JP5103498B2 - Mist generator and beauty device - Google Patents

Description

  The present invention relates to a mist generating device and a beauty device including the mist generating device.

  Conventionally, mist generators have been designed to moisturize the skin by releasing warm mist generated by boiling liquid with a heater or atomizing with ultrasonic waves toward the human body such as the face. It is used as a device intended for effects and skin care. In such a mist generating device, it is known that a relatively low temperature liquid supplied from a storage tank directly touches the heater, thereby reducing the surface temperature of the heater and reducing the amount of generated warm mist. To solve such problems, a preheating mechanism for preliminarily heating the liquid supplied from the storage tank is provided, and mist is generated after being mixed with a relatively high temperature liquid heated by the preheating mechanism and then supplied to the boiling chamber. An apparatus has been proposed (for example, Patent Document 1).

  In the mist generator of Patent Document 1, the liquid is preheated by circulating the relatively high temperature liquid flowing out from the boiling chamber, or by arranging the pipe so as to face the heat radiation surface of the heater. The liquid supplied from the storage tank is mixed and supplied to the boiling chamber. For this reason, in the mist generating apparatus of patent document 1, it prevents that the comparatively low temperature liquid stored by the storage tank is supplied to a boiling chamber as it is, and the fall of the amount of warm mist generation accompanying the fall of the surface temperature of a heater is carried out. Can be suppressed.

JP 2007-260058 A

  However, in the mist generating apparatus of Patent Document 1, the supply path for supplying liquid from the storage tank to the boiling chamber is disposed substantially horizontally, and the supply path for supplying preheated liquid to the supply path is provided. The structure which connects from the top is adopted. For this reason, in the mist generator of patent document 1, mixing with the liquid supplied from a storage tank and the preheated liquid whose specific gravity is light compared with the liquid supplied from this storage tank is not fully performed. there is a possibility. Therefore, in the mist generator of Patent Document 1, the surface temperature of the heater is lowered by supplying a relatively low temperature liquid to the boiling chamber without being sufficiently mixed, and the amount of generated warm mist is reduced. There was a fear.

  This invention was made in order to solve the problem which exists in the said prior art, The objective is to provide the mist generator and beauty apparatus which can suppress that the generation amount of warm mist falls. is there.

In order to solve the above problems, the first invention includes a storage tank capable of storing a liquid, a heating unit that heats the supplied liquid to generate a warm mist, and a warm mist generated by the heating unit. In the mist generating apparatus having a mist discharge port for discharging, a reflux path for refluxing the liquid that has been preheated by the heating unit and then flows into the mist path to the mist discharge port, and is refluxed through the reflux path. comprising a liquid and a reservoir for storing the liquid mixture obtained by mixing the liquid supplied from the storage tank, a mixing promoting means for promoting mixing of the liquid mixture, wherein the mixing acceleration means, said reservoir Is a partition wall that divides a part of the mixed liquid into two regions, and in one of the two regions, a mixed liquid supply unit that communicates with the heating unit and supplies the mixed liquid to the heating unit is provided. When it is provided To, the other region of said two regions is characterized in that the stored liquid supply unit which the liquid is supplied from the communicated with in storage tank to the reservoir tank.

The second invention is characterized in that, in the first invention, the partition wall is provided with a liquid passing portion through which the liquid can pass.
In a third aspect based on the second aspect , the liquid passage section is located at a position where the length of the liquid path from the stored liquid supply section to the mixed liquid supply section via the liquid passage section is the longest. It is characterized by being provided.

According to a fourth invention, in any one of the first to third inventions, the reflux path is connected to a lower portion of the storage section.
According to a fifth invention, in any one of the first to fourth inventions, the invention further includes a tank preheating mechanism for preheating the liquid stored in the storage tank.

According to a sixth aspect , in any one of the first to fifth aspects, the liquid in the supply path is preheated to the supply path for supplying the liquid from the storage tank to the mixed liquid supply unit. A path preheating mechanism is further provided.

A seventh aspect of the present invention is a cosmetic apparatus for cleaning the skin surface by releasing mist, wherein the cosmetic apparatus includes the mist generating apparatus according to any one of the first to sixth aspects. Yes.

  ADVANTAGE OF THE INVENTION According to this invention, the mist generator and beauty apparatus which can suppress that the generation amount of warm mist falls can be provided.

(A), (b) is a perspective view which shows a cosmetics device. The AA partial fragmentary sectional view shown in FIG.1 (b). The schematic diagram which shows the piping structure of a cosmetics device. The perspective view of a path | route formation member. (A) is a top view of a heating mechanism part, (b) is the BB partial sectional view of (a). CC sectional view taken on the line shown to Fig.5 (a). Sectional drawing which shows the path | route formation member in a modification.

  Hereinafter, embodiments in which the present invention is embodied in a cosmetic device will be described with reference to the drawings. In the following description, “front (front)”, “rear”, “upper”, “lower”, “left”, and “right” indicate that the user of the cosmetic device is suitable for the cosmetic device when using the cosmetic device. “Front (front)”, “Rear”, “Up”, “Down”, “Left”, and “Right” are shown.

  FIG. 1 shows a cosmetic device 10 as a cosmetic device including the mist generating device of the present embodiment. As shown in FIG. 1, a cosmetic body 12 is accommodated and fixed in a bottomed substantially cylindrical main body case 11. In the cosmetic device body 12, an opening 13 b that opens upward is formed in the front center portion of the upper surface 13 a of the upper housing 13. A base member 16 that forms a recess 15 in alignment with the opening 13b is assembled to the upper housing 13.

