KR101229109B1 - Hair dryer - Google Patents

Abstract

The present invention relates to a hair dryer. The hair dryer of the present invention is provided with a motor 20 and a fan 22 for forming an air flow in the housing 10, and is selective to air introduced from the outside of the housing 10 by the fan 22. It is provided with a heating element 28 to provide heat. A discharge nozzle 30 is installed at one end of the housing 10, and the discharge nozzle 30 is provided with a coplanar face 35 'so that the air passing through the housing 10 is coplanar face 35'. While flowing along the air, the air outside the discharge nozzle 30 is sucked into the central flow path part 37 of the discharge nozzle 30 to be mixed with the air passing through the housing 10. The air mixed in the central flow passage part 37 is discharged through the discharge port 38 ′ of the discharge nozzle 30. In the present invention as described above, the air passing through the coplanar surface 35 ′ can suck the air outside the discharge nozzle 30, so that the capacity of the motor 20 can be relatively reduced. In addition, due to the structure of the discharge nozzle 30, moisture is prevented from entering the interior of the housing 10 from the outside through the discharge nozzle 30, so that the waterproof and noise blocking effect is relatively great, and the electromagnetic shielding effect is also very high. There is an advantage to be large.

Description

Hair dryer {Hair dryer}

The present invention relates to a hair dryer, and more particularly, to a hair dryer to form an air flow using the coanda effect.

A general hair dryer dries or tidys a user's hair as air flow generated by a fan driven by a motor is discharged to the outside. The temperature of the air discharged from the hair dryer varies depending on need, and a heating element is provided therein for discharging air of a relatively high temperature.

However, in the conventional hair dryer, the amount of air discharged through the discharge port is determined according to the capacity of the motor and the fan. Therefore, in order to provide a desired flow rate, since the motor and the fan must have a certain capacity or more, there is a problem that the size of the hair dryer is relatively large.

The fan is rotated by the driving of the motor, and the air sucked from the outside by the rotation of the fan passes through the heating element and is discharged to the outside of the hair dryer. The heating element is adjacent to a portion where air is discharged from the hair dryer. It is.

Therefore, the electromagnetic wave generated in the heating element can be directly transmitted to the user's head, there is a problem that adversely affects the user's health.

In addition, since the heating element is adjacent to the discharge port, when water enters from the outside through the discharge port, the heating element is easily transferred to the heating element, thereby causing a large risk of electric shock or the like.

Accordingly, an object of the present invention is to solve the conventional problems as described above, to increase the flow rate of the air flow generated by the fan rotated by the drive of the motor by using the Coanda effect to deliver to the hair of the user's hair dryer To design.

Another object of the present invention is to place the electrical component inside the hair dryer away from the discharge portion corresponding to the upstream portion of the flowing air flow to block the transfer of moisture directly to the electrical component.

According to a feature of the present invention for achieving the above object, the present invention is a housing formed with an inlet slot is formed so that the inner space is formed inside and the outside air flows into the inner space on one side of the outer surface, An airflow forming unit positioned in an inner space and allowing air to enter the outside of the housing through the inlet slot and passing through the housing, and a heating element positioned in the inner space of the housing to selectively supply heat to the air passing through the housing; And a discharge nozzle coupled to one end of the housing and provided with a co-facing surface through which air that has passed through the inside of the housing passes through and sucks outside air by air passing through the co-facing surface.

The other end of the housing is provided with a power supply for supplying power for driving the heating element and the air flow forming unit.

The airflow forming unit includes a motor and a fan rotated by the motor to form an airflow.

The motor is assembled to a motor housing fixed to an inner space of the housing.

The discharge nozzle has a cylindrical shape having at least a part of a circular shape, and a central flow path portion is formed at both ends of a secondary inlet through which the outside air flows in and around the center, and a discharge hole that mixes and discharges the air passed through the housing and the outside air. do.

