KR20210137751A - Hair dryer - Google Patents

Abstract

The present invention relates to a hair dryer and, more specifically, to a hair dryer that stabilizes the air flow entering a fan unit and suppress the occurrence of turbulence so as to be effective in increasing the internal flow efficiency and reducing noise, by changing the shape of fan unit components. To this end, the present invention comprises: a main body portion provided with a discharge portion through which air is discharged on one side; a handle portion extending from one side of the main body portion, and including an inlet portion which is in communication with the discharge portion and through which outside air is introduced; a heater provided inside the main body portion and heating the air introduced through the inlet portion; and an air flow unit disposed on any one among the main body portion or the handle portion and enabling the air introduced through the inlet portion to move to the discharge portion.

Description

Hair dryer

The present invention relates to a hair dryer, and relates to a hair dryer in which air introduced into an inlet is discharged toward an outlet, and can dry or tidy hair using the discharged air.

A hair dryer can be used to dry wet hair or to fix and style the hair to keep it in a specific shape. In addition, it can be used to tidy up the hair.

In the case of drying hair using a hair dryer, it is required to generate wind by forming an air flow at a high speed.

Therefore, a high-speed rotating motor and a blower fan coupled thereto are required, and a wind is generated according to the air flow generated by the blower fan, and the hair can be dried or hair styled using the generated wind.

However, in the process of forcibly generating air flow, the path of the air flow changes rapidly and turbulence or vortex may occur, and as the flow becomes unstable, air flow efficiency may decrease. will do

Hair dryer noise is mainly caused by two factors. First, noise is generated due to air blown generated by the friction of the air moving rapidly by the blower fan with the inner wall of the hair dryer body and accessories. Second, when the motor rotor rotates at high speed, the physical and electromagnetic vibrations generated are transmitted to the hair dryer main body to generate noise.

Looking in detail at the process of generating noise for the first reason, unnecessary noise is generated for reasons such as the air flow formed by the motor collides with the internal structure of the motor and forms turbulence or causes friction with the internal structure.

In addition, as mentioned above, turbulence is formed when noise is generated, which is not expected in the hair dryer design process. Even if it is an expected problem, it is desirable to suppress the occurrence of such turbulence. When turbulence is formed, there is a problem in that the efficiency of the motor is reduced and unnecessary power is consumed.

Noise generated for the first reason can be suppressed by appropriately changing the structure or arrangement of the hair dryer body and accessories.

Therefore, there is a need to devise a method for preventing unnecessary noise from being generated by allowing air to flow smoothly without forming turbulence in the driving unit of the hair dryer and solving the problem of wasting power.

In relation to this, Korean Patent No. 10-1407404 discloses an invention for reducing noise generated during operation of the hair dryer by inserting a suction grill located at an air inlet portion of the hair dryer with a smaller one than the conventional one.

In addition, Korean Patent Application Laid-Open No. 10-2016-0096330 discloses an invention for a hair dryer to solve a noise problem caused by amplifying the vibration of a motor into sound. To solve this problem, a transmission that can increase the rotation speed of the motor and transmit it to the blower fan is used. Although the transmission motor is driven at a relatively low rotational speed, the blower fan connected thereto can be rotated at a high speed, thus solving the noise problem without lowering the wind speed.

However, the inventions for solving the existing noise problem cannot fundamentally solve the noise generation because they do not remove the air flow that generates the noise by using a structural arrangement or shape. In addition, there is a problem in that an additional configuration is required, which takes up space and adds cost.

Therefore, it is necessary to develop a hair dryer that reduces the noise caused by the flow of air and prevents the efficiency of the motor from decreasing by changing the structural formation without adding a configuration.

Korean Patent Publication No. 10-1407404 (2014.05.12) Korean Patent Publication No. 10-2016-0096330 (2015.02.05)

An object of the present disclosure is to increase the efficiency of a fan motor flow path by minimizing a loss in the flow of air entering the fan motor.

The present disclosure aims to solve the problem of minimizing the three-dimensional flow generated in the impeller by reducing the vortex before the flow enters the wing of the impeller.

The present disclosure aims to solve the problem of stabilizing the air flow flowing into the impeller by using the shape of the impeller hub and reducing noise generated by the vortex through this.

An object of the present disclosure is to provide a hair dryer capable of efficiently using an internal space by stabilizing the flow of air entering a fan motor without adding a configuration.

An object of the present disclosure is to provide a hair dryer capable of lowering the load applied to the rotating shaft by reducing the size of the impeller and reducing the weight.

An object of the present disclosure is to provide a hair dryer capable of removing a groove for reducing the load of the impeller by reducing the size of the impeller and reducing noise generated by the existing groove.

The present disclosure stabilizes the inflow flow by giving a blend to the hubcap of the impeller in order to solve the above-described problem. In the case of the prior invention, the blend is not applied to the impeller, so the hub cap protrudes above the housing. This is to prevent vortexing of the inflow flow. In the case of applying the blend, it is possible to prevent the vortex from occurring on the hub side as the flow is introduced, and the three-dimensional flow can be formed to lower the efficiency and prevent noise from being generated.

In the case of existing products, since blend is not applied to the hub cap, a method of increasing the length of the impeller hub cap is used to reduce noise. As a result, the impeller hubcap protrudes above the housing. However, the present disclosure can stabilize the flow without increasing the hubcap height due to the blend applied to the hubcap.

