₂ : d _a in a hair dryer having a heater in the main body is preferably 1 to 3.4,
Hair dryer. 18. The method of claim 17,
Wherein the inner duct includes a conical part and a tubular part, the conical part at least partially defining a fluid inlet, the tubular part at least partially defining the fluid outlet, Wherein the diameter increases toward the outlet,
Hair dryer. The method according to claim 6,
Wherein the body has an outer wall, an inlet end and an outlet end, wherein the outlet end is provided with a chamfer, wherein the diameter of the outer wall at the chamfer is reduced toward the center of the outer wall AA, RTI ID = 0.0 > 60 < / RTI >
Hair dryer. The method according to claim 6,
Wherein the body includes a primary fluid outlet formed by a first surface and a second surface of the body, the first surface and the second surface having respective external annular limits for the primary fluid outlet, Which is a substantially parallel surface forming a boundary,
Hair dryer. 41. The method of claim 40,
Wherein the body includes an inner duct and the first surface and the second surface are also substantially parallel to the inner duct,
Hair dryer. 41. The method of claim 40,
Wherein the body includes an inner duct and the first surface and the second surface are also inclined toward the inner duct adjacent the primary fluid outlet,
Hair dryer. 41. The method of claim 40,
Wherein the body includes an inner duct and wherein the first surface and the second surface are also inclined in a direction away from the inner duct adjacent the primary fluid outlet,
Hair dryer.

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