An inner flow path through which the air passing through the housing flows is formed in an annular shape, and a discharge slit for discharging air to the nose face is formed in an annular shape in a downstream portion of the inner flow path.

An inner surface wall is formed on the inner surface of the discharge nozzle, and the inner surface wall is continuously formed with a co-facial surface for guiding air exiting the discharge slit and a diffusion surface for gradually increasing the flow cross-sectional area of the central flow path to the discharge port. .

The outer surface of the discharge nozzle is provided with a coupling ring formed with a threaded portion on the inner surface, the one end portion of the housing is formed with a screw portion corresponding to the screw portion is coupled to the one end of the housing.

The airflow forming portion is located upstream of the airflow flowing inside the housing, and the heating element is located downstream of the airflow than the airflow forming portion.

According to another feature of the invention, the present invention is a housing formed with an inner space is formed inside the inlet slot to allow the outside air to flow into the inner space on one side, and the inlet slot is located in the inner space of the housing A motor that rotates a fan to form an airflow through which air is introduced from the outside of the housing and passes through the housing; a heating element for selectively supplying heat to air passing through the housing and positioned in the interior space of the housing; It is coupled to one end of the housing and provided with an internal flow path through which the air passing through the inside of the housing passes and the co-facial face guiding the air exiting the inner flow path, so that outside air is sucked together by the air passing through the co-facial face. And a discharge nozzle for discharging.

The discharge nozzle has a cylindrical shape having at least a portion of a circular shape, and an outer wall is formed on the outer surface, and an inner surface is formed on the inner surface, and an inner flow path is formed between the outer wall and the inner wall to flow air passing through the housing. A discharge slit for discharging air passing through the inner flow passage is provided around the inside of the rear end to guide the air to the nose face formed on the inner surface wall, and through which the outside air flows through the center of the discharge nozzle. A central flow path portion is formed at each end of the inlet and the outlet through which air passing through the housing and external air are discharged.

The inner face wall of the discharge nozzle is continuously formed with a co-facial surface for guiding air exiting the discharge slit and a diffusion surface for gradually increasing the flow cross-sectional area of the central flow path toward the discharge port.

In the hair dryer according to the present invention, the following effects can be obtained.

In the present invention, in addition to the air sucked by the drive of the fan into the inside of the hair dryer, the air supplied from the outside of the discharge nozzle is mixed by the coanda effect, so that the total flow rate is amplified and discharged, so that the conventional hair dryer discharges the same flow rate. In comparison, motors and fans with smaller capacities may be used. Therefore, the size of the entire hair dryer can be miniaturized and cost can be reduced.

In addition, in the present invention, since the length of the flow path through which the air from the inside of the housing passes through the discharge nozzle is relatively long, and the discharge slit is formed very narrowly, the waterproof performance of the housing itself can be increased, so that moisture from the outside of the housing can be increased. There is also an effect that can be prevented from being transferred to the inside to prevent the transfer of moisture to the electrical components inside the housing.

In addition, since the heating element has a structure capable of sufficiently shielding the electromagnetic waves generated from the heating element in the upstream portion of the air flow relatively at the discharge port of the discharge nozzle, it is possible to minimize the electromagnetic wave delivered directly to the user.

In addition, the components such as the heating element is relatively far from the discharge port and can be shielded from the outside structurally to increase the waterproof performance of the housing itself, so that the shielding performance against noise as well as the waterproof performance is improved, and the motor and fan are relatively The use of a small one also has the effect of reducing noise as a whole.

In addition, since the capacity of the motor can be relatively reduced, power consumption is also reduced, so that even when a battery is used, the use time can be relatively maintained over a certain time, thereby making the hair dryer portable.