The present disclosure relates to a body part provided with a discharge part from which air is discharged on one side, a handle part extending from one side of the body part and communicating with the discharge part and including an inlet part through which air is introduced, and is provided inside the body part to provide the inlet. It may include a heater for heating the air introduced into the unit and an air flow unit disposed on any one of the main body portion or the handle portion to move the air introduced into the inlet portion to the discharge portion, wherein the air flow unit has an appearance A driving unit comprising a case having a suction part on one side and an exhaust part on the other side, a stator fixed inside the case to generate a rotating magnetic field, and a rotor accommodated in the stator and rotated by the rotating magnetic field, the rotation In the former, a rotating shaft extending or coupled in the direction of the suction unit or the discharge unit, an impeller that is coupled to one end of the rotating shaft adjacent to the suction unit and rotates with the rotating shaft and sucks air in the atmosphere and is accommodated in the case It may include a guide part for guiding the air sucked by the impeller in the direction of the discharge part, the impeller is a hub part coupled to the rotation shaft and the hub part protrudes from the hub part toward the inner circumferential surface of the case so that the rotation shaft rotates. It may include a wing portion for generating air flow according to the wing portion, and the hub portion may include a hub body from which the wing portion protrudes and a hub cap extending from one surface of the hub body adjacent to the intake portion in the direction of the intake portion, The hub cap may be formed such that the area of the cross-section decreases from the hub body toward the suction part.

The hub cap may include a circular first surface forming a free end of the hub cap and a second surface extending from an outer circumferential surface of the first surface toward the hub body.

The second surface may be formed to extend from the first surface toward the hub body in a curved surface.

The second surface may be convex toward the suction part.

The first surface may be disposed on the same line as one end of the case in which the suction part is formed.

An axial separation distance of the rotation shaft between one surface of the hub body facing the guide part and the guide part may be uniformly provided.

The guide part may include a guide hub coupled to the stator and a guide wing part protruding from the guide hub toward the inner circumferential surface of the case to guide the air sucked in by the impeller in the direction of the discharge part.

The guide wing portion may be provided to be spaced apart from the inner circumferential surface of the case.

The guide hub may include a guide hub body from which the wing portion protrudes, and a guide hub cap extending from one surface of the guide hub body adjacent to the impeller in the direction of the impeller, wherein the guide hub cap is a third facing the impeller. It may include three surfaces and a fourth surface extending from the outer peripheral surface of the third surface toward the guide hub body.

The guide hub cap may be formed to increase in cross-sectional area from the third surface toward the guide hub body.

A diameter of the third surface may be greater than or equal to a diameter of the hub body.

The wing part may be provided to be inclined with respect to the axial direction of the rotation shaft, and the guide wing part may be provided to be inclined in the opposite direction to the wing part with respect to the axial direction of the rotation shaft.

It may further include a main bearing coupled to the rotation shaft and disposed between the impeller and the driving unit to rotatably support the rotation shaft.

The main bearing part may be provided in contact with the stator and the guide part.

It may include an auxiliary bearing part coupled to one end of the rotation shaft in the direction of the discharge part to rotatably support the rotation shaft, and a bracket to receive the auxiliary bearing part and be coupled to the guide part.

The bracket may include a accommodating part having an accommodating space for accommodating the auxiliary bearing part, and a leg part protruding from an outer circumferential surface of the accommodating part and overlapping the guide part.

The leg part may include a first leg protruding from the receiving part in a radial direction of the rotation shaft and a second leg protruding from an end of the first leg in the axial direction of the rotation shaft and coupled to the guide part.

The present disclosure has the effect of providing a hair dryer capable of stabilizing the air flow from the impeller hub side.

The present disclosure has the effect of providing a hair dryer capable of reducing flow loss through flow stabilization at the impeller hub side, where relatively large flow loss occurs.

The present disclosure has the effect of providing a hair dryer capable of preventing noise by lowering the flow loss on the impeller hub side.

The present disclosure has the effect of providing a hair dryer capable of improving the stability and efficiency of the hair dryer by lowering the weight of the impeller to lower the load applied to the rotating shaft from the viewpoint of rotor dynamics.

The present disclosure has an effect of providing a hair dryer capable of increasing structural rigidity by removing an internal groove for lowering the weight of an impeller.

The present disclosure has the effect of providing a hair dryer capable of preventing the generation of cavity noise by removing the internal groove for lowering the weight of the impeller.

The present disclosure has an effect of providing a hair dryer capable of increasing user convenience by lowering the weight of the impeller.

1 is a perspective view showing a hair dryer according to an embodiment of the present disclosure.
2 is an internal cross-sectional view of a hair dryer according to an embodiment of the present disclosure.
3 is a cross-sectional view of an air flow unit according to an embodiment of the present disclosure.
4 is an exploded perspective view of an air flow unit according to an embodiment of the present disclosure.
5 is a perspective view of an impeller according to an embodiment of the present disclosure;
6 is a perspective view of a guide unit according to an embodiment of the present disclosure.
7 is an exploded perspective view of an impeller and a guide part according to an embodiment of the present disclosure.

Hereinafter, embodiments disclosed herein will be described in detail with reference to the accompanying drawings. In this specification, even in different embodiments, the same and similar reference numerals are assigned to the same and similar components, and the description is replaced with the first description. As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. In addition, in describing the embodiments disclosed in the present specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in the present specification, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easy understanding of the embodiments disclosed in the present specification, and should not be construed as limiting the technical spirit disclosed in the present specification by the accompanying drawings.

Also in this specification, the term 'and/or' includes a combination of a plurality of listed items or any of a plurality of listed items. In this specification, 'A or B' may include 'A', 'B', or 'both A and B'.

1 is a perspective view of a hair dryer according to an embodiment of the present disclosure, and FIG. 2 is a cross-sectional view showing the inside of the hair dryer according to an embodiment of the present disclosure. The hair dryer according to an embodiment of the present invention includes a body portion 100 and a handle portion 300 as shown in FIGS. 1 and 2 .

The body part 100 may be provided in a cylindrical shape. However, the present invention is not limited thereto and may be formed in various shapes. The main body 100 may have a discharge unit 200 through which air is discharged on one surface. Air flowing inside the main body 100 is introduced through the inlet 310 , and the inlet 310 may be provided in the main body 100 or the handle 300 .

When the inlet 310 is provided in the handle 300 , a flow path through which air can flow may be formed in the handle 300 . In addition, it may be provided to communicate from the inlet part 310 formed in the handle part 300 to the discharge part 200 formed in the body part 100 .

The handle part 300 may be formed to extend from one side of the body part 100 . The handle portion 300 may be formed to extend from all surfaces of the body portion 100 except for the portion where the discharge portion 200 is formed.

In general, it may extend in a direction close to perpendicular to the surface on which the discharge part 200 is formed. For example, it is preferable that the handle portion 300 is formed such that the discharge portion 200 of the body portion 100 faces the direction in which the knuckles face when the user grips the handle portion 300 . do. However, the present invention is not limited thereto, and the handle unit 300 may be formed to extend from a surface facing the discharge unit 200 .

1 and 2, the handle part 300 extending downward from the main body part 100 is shown. The handle part 300 may be a part held by a user's hand, and thus may have a shape to improve grip convenience. The extending direction of the handle part 300 may be various, but for convenience of description below, the extending direction of the handle part 300 from the main body part 100 will be described below.

An inlet 310 through which external air flows into the hair dryer may be formed below the handle 300 . The inlet portion 310 may be formed from the lower side of the handle portion 300 toward the outer peripheral surface, but is not limited thereto, and may be formed in various ways, such as formed toward the lower side of the handle portion 300 . The inlet 310 may be formed in a shape having a plurality of through holes through which outside air may be introduced.

According to an embodiment of the present disclosure, the inside of the hair dryer may include an air flow unit 600 for generating an air flow inside the hair dryer by sucking outside air. The air flow unit 600 may be disposed inside the body part 100 or the handle part 300 . In the present disclosure, the invention will be described based on the air flow unit 600 being disposed on the handle portion 300 .

A heater 500 capable of adjusting the temperature of the air discharged to the discharge unit 200 according to the air flow generated by the air flow unit 600 may be provided inside the body unit 100 .

FIG. 2 schematically shows the heater 500 provided in the body part 100 . The heater 500 may be a method of heating a gas by generating heat by providing a current to a coil-shaped resistor. However, the present invention is not limited thereto, and a configuration for heating a gas, such as using a thermoelectric element, may be adopted.

The heater 500 may be disposed at various positions inside the main body 100 . However, as the distance between the discharge unit 200 and the heater 500 increases, the possibility that the gas discharged from the discharge unit 200 is cooled before reaching the user and cannot be used as intended for use increases. The heater 500 is preferably disposed inside the body part 100 adjacent to the discharge part 200 . However, the present invention is not limited thereto, and as long as the temperature of the gas discharged from the discharge unit 200 can be appropriately adjusted, it may be disposed in another portion of the body unit 100 .

The operation method of the hair dryer according to an embodiment of the present invention will be schematically described with gas flow as follows.

First, the user operates the power button disposed on the main body part 100 or the handle part 300 . When the power button is turned on, the air flow unit 600 is operated and external air is introduced into the hair dryer through the inlet 310 .

The air introduced through the inlet 310 flows along the inner space of the handle 300 by the air flow unit 600 toward the discharge unit 200, and in the discharge unit 200 Air is discharged and provided to the user. The user can dry wet hair using the discharged air, or fix and style the hair to maintain a specific shape. It can also be used to straighten hair.

In this process, the flow rate of the air on the handle part 300 and the body part 100 may be controlled by the air flow unit 600 , and the temperature may be controlled by the heater 500 . . The operation state control of the air flow unit 600 and the heater 500 may be performed by a user operating the operation unit, or may be automatically performed according to an operation mode preset in the control unit.

An embodiment of the present invention may include an operation mode that can improve the user's operation convenience or the utility of the hair dryer. In addition, the manipulation unit may be provided so that a user can use the hair dryer by selecting a desired driving mode, and the manipulation unit may be provided in various types and shapes.

For example, the operation unit may include a plurality of buttons or a rotary dial to select an operation mode, and may further include additional buttons or selection means.

In addition, the manipulation unit may be provided on the body unit 100 or provided on the handle unit 300 and provided to the user, and a plurality of buttons or operating means are provided on the body unit 100 and the handle unit 300 . It may be distributed in

Meanwhile, the control unit may be signally connected to a temperature sensor built into the hair dryer. The control unit may be installed in various positions as needed, and the control unit may be disposed on a PCB installed adjacent to the rear surface of the body unit 100 .

Also, the control unit may determine the current driving mode through the manipulation unit operated by the user. The control unit may receive a set value manipulated by the user to control the driving state of the heater 500 and the air flow unit 600 .

, 40℃?, 60℃? 및 90

등과 같이 미리 저장되고, 상기 히터(500)는 상기 제1,2,3,4온도 중 어느 하나로 선택될 수 있도록 마련될 수 있다.In this case, the heater 500 may be operated with a temperature value set by the controller. For example, in the control unit, the first, second, third, and fourth temperatures are, for example, 28

, 40℃?, 60℃? and 90

It is stored in advance, such as, and the heater 500 may be provided so that any one of the first, second, third, and fourth temperatures can be selected.

That is, the control unit may be electrically and signally connected to the manipulation unit, the heater 500 and the air flow unit 600 . The control unit may receive a signal from the operation unit and control the heater 500 and the air flow unit 600 according to the temperature and speed of the discharge air.

The discharge part 200 provided in the body part 100 is shown. As shown in FIG. 1 or 2 , the body part 100 may have a substantially circular cross-section and a length. However, the cross-sectional shape of the body part 100 may vary as needed.