1 is a perspective view showing the configuration of a preferred embodiment of a hair dryer according to the present invention.
Figure 2 is a partial cross-sectional perspective view showing the internal configuration of an embodiment of the present invention.
Figure 3 is an exploded perspective view showing the configuration of the motor and the fan constituting the embodiment of the present invention.
4 is a cross-sectional view showing a detailed configuration of a discharge nozzle constituting an embodiment of the present invention.
Figure 5 is an operating state showing that the air flow is formed in the embodiment of the present invention.

Hereinafter, a preferred embodiment of the hair dryer according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in the figures, the housing 10 forms part of the exterior of the hair dryer. The housing 10 has a cylindrical shape in this embodiment and an inner space 11 in which parts to be described below are installed is formed. The shape of the housing 10 may be polygonal or oval in cross section, such as a square.

An operation button 12 is provided at one side of the outer surface of the housing 10. The operation button 12 serves to manipulate the operation of the hair dryer. A plurality of inflow slots 14 are formed at the lower end of the housing 10. The inlet slot 14 is formed around the lower outer surface of the housing 10 are formed in parallel. The inlet slot 14 serves as a passage through which air enters from the outside of the housing 10.

The power supply unit 16 is provided at the lower end of the housing 10. The power supply unit 16 is a part for supplying power for driving the hair dryer. The power supply unit 16 may be a rechargeable battery or a part into which a battery can be inserted, or a part including a power line and a plug for connection to a power source.

The motor housing 18 is provided inside the housing 10. The motor housing 18 is installed on the inner surface of the housing 10 in close contact with the outer surface thereof. In the motor housing 18, an inflow slot 18 ′ is formed at a position corresponding to the inflow slot 14 to allow outside air to flow into the motor housing 18.

The motor 20 is installed in the motor housing 18. The motor 20 is driven by receiving power from the power supply unit 16 to provide rotational force. The fan 22 is installed on the rotating shaft (not shown) of the motor 20. The fan 22 is rotated inside the motor housing 18 to direct air from the outside of the housing 10 to the inside of the motor housing 18 through the inlet slot 14 and the inlet slot 18 ′. Inflow and flow to the discharge nozzle 30 to be described below.

The fan 22 rotates inside the motor housing 18 to flow air, and is designed so as not to interfere with a configuration for guiding the flow of air formed on the inner surface of the motor housing 18. The motor housing 18, the motor 20 and the fan 22 are made of one assembly and inserted into the housing 10 to be assembled.

The cap 24 is installed on the upper inner surface of the housing 10. The cap 24 is composed of a ring-shaped cap body 25 and a connecting bar 25 'traversing the cap body 25 in the radial direction. The cap 24 is press-fitted or screwed into the inner surface of the housing 10 to serve to fix the components installed inside the housing 10.

A plurality of fixing bars 26 are provided between the cap 24 and the motor 20 to fix the motor 20 to the inside of the housing 10. The fixing bar 26 is made of four in this embodiment. Of course, the cap 24 and the fixing bar 26 are not necessarily used if the motor housing 18 can be firmly fixed to the inside of the housing 10.

The heating element 28 is installed at a position corresponding to an inner upper end of the housing 10, that is, an upper portion of the motor 20. The heating element 28 is a plurality of heating plates are arranged side by side in the longitudinal direction of the housing 10, the heat exchange is performed while the air passes between the heating plates. The air passing through the heating element 28 receives heat and becomes relatively high in temperature. The heating element 28 receives power from the power supply unit 16 to generate heat.

The discharge nozzle 30 is installed on the upper end of the housing 10. The discharge nozzle 30 is configured to discharge the combined air and external air passed through the housing 10. At least a part of the cross section of the discharge nozzle 30 is circular. In this embodiment, the cross section of the discharge nozzle 30 is an elliptic cylinder shape which becomes an ellipse. However, the cross section of the discharge nozzle 30 may be a circle.

The coupling ring part 32 is formed at one side of the outer surface of the discharge nozzle 30. The coupling ring part 32 is coupled to the upper end of the housing 10. A screw portion is formed on an inner surface of the coupling ring portion 32 and a screw portion corresponding to an outer surface of the upper end of the housing 10 is formed to allow the discharge nozzle 30 to be coupled to the housing 10.