The shape of the body part 100 may vary, but FIGS. 1 and 2 show the shape of the body part 100 having a circular cross section and a length. Hereinafter, for convenience of description, the main body 100 has a length extending forward and backward as shown in FIG. 1 , and a cross-section will be described based on a substantially circular shape.

The open side of the main body 100 may be in various positions, but may correspond to the front side as shown in FIG. 2 , and the discharge unit 200 may cover the front side of the main body 100 as shown in FIG. 2 . It may be provided so as to partially shield the open side while forming.

3 and 4 show a combined cross-sectional view and an exploded perspective view of the air flow unit.

Referring to FIG. 3 , the air flow unit 600 discharges the suction unit 601 into which the external air introduced into the inlet 310 is sucked and the air to the outside of the air flow unit 600 to the outside of the hair dryer. It may include a case 610 including the discharge unit 602 to guide the discharge unit 200 of the. The case 610 forms the exterior of the air flow unit 600 and includes other components for generating air flow therein.

The inside of the case 610 includes a stator 621 fixed inside the case 610 to generate a rotating magnetic field, and a rotor 622 accommodated in the stator 621 and rotated by the rotating magnetic field. It may include a driving unit 620 that In addition, the rotor 622 may include a rotating shaft extending or coupled to the suction unit 601 or the discharge unit 602 direction. The rotation shaft 630 rotates together with the rotation of the stator 621 and may transmit a rotational force to a configuration coupled to one end of the rotation shaft 630 . Here, the driving unit 620 and the rotating shaft 630 may be provided as one module, and a generally used motor may be used.

An impeller 640 generating an air flow may be coupled to one end of the rotation shaft 630 in the direction of the suction unit 601 . The impeller 640 rotates together with the rotation shaft 630 and may generate an air flow that sucks air into the suction unit 601 and discharges the suctioned air toward the discharge unit 602 . The impeller 640 may have a through hole formed in its center so that the rotation shaft 630 may be press-fitted or may be coupled to the rotation shaft in a different manner.

The impeller 640 may include a hub portion 641 that is coupled to the rotation shaft 630 and forms a central portion, and a wing portion 642 that generates air flow according to rotation. The hub part 641 may be provided in a cylindrical shape, but is not limited thereto, and may be formed in another manner as long as it has a shape that can be coupled to the rotation shaft 630 .

A wing portion 642 protruding in a radial direction from the outer circumferential surface of the hub portion 641 may be formed. The wing portion 642 may be formed in various numbers. It is preferable that the hair dryer be provided in sufficient number to generate sufficient air flow for use.

In addition, the wing portion 642 may be formed in various shapes. A portion coupled to the hub portion 641 and the free end may have different inclinations. It can be provided to generate sufficient air flow while improving bond stability. It is preferable that the length of one end of the wing portion 642 coupled to the hub portion 641 is shorter than the length of the free end. When the wing portion 642 is formed as described above, a stronger air flow may be generated. However, the present invention is not limited thereto and may be provided in various shapes.

The hub part 641 may include a hub body 6411, which is a portion from which the wing part 642 protrudes, and the hub cap 6412 extending to the side of the suction part 601 of the hub body 6411. have.

Here, the extended means are integrally formed and include those that are coupled as a separate component from the extended ones. That is, the hub cap 6412 is integrally formed with the hub body 6411 on one surface of the hub body 6411 and may extend in the direction of the suction unit 601 , and is separate from the hub body 6411 . may be coupled to shield one side of the hub body 6411 in the direction of the suction part 601 .

The hub cap 6412 is installed on the front surface of the hub part 641 of the impeller 640 in order to protect the internal structure of the axial fan because the driving part 620 and the impeller 640 are connected by the same rotation shaft 630 . can be At the same time, it can serve to reduce uneven inlet flow. In general, the performance of the axial fan may be greatly changed by the hub cap 6412 . Here, the axial fan means a fan that generates flow in the longitudinal direction of the rotating shaft.

The shape of the hub cap 6412 may serve to improve the efficiency and stability of the impeller 640 and solve the noise generation problem by controlling the flow of air sucked in from the suction unit 601 . The detailed structure and effect of the hubcap 6412 will be described below.

A guide part for guiding air sucked into the suction part 601 of the case 610 by the impeller 640 in the direction of the discharge part 602 of the case 610 in the inside of the case 610 . 650 may be provided.

Since the force generated by the rotation of the impeller 640, that is, the force generated in the rotational direction of the axial fan, is involved in the air discharge of the axial fan, the air introduced by the impeller 640 is The circumferential speed is strong. When the impeller 640 rotates, the force generated in the rotational direction of the impeller 640 in addition to the force that the impeller 640 pushes the air forward also acts.

Accordingly, most of the air discharged through the impeller 640 does not go straight forward, but spreads widely laterally. When most of the discharged air spreads out to the side as described above, the front discharge range of the discharged air is inevitably reduced.

Accordingly, the guide portion 650 may be included to eliminate circumferential velocity and enhance axial velocity. Here, the axial speed refers to a speed from the suction unit 601 to the discharge unit 602 of the case 610 .

As the rotation speed of the impeller 640 increases, the air volume of the air passing through the guide unit 650 increases, and as the air volume increases, the guide unit 650 can further help improve air discharge performance. .

The guide part 650 may be coupled to an outer circumferential surface of the stator 621 forming the driving part 620 to guide air flowing inside the case 610 . However, the present invention is not limited thereto and may be fixed to the inner circumferential surface of the case 610 if it can serve to guide the air flow. In addition, the guide part 650 may serve to support the driving part 620 inside the case 610 by accommodating the stator 621 , the rotor 622 , and the rotation shaft 630 . .