An internal flow path 33 is formed in the discharge nozzle 30. The inner passage 33 is formed in an annular shape surrounding the inside of the discharge nozzle 30, and the overall shape of the inner passage 33 is correlated with the shape of the discharge nozzle 30. The inner passage 33 is a portion through which the air exiting the housing 10 flows, and the coupling ring 32 is an inlet.

The inner flow path 33 is formed by the outer wall 34 and the inner wall 35 cooperate with each other, the outer wall 34 forms the outer surface of the discharge nozzle 30, the inner wall 35 is An inner surface of the discharge nozzle 30 is formed.

If a certain section is coan at the upstream portion of the air flow exiting the inner flow passage 33 out of the surface of the inner surface wall 35, that is, the position outside the discharge slit 36 to be described below (Coanda surface) 35 ′. do. The coplanar face 35 'may flow along the surface when the fluid flows to generate a coanda effect. The coanda effect is well known, and thus, further description thereof will be omitted. A diffusion surface 35 "is provided along the inner surface wall 35 in connection with the co-facing surface 35 '. As for the diffusion surface 35", the flow cross section formed by the inner surface wall 35 gradually increases. It is configured to be wider.

A discharge slit 36 is formed downstream of the internal passage 33. The discharge slit 36 is formed around the inner surface of the rear end of the discharge nozzle 30, and is formed by forming a predetermined gap between the inner wall 35 and the end of the outer wall 34 adjacent to each other. Accordingly, the shape of the discharge slit 36 corresponds to the cross sectional shape of the discharge nozzle 30. The discharge slit 36 allows the air flowed along the inner flow passage 33 to be discharged and flow to the co-face 35 '. The outer wall 34 forming the discharge slit 36 has a semicircular longitudinal section, and has a predetermined gap with a rear end of the inner wall 35. The gap is the discharge slit 36, the width of the discharge slit 36 and the angle of the co-face 35 ′ determine the flow rate discharged through the discharge slit 36. The outer wall 34 and the inner wall 36 are formed so that the flow cross-sectional area gradually narrows from the inner passage 33 to the discharge slit 36.

A central flow path portion 37 is formed by penetrating the inside of the discharge nozzle 30 back and forth, and the inner surface of the central flow path portion 37 is diffused with the coplanar surface 35 'which is the surface of the inner wall 35. A surface 35 "is formed. Therefore, the central flow path portion 37 gradually increases its flow cross-sectional area from the rear end of the discharge nozzle 30 toward the tip.

A distal end of the central flow path part 37, that is, a part where air is finally discharged from the discharge nozzle 30 is called a discharge port 38, and a rear end of the central flow path part 37, that is, the discharge nozzle 30. The portion where air flows from the outside into the central flow passage part 37 is called a secondary inlet 38 ′. Through the secondary inlet 38 ′, the air flowing out through the discharge slit 36 flows along the nose face 35 ′, thereby introducing air from the outside of the discharge nozzle 30 by a low pressure region. As such, the air introduced through the secondary inlet 38 ′ is mixed with air passing through the discharge slit 36 while passing through the region corresponding to the diffusion surface 35 ″ and discharged through the discharge hole 38. .

Hereinafter, the hair dryer according to the present invention having the configuration as described above will be described in detail and used.

The hair dryer of the present invention is equipped with a power supply unit 16 at the lower end of the housing (10). The lower end of the housing 10 is closed by the power supply unit 16 or a separate structure, and the motor housing 18 is inserted through the upper end of the housing 10. The motor 20 and the fan 22 are already assembled in the motor housing 18. That is, the motor housing 18, the motor 20 and the fan 22 are made of one assembly. Such a configuration may be considered as an airflow forming unit by inducing external air to the inside of the housing 10 to create an airflow passing through the inside of the housing 10.

After the motor 20 is inserted, the heating element 28 is inserted into and fixed to the inner space 11 of the housing 10. The bar 26 is inserted into the upper end of the housing 10 into which the heating element 28 is inserted, and one end thereof is seated on one surface of the motor 20. Next, the cap 24 is pressed into and fixed to the upper end inlet of the housing 10, thereby preventing the components inside the housing 10 from being randomly moved or falling out of the housing 10.

Next, the screw portion formed on the inner surface of the coupling ring 32 of the discharge nozzle 30 is coupled to the screw portion formed on the outer surface of the upper end of the housing 10. In this way, the discharge nozzle 30 is coupled to the housing 10, and the interior of the housing 10 and the internal flow path 33 of the discharge nozzle 30 communicate with each other.

Assembled as above, in order to operate the hair dryer of the embodiment of the present invention, the user must operate the operation button 12. For example, the hot air mode and the normal temperature wind mode may be selected by operating the operation button 12. In the hot wind mode, the heating element 28 generates heat to set the temperature of the air discharged to the discharge port 38 to a predetermined value. In the case of the normal temperature wind mode, the heating element 28 does not generate heat so that the air sucked into the interior of the housing 10 passes through the heating element 28 without heat exchange, thereby allowing air at room temperature to flow to the discharge port 38. Discharged.

Intake of air into the housing 10 is performed by driving the motor 20 to rotate the fan 22. As the fan 22 is rotated, air flow is formed in the interior of the housing 10 in the direction of the heating element 28. The inside of the inlet slot 14 of the housing 10 is caused by the air flow. The space 11 is relatively low pressure and air is introduced from the outside of the housing 10 through the inlet slot 14 and the inlet slot 18 ′ as shown by arrow i of FIG. 5.

The air introduced into the housing 10 passes through the outside of the fan 22 and the motor 20 and passes between the heating plates of the heating element 28. In the hot wind mode, heat is exchanged between the heating plate and the air, thereby raising the temperature of the air.

Air passing through the heating element 28 flows through the coupling ring part 32 to the internal flow path 33 of the discharge nozzle 30 as indicated by arrow e in FIG. 5. The air delivered to the inner passage 33 is transferred to the entire annular inner passage 33 and exits the inner passage 33 through the discharge slit 36.

The air exiting the discharge slit 36 flows along the coplanar surface 35 ′ as shown by arrow A of FIG. 5. As such, when air flows along the nose face 35 'and the velocity increases, the pressure around the nose face 35' becomes relatively low and the discharge nozzle 30 is indicated by arrow B of FIG. Outside air flows into the central flow path part 32 through the secondary inlet 38.

External air introduced into the central channel 32 through the secondary inlet 38 and air exiting the discharge slit 36 are sections of the central channel 32 corresponding to the diffusion surface 35 ″. While passing through the mixture is finally discharged through the discharge port 38 is delivered to the user's hair.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, in the present embodiment, the configuration of the motor 20 and the fan 22 to allow air to be sucked into the housing 10 may be different. That is, the position of the fan 22 can be made downstream of the airflow rather than the motor 20. In addition, the fan 22 may have various shapes.

In addition, the motor 20 does not necessarily need to be inserted into the housing 10 while being installed in the motor housing 18. The motor 20 may be directly mounted in the inner space 11 of the housing 10. In this case, a structure for fixing the motor 20 may be formed on the inner surface 11 of the housing 10.

In addition, unlike the illustrated embodiment, the position of the airflow forming unit including the heating element 28 and the motor 20 is close to the inlet slot 14, and includes the motor 20. The air flow forming unit may be adjacent to the discharge nozzle 30.