The guide part 650 has a guide hub 651 that forms a body at the center and forms a space for accommodating the stator 621, and protrudes from the outer periphery of the guide hub 651, and the air inside the case 610 may include a guide wing portion 652 for guiding from the suction unit 601 to the discharge unit 602 . The guide wing portion 652 may be provided in plurality, and may be provided in an appropriate number in a line that does not obstruct the air flow while sufficiently guiding the air inside the case 610 .

The guide wing portion 652 may be provided in parallel with the axial direction of the rotation shaft 630 . However, the present invention is not limited thereto, and may be provided to be inclined in the axial direction of the rotation shaft 630 and may be provided to have a curvature in the inclined direction. When the guide wing portion 652 is provided with a curved surface, it is possible to obtain an effect of stabilizing the flow by gently guiding the air flow.

The guide hub 651 includes a guide hub body 6511 forming a body from which the guide wing portion 652 protrudes, and a guide hub cap 6512 extending from the guide hub body 6511 to the impeller 640 direction. ) may be included. Extending here may be provided to be formed as a separate configuration and coupled, and may be integrally formed. The guide hub body 6511 and the guide hub cap 6512 may be provided in various shapes to stabilize the flow of air flowing inside the case 610 . The shape and effect of the guide hub cap 6512 will be described below.

The configuration and coupling relationship of the air flow unit 600 will be described with reference to FIG. 4 . As described above, the case 610 forming the exterior may be provided to accommodate other components. The driving unit 620 including the stator 621 and the rotor 622 may be accommodated in the case 610 .

The case 610 may accommodate all of the stator 621 , the rotor 622 , and the guide part 650 , but is not limited thereto, and may be provided to accommodate a portion.

The rotating shaft 630 extending from the center of the rotor 622 toward the outlet 602 or the inlet 310 of the case 610 may be included. The guide part 650 may be coupled to an outer circumferential surface of the stator 621 . In addition, the impeller 640 may be coupled to one end of the rotation shaft 630 in the direction of the inlet 310 . The other end of the rotation shaft 630 may be accommodated by the bracket 660 . The bracket 660 may be coupled to one side of the case 610 . In addition, the guide part 650 may be coupled to the case 610 to support the driving part 620 , the rotation shaft 630 and the impeller 640 .

It may further include a main bearing part 631 coupled to the outer circumferential surface of the rotation shaft 630 positioned between the impeller 640 and the driving unit 620 to rotatably support the rotation shaft 630 .

The main bearing part 631 may be provided to contact the stator 621 or the guide part 650 between the stator 621 and the guide part 650 . The main bearing part 631 may be supported by the stator 621 or the guide part 650 . According to an embodiment of the present disclosure, the main bearing part 631 may be provided to simultaneously contact one surface of the stator 621 facing the impeller 640 and an inner peripheral surface of the guide part 650 .

An auxiliary bearing part 632 for rotatably supporting the rotation shaft 630 may be coupled to one end of the rotation shaft 630 in the direction of the discharge part 602 . The auxiliary bearing part 632 may support a load applied to the rotation shaft together with the main bearing part 631 .

The auxiliary bearing unit 632 may be rotatably accommodated while receiving a supporting force by the bracket 660 for accommodating the auxiliary bearing unit 632 . The bracket 660 may be coupled to the guide part 650 or the case 610 to receive a load applied by the rotation shaft 630 .

The bracket 660 protrudes from the outer circumferential surface of the receiving portion 661 and the receiving portion 661 having an accommodation space to accommodate the rotation shaft 630 to which the auxiliary bearing portion 632 is coupled to the guide. It may include a part 650 or a leg part 662 coupled to the case 610 .

The accommodating part 661 and the leg part 662 may be integrally formed, but the present invention is not limited thereto.

In addition, the accommodating part 661 may be provided so that an accommodating space is formed therein to surround the outer circumferential surface of the auxiliary bearing part 632 . The leg portion 662 may be provided in plurality, and if the number is sufficient to support the auxiliary bearing portion 632, various numbers may be provided.

The leg portion 662 may be composed of two parts. The leg portion 662 includes a first leg 6621 protruding from the receiving portion in a radial direction of the receiving portion and a second leg projecting from the free end of the first leg 6621 toward the guide portion 650 . (6622). The second leg 6622 may be coupled to the guide part 650 or the case 610 to support the rotation shaft 630 and the auxiliary bearing part 632 .

A receiving groove may be formed on one side of the guide hub 651 . This may be formed to engage with a protrusion protruding from the outer circumferential surface of the stator 621 . In addition, it may include a coupling portion which protrudes from one side of the second leg 6622 constituting the bracket 660 and is provided to engage the receiving groove of the guide hub 651 . Through this, the stator 621 , the rotor 622 , and the rotation shaft 630 may be fixed in the receiving space formed by the guide part 650 and the bracket 660 .

As described above, the guide part 650 may be provided to accommodate other components, but is not limited thereto. The guide part 650 may be integrally formed with the case 610 . The driving unit 620 may be provided between the guide unit 650 and the discharge unit 602 . The impeller 640 may also be provided to be coupled to the rotation shaft 630 between the guide part 650 and the driving part 620 .

As shown in FIG. 4 , when the guide unit 650 is provided to accommodate the driving unit 620 , other components such as the driving unit 620 and the rotating shaft 630 may be disposed in the space occupied by the guide unit 650 . This has the effect of improving space efficiency.

In addition, when the guide part 650 accommodates the driving part 620 and is supported by the main bearing part 631, the auxiliary bearing part 632 and the bracket 660, the driving part 620 It is possible to partially dampen the vibration generated by the Vibration generated according to the operation of the driving unit 620 is one of the main causes of noise when the hair dryer is operated.

The guide part 650 , the main bearing part 631 , the auxiliary bearing part 632 , and the bracket 660 attenuate the vibration of the driving part 620 to make unnecessary noise while the user is using the hair dryer. to prevent discomfort or discomfort.

5 illustrates an impeller according to an embodiment of the present disclosure.

5, the impeller 640 is provided to protrude in the radial direction of the impeller 640 from the hub portion 641 and the hub portion 641 having a through hole coupled to the rotation shaft as described above. It may include a wing portion 642 that generates an air flow according to the rotation of the impeller 640 .

In the case of drying hair using a hair dryer, it is required to generate wind by forming an air flow at a high speed.

Therefore, the rotating shaft 630 rotating at high speed and the impeller 640 coupled thereto are required, and a wind is generated according to the air flow generated by the impeller 640, and using the generated wind, the hair is dried or the hair is washed. can be styled.

However, in the process of forcibly generating air flow, the path of the air flow changes rapidly and turbulence or vortex may occur, and as the flow becomes unstable, air flow efficiency may decrease. will do

Hair dryer noise is mainly caused by two factors. First, noise is generated due to air blown generated by the friction of the air moving rapidly by the impeller 640 with the inner wall and accessories of the hair dryer body. Second, when the motor rotor rotates at high speed, the physical and electromagnetic vibrations generated are transmitted to the hair dryer main body to generate noise.

Looking in detail at the process of generating noise for the first reason, unnecessary noise is generated for reasons such as the air flow formed by the impeller 640 collides with the internal structure and forms turbulence or causes friction with the internal structure.

In addition, as mentioned above, turbulence is formed when noise is generated, and it is desirable to suppress the occurrence of such turbulence. When turbulence is formed, there is a problem in that the efficiency of the motor is reduced and unnecessary power is consumed.

The hub part 641 forms a body and includes a hub body 6411 providing an outer peripheral surface from which the wing parts 642 protrude, and a hub cap 6412 extending from the hub body 6411 in the inlet part 310 direction. ) may be included. As described above, extending here is a concept including being provided as an integral configuration and being provided as a separate configuration and coupled thereto. It can be appropriately selected whether to be formed as a separate structure or integrally according to the conditions of use.

The hub cap 6412 may be formed to have a cross-sectional area that decreases from the hub body 6411 toward the inlet 310 . The cross-section referred to herein means a cross-section perpendicular to the axial direction of the rotation shaft 630 .

When the area of the cross-section is equally extended, the flow of air sucked into the suction part 601 of the case 610 as the impeller 640 rotates may generate a vortex while passing the hub part 641 . . When the vortex flows into the wing portion 642 while the vortex is generated, a three-dimensional flow is formed, resulting in flow loss and reducing the efficiency of the impeller. In addition, when the three-dimensional flow occurs, unwanted noise may be generated, which may cause discomfort to the user.

However, when the cross section of the hub cap 6412 is provided to gradually increase along the air flow direction, when the impeller 640 rotates, air can naturally flow along the surface, thereby preventing flow loss to a certain extent. can be prevented

The hub cap 6412 has a first surface S1 having a circular shape forming a free end, and extends from the first surface S1 toward the hub body 6411 to form a side surface of the hub cap 6412 . It may include a second surface (S2) forming a.

The second surface S2 may be formed to increase in inclination from the first surface S1 to the hub body 6411 . That is, the hub cap 6412 may be provided such that a cross section in a direction parallel to the axial direction of the rotation shaft 630 is not a trapezoidal shape, but a trapezoidal cross section in which the side surface is formed as a convex curve.

The second surface S2 may be convex toward the extension direction of the hub cap 6412 . In 3D modeling, connecting two parallel sections with a curved surface can be expressed as “blend treatment” or “blend”. That is, it is possible to stabilize the flow flowing into the suction unit 601 by applying the blend to the hub cap 6412 .

The second surface S2 is provided with a curved surface to prevent flow loss when the inflow flow is stabilized, thereby improving the efficiency and stability of the impeller 640 . In addition, since it is possible to prevent the vortex from occurring in the flow, there is an effect of reducing the noise generated by the vortex.

The first surface S1 may be disposed on the same line as one end of the case 610 in which the inlet 310 is formed. Since the existing hubcap 6412 is not formed in a curved surface as in the present disclosure, the length of the hubcap 6412 is extended to protrude out of the case 610 to reduce flow loss. However, when the second surface S2 is formed as a curved surface as in the present disclosure, it is not necessary to extend the length of the hub cap 6412 , so that the height can be matched with one end of the case 610 .

As described above, when the hub cap 6412 is manufactured, the load of the impeller 640 may be relatively reduced. Therefore, it may not be necessary to form a groove unlike the conventional product using a method of digging a groove in the interior of the impeller 640 to lower the load of the impeller 640 .

In the case of digging a groove inside the impeller 640 as in the conventional product, a problem of generating unexpected noise by rapidly flowing air flows into the groove to form turbulence and vortex inside may occur.

However, as in the present disclosure, when the second surface S2 of the impeller 640 is formed in a curved surface, the hub cap 6412 can be made smaller, so to lower the load of the impeller 640, the impeller ( There is no need to dig a groove on one surface of the driving unit 620 in the direction of the 640). Therefore, there is an effect that can solve the noise problem generated by the impeller 640 of the existing product.

As described above, when a groove for reducing load is not formed in the impeller 640 , one surface of the hub body 6411 facing the guide part 650 and the guide part 650 are spaced apart in the axial direction. The distance may be formed constant.

That is, the axial distance between a name of the hub body 6411 facing the guide part 650 and the guide part 650 is constant means that the hub part 641 of the impeller 640 is It may be that the upper surface is formed as a flat surface without forming a depression.

6 illustrates a guide unit according to an embodiment of the present disclosure.

Referring to FIG. 6 , the guide part 650 may include a guide hub 651 that forms an accommodating space therein, and a guide wing part 652 that is formed to protrude from the guide hub 651 in a radial direction. .