10: housing 11: inner space
12: operation button 14: inflow slot
16: power supply unit 18: motor housing
18 ': Inlet slot 20: Motor
22: Fan 24: Cap
26 bar 28: heating element
30: discharge nozzle 32: coupling ring
33: inner flow path 34: outer wall
35: inner wall 35 ': if you know
35 ": diffused surface 36: discharge slit
37: central flow path portion 38: discharge port
38 ': 2nd inlet

Claims (12)

A housing having an inner space formed therein and having an inlet slot configured to allow external air to flow into the inner space on one outer surface thereof;
An airflow forming unit located in the inner space of the housing and allowing air to flow in from the outside of the housing through the inlet slot and pass through the housing;
A heating element positioned in an inner space of the housing and selectively supplying heat to air passing through the housing;
And a discharge nozzle coupled to one end of the housing and provided with a co-facing surface through which air that has passed through the inside of the housing passes through and sucks outside air by air passing through the co-facing surface. Hair dryer.
The hair dryer of claim 1, wherein a power supply unit for supplying power for driving the heating element and the air flow forming unit is provided at the other end of the housing.
The hair dryer of claim 2, wherein the air flow forming unit comprises a motor and a fan rotated by the motor to form an air flow.
4. The hair dryer of claim 3, wherein the motor is assembled to a motor housing fixed to an inner space of the housing.
The discharge nozzle has a cylindrical shape in which at least part of the discharge nozzle has a circular shape, and the air and the external air passing through the secondary inlet and the housing through which the external air flows in and around the center are introduced. A hair dryer, characterized in that the central flow path portion is provided with a discharge port for mixing and discharging.
The discharge passage of claim 5, wherein an inner flow path through which the air passing through the housing flows is formed in an annular shape, and a discharge slit for discharging air into the nose face is formed in an annular shape in a downstream portion of the inner flow path. Hair dryer characterized in that.
According to claim 6, wherein the inner surface of the discharge nozzle is formed in the inner wall, the inner surface wall diffuses to gradually increase the flow cross-sectional area to guide the air exiting the discharge slit and the central flow path portion to the discharge port Hair dryer, characterized in that the surface is formed continuously.
According to claim 7, wherein the outer surface of the discharge nozzle is provided with a coupling ring formed with a threaded portion on the inner surface, one end of the housing is formed with a screw portion corresponding to the screw portion is coupled to the one end of the housing Featuring a hair dryer.
9. The hair dryer of claim 8, wherein the airflow forming portion is located upstream of the airflow flowing in the housing and the heating element is located downstream of the airflow rather than the airflow forming portion.
A housing having an inner space formed therein and having an inlet slot configured to allow external air to flow into the inner space on one outer surface thereof;
A motor which is located in an inner space of the housing and rotates a fan which forms an airflow through which the air flows in from the outside of the housing and passes through the housing;
A heating element positioned in an inner space of the housing and selectively supplying heat to air passing through the housing;
It is coupled to one end of the housing and provided with an inner flow passage through which the air passing through the inside of the housing and a co-facing surface guiding the air exiting the inner flow passage to suck the outside air by the air passing through the co-facing surface. Hair dryer characterized in that it comprises a discharge nozzle discharged together.
The housing of claim 10, wherein the discharge nozzle has a cylindrical shape having at least a portion of a circular shape, and an outer surface is formed on an outer surface, and an inner surface is formed on an inner surface, and an inner flow path is formed between the outer surface wall and the inner surface wall. The air passing through the air flows, and a discharge slit for discharging the air passing through the inner flow passage is provided around the rear end to guide the air to the nose face formed on the inner wall, and passes through the center of the discharge nozzle back and forth And a central flow path portion provided at each end thereof with a secondary inlet through which air is introduced, and a discharge port through which air passing through the housing and external air are discharged.
12. The method of claim 10 or 11, wherein the inner surface of the discharge nozzle is formed with a co-facial surface for guiding the air exiting the discharge slit and the diffusion surface so that the flow cross-sectional area of the central flow path portion gradually increases toward the discharge port. Hair dryer characterized in that.

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