The guide hub 651 may accommodate the driving unit 620 and the rotation shaft 630 therein. In addition, the guide wing portion 652 protruding from the outer circumferential surface of the guide hub 651 may serve to guide the air introduced by the impeller 640 to be discharged toward the discharge unit 602 .

The guide wing portion 652 may be provided in plurality. The guide wing portion 652 may be provided to protrude from the guide hub 651 so as to be parallel to the axial direction of the rotation shaft 630 . However, in order to smoothly guide the flow of air, the guide wing portion 652 may be provided to have a constant inclination relative to the axial direction. When the guide wing portion 652 is provided with an inclination, it is possible to partially prevent the formation of turbulence on the surface.

The guide hub 651 extends in the direction of the guide hub body 6511 from which the guide wing part 652 protrudes and the guide hub body 6511 adjacent to the impeller 640 in the impeller 640 direction. It may include a guide hub cap (6512). The term "extended" here is a concept that includes both those that are extended to be integrally formed and those that are provided in a separate configuration and are provided in contact with each other.

The guide hub cap 6512 may include a third surface S3 facing the impeller and a fourth surface S4 extending from the outer circumferential surface of the third surface S3 toward the guide hub body 6511. can

The third surface S3 may have a smaller area than the cross-sectional area of the guide hub body 6511 . That is, the cross-sectional area of the guide hub cap 6512 may be formed to increase from the third surface toward the guide hub body 6511 . The cross-sectional area referred to herein may mean an area of a cross-section in a direction perpendicular to the axial direction of the rotation shaft 630 .

The fourth surface S4 may have a curved surface. That is, the fourth surface S4 may be provided such that the slope increases from the third surface S3 toward the guide hub body 6511 . In other words, the fourth surface S4 may be convex toward the impeller 640 .

The fourth surface S4 may be convex toward the extension direction of the guide hub cap 6512 . In 3D modeling, connecting two parallel sections with a curved surface can be expressed as “blend treatment” or “blend”. That is, it is possible to stabilize the flow flowing into the guide wing portion 652 by applying a blend to the guide hub cap 6512 .

As described above, when the fourth surface S4 is formed, the turbulence and It is possible to prevent eddy currents from occurring. By reducing the flow loss as described above, it is possible to increase the efficiency and stability of the air flow unit 600 . In addition, there is an effect that can reduce the noise generated by the flow loss.

The third surface S3 forming the free end of the guide hub cap 6512 may have a diameter greater than or equal to the diameter of the hub body 6411 . When the diameter of the third surface S3 is smaller than the diameter of the hub body 6411, the flow path of the air flowing into the case 610 through the impeller 640 is the third surface. Passing through (S3), the result of expansion occurs.

As described above, when air passes through a rapidly expanding flow path, turbulence is formed in the corresponding portion. Accordingly, a large flow loss may occur during the flow of air due to the turbulence. Accordingly, by adjusting the cross-sectional area of the third surface S3, a flow path through which the air flows may be smoothly formed.

When the diameter of the third surface S3 is formed to be the same as the diameter of the hub body 6411, the air flowing into the case 610 through the impeller 640 flows through a flow path that flows smoothly. Therefore, flow loss can be minimized, and noise generated by turbulence can be reduced.

In addition, the diameter of the third surface (S3) is formed to be the same as the diameter of the hub body (6411), the third surface (S3) toward the guide hub body (6511) direction from the third surface (S3) When the cross-sectional area of the guide hub cap 6512 is formed to increase in parallel with the guide hub cap 6512, the air flowing in and flowing through the impeller 640 flows along the gradually reduced flow path.

In the case of flowing along the gradually shrinking flow path as described above, it is possible to prevent efficiency reduction or noise generation caused by turbulence or vortex flow because it smoothly moves by forming laminar flow rather than forming turbulence.

7 illustrates an impeller and a guide unit.

Referring to FIG. 7 , the wing part 642 constituting the impeller 640 and the guide wing part 652 constituting the guide part 650 are in the axial direction XX of the rotation shaft 630, respectively. can be formed side by side.

However, rather than being formed in parallel with the axial direction (X-X) of the rotation shaft 630, it is more preferable to be inclined to the axial direction (X-X) of the rotation shaft 630 in terms of reducing flow loss.

First, the wing portion 642 constituting the impeller 640 is required to be inclined to the axial direction (X-X) of the rotation shaft 630 in order to suck in external air according to the rotation. When the axial direction (X-X) of the rotation shaft 630 and the wing portion 642 of the impeller 640 are provided side by side, it may be difficult to generate a flow of air according to the rotation.

Next, in the case of the guide wing part 652 constituting the guide part 650 , the air flow generated by the wing part 642 of the impeller 640 is guided in the direction of the discharge part 602 . do That is, in the case of the guide wing portion 652, it is not essential to be inclined to the axial direction (X-X) of the rotation shaft 630 .

However, the guide wing part 652 constituting the guide part 650 is opposite to the direction in which the wing part 642 constituting the impeller forms an inclination with the axial direction XX of the rotation shaft 630 . It is preferable to be provided inclined in the direction.

The flow of air passing through the impeller 640 by inclining the wing portion 642 of the impeller 640 may generate turbulence and vortex in the inclined direction of the wing portion 642 . In such a situation, when flowing along the guide wing portion 652 of the guide portion 650 that forms an inclination in the same direction as the wing portion 642, the strength of turbulence and vortex is further increased, which is the flow It may cause side effects such as an increase in loss and noise generation.

However, when the guide wing part 652 of the guide part 650 is inclined in the opposite direction to the wing part 642 of the impeller 640 , the turbulence generated while passing the wing part 642 of the impeller 640 . And while the vortex flows along the opposite slope, it can be partially resolved.

A shape design for guiding the flow direction of the air flowing by the impeller 640 is applied to the guide wing portion 652 of the guide portion 650 . When the flow direction of the air flowing through the impeller 640 rapidly changes, the risk of turbulence is further increased while the air passes through the guide part 650 .

Therefore, it is preferable that the guide wing portion 652 serves to guide the flow direction of the air so as not to change abruptly. In addition, in order to solve the turbulence that may have already occurred in the impeller 640, the guide wing portion 652 is inclined in the opposite direction to the inclination direction of the impeller 640 to weaken the formed turbulence without further strengthening. can play a role.

Accordingly, the efficiency and stability of the hair dryer can be improved by reducing the flow loss caused by the turbulence or vortex. In addition, there is an effect of reducing noise generated by the turbulence or vortex.

The present disclosure may be modified and implemented in various forms, but the scope of the rights is not limited to the above-described embodiments. Therefore, if the modified embodiment includes the elements of the claims of the present disclosure, it should be regarded as belonging to the scope of the present disclosure.

100: body part 200: discharge part 300: handle part
310: inlet 400: air flow path 500: heater
600: air flow unit 601: suction unit 602: exhaust unit
610: case 620: driving unit 621: stator
622: rotor 630: rotation shaft 631: main bearing part
632: auxiliary bearing part 640: impeller 641: hub part
6411: hub body 6412: hub cap 642: wing part
650: guide unit 651: guide hub 6511: guide hub body
6512: guide hub cap 652: guide wing 660: bracket
661: receiving portion 662: leg portion 6621: first leg
6622: second leg S1: first surface S2: second surface
S3: 3rd side S4: 4th side

Claims (17)

a body portion provided with a discharge portion through which air is discharged on one side;
a handle portion extending from one side of the body portion and including an inlet portion through which air is introduced in communication with the discharge portion;
a heater provided inside the main body to heat the air introduced into the inlet; and
an air flow unit disposed on any one of the body part or the handle part to move the air introduced into the inlet part to the discharge part; and
The air flow unit is
a case having an external appearance and having a suction part on one side and a discharge part on the other side;
a driving unit including a stator fixed inside the case to generate a rotating magnetic field and a rotor accommodated in the stator and rotated by the rotating magnetic field;
a rotating shaft extending or coupled to the suction unit or the discharge unit from the rotor;
an impeller coupled to one end of the rotating shaft adjacent to the suction unit, rotating together with the rotating shaft, and sucking air in the atmosphere; and
and a guide part accommodated in the case and guiding the air sucked in by the impeller in the direction of the discharge part;
The impeller is
a hub portion coupled to the rotation shaft; and
and a wing portion protruding from the hub portion toward the inner circumferential surface of the case to generate air flow as the rotation shaft rotates;
the hub part
a hub body from which the wings protrude; and
and a hub cap extending from one surface of the hub body adjacent to the suction unit toward the suction unit.
The hub cap
A hair dryer in which the area of the cross-section decreases from the hub body toward the suction part. The method of claim 1,
The hub cap
A hair dryer comprising: a circular first surface forming a free end of the hub cap; and a second surface extending from an outer circumferential surface of the first surface toward the hub body. 3. The method of claim 2,
The second surface is a hair dryer, characterized in that extending from the first surface toward the hub body in a curved surface. 4. The method of claim 3,
The second surface is a hair dryer, characterized in that formed convex toward the suction part. 5. The method of claim 4,
The first surface is a hair dryer, characterized in that it is disposed on the same line with one end of the case in which the suction part is formed. 5. The method of claim 4,
A hair dryer, characterized in that the distance in the axial direction of the rotation shaft between the guide part and one surface of the hub body facing the guide part is constant. The method of claim 1,
the guide part
a guide hub coupled to the stator; and
Hair dryer comprising a; guide wing portion protruding from the guide hub toward the inner circumferential surface of the case to guide the air sucked by the impeller in the direction of the discharge portion. 8. The method of claim 7,
The guide wing portion is a hair dryer, characterized in that provided to be spaced apart from the inner peripheral surface of the case. 9. The method of claim 8,
The guide hub is
a guide hub body from which the guide blades protrude; and
Including; a guide hub cap extending in the direction of the impeller from one surface of the guide hub body adjacent to the impeller;
The guide hub cap is
A hair dryer comprising a third surface facing the impeller and a fourth surface extending from an outer circumferential surface of the third surface toward the guide hub body. 10. The method of claim 9,
The guide hub cap is
Hair dryer, characterized in that the cross-sectional area increases from the third surface toward the guide hub body. 11. The method of claim 10,
A hair dryer, characterized in that the diameter of the third surface is greater than or equal to the diameter of the hub body. 8. The method of claim 7,
The wing portion is provided inclined with respect to the axial direction of the rotation shaft,
The guide wing portion is a hair dryer, characterized in that provided to be inclined in the opposite direction to the wing portion with respect to the axial direction of the rotation shaft. The method of claim 1,
A hair dryer comprising a main bearing coupled to the rotation shaft and disposed between the impeller and the driving unit to rotatably support the rotation shaft. 14. The method of claim 13,
The main bearing part is a hair dryer, characterized in that provided in contact with the stator and the guide part. 15. The method of claim 14,
an auxiliary bearing unit coupled to one end of the rotating shaft in the direction of the discharge unit to rotatably support the rotating shaft; and
and a bracket for accommodating the auxiliary bearing unit and coupled to the guide unit. 16. The method of claim 15,
The bracket is
an accommodating part having an accommodating space for accommodating the auxiliary bearing part; and
A hair dryer comprising a; leg portion protruding from the outer peripheral surface of the receiving portion overlapping the guide portion. 17. The method of claim 16,
the leg part
a first leg protruding from the receiving part in a radial direction of the rotation shaft; and
and a second leg protruding from an end of the first leg in the axial direction of the rotation shaft and coupled to the guide part.

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