  Warm mist is discharged to the base member 16 via a support shaft (not shown) so as to be rotatable in the arrow Ya direction (vertical direction) at a predetermined angle (for example, 25 to 55 °) with respect to the cosmetic body 12. A mist nozzle 20 (injecting) is attached. The mist nozzle 20 is configured by integrally forming a nozzle cover 22 formed so as to cover the periphery of a mist discharge port 21 for discharging a warm mist. In the present embodiment, by rotating the mist nozzle 20 in the vertical direction, the discharge direction of the warm mist discharged from the mist discharge port 21 can be adjusted in the vertical direction.

  In the nozzle cover 22, a mist guide 23 that is substantially U-shaped as viewed from the end is erected so as to extend in the normal direction of the outer surface of the nozzle cover 22 below the mist discharge port 21. The mist guide 23 is formed so as to surround the lower side and the left and right sides of the mist discharge port 21, and prevents the user's fingers from approaching the mist nozzle 20 from the left and right directions and the lower direction. . At a position corresponding to the lower end of the mist discharge port 21 at the base end portion of the mist guide 23, an escape hole 23a penetrating the mist guide 23 in the vertical direction is provided, and the liquid condensed at the upper portion of the mist guide 23 (Water etc.) will not stay. As shown in FIG. 2, the mist nozzle 20 is restricted from rotating downward by the mist nozzle 20 (the lower surface of the mist guide 23) coming into contact with the restriction portion 25 formed on the base member 16. Yes.

  Further, as shown in FIG. 1, a nozzle guard 26 for protecting the mist nozzle 20 is attached to the base member 16 so as to be rotatable in the vertical direction (indicated by an arrow Yb) behind the mist nozzle 20. Yes. The nozzle guard 26 is configured to be rotatable in the vertical direction between a closed position (shown in FIG. 1A) covering the mist nozzle 20 and an open position of the nozzle guard 26 (shown in FIG. 1B). Has been.

  As shown in FIGS. 1 and 2, the nozzle guard 26 is formed in a substantially semicircular flat plate shape, and the left and right base end portions 26 a are rotatably supported with respect to the base member 16. It is fixed to the axis Z (shown in FIG. 2). A front rib 26b having a substantially U-shape in plan view is suspended downward from the lower surface at substantially the center of the lower surface of the nozzle guard 26. The front rib 26b is disposed inside the mist guide 23 so as to cover the front of the mist nozzle 20 (mist discharge port 21) when the nozzle guard 26 is in the closed position (closed state). . In addition, on the lower surface of the nozzle guard 26, a pair of side ribs 26c extending in the front-rear direction are suspended from the lower surface on the left and right sides of the front rib 26b. The side ribs 26c are disposed so as to cover the left and right sides of the mist guide 23 when the nozzle guard 26 is closed. That is, in a state where the nozzle guard 26 is located at the closed position, the mist nozzle 20 (mist discharge port 21) is covered with the front rib 26b at the front and the side ribs 26c and the mist guide 23 at the left and right sides. It is supposed to be covered. For this reason, in this embodiment, when the nozzle guard 26 is set to the closed position, the warm mist discharged from the mist nozzle 20 (mist discharge port 21) is not discharged forward and sideward.

  An exhaust passage 26d formed in a concave shape extending rearward from the front rib 26b is formed on the lower surface of the nozzle guard 26. An exhaust port 26e that connects the lower surface and the upper surface of the nozzle guard 26 is formed on the base end side of the nozzle guard 26 in the exhaust passage 26d. In other words, in the present embodiment, the exhaust port 26e is formed behind the nozzle guard 26 that is farthest from the user in the nozzle guard 26. In this embodiment, when the nozzle guard 26 is in the closed position, the warm mist blocked by the ribs 26b and 26c passes through the exhaust passage 26d and is discharged upward from the exhaust port 26e. .

  As shown in FIG. 2, the nozzle guard 26 is connected to the mist nozzle 20 by a link member 30 that is integrally formed so that the center line of the flat plate member intersects at a predetermined angle (bending angle D). The bending angle D of the link member is set to an obtuse angle (132 ° in this embodiment). The link member 30 is rotatable about a first link base 31 fixed to the rotary shaft Z and rotated integrally with the nozzle guard 26 and a second link base 32 formed on the mist nozzle 20. It is assembled.

  With such a configuration, in the second movable range H2 shown in FIG. 2, the mist nozzle 20 (the lower surface of the mist guide 23) is restricted even if the nozzle guard 26 is rotated. The state in contact with the portion 25 is maintained. That is, the nozzle guard 26 is configured to be operable independently of the mist nozzle 20 in the second movable range H2.

  On the other hand, in the first movable range H <b> 1 shown in FIG. 2, the mist nozzle 20 (nozzle cover 22) rotates in the vertical direction about the central axis X as the rotation center in conjunction with the rotation operation of the nozzle guard 26. Therefore, in the first movable range H1, the discharge direction of the warm mist from the mist nozzle 20 (mist discharge port 21) can be adjusted by rotating the nozzle guard 26. In the first movable range H1, the nozzle guard 26 is configured to be able to maintain (hold) the rotational position without applying external force by a biasing means (not shown), and the adjusted mist nozzle 20 Can be maintained (maintained). Further, in the first movable range H1, the nozzle guard 26 maintains a position where the nozzle guard 26 is disposed above the mist nozzle 20 and the discharge of the warm mist is not blocked by the nozzle guard 26. ing. Thus, the nozzle guard 26 of the present embodiment has a function as a lid member that covers the mist nozzle 20 (mist discharge port 21) when the cosmetic device 10 is not used. Further, the nozzle guard 26 functions as a protective device that protects the user by restricting the user's fingers from approaching the mist nozzle 20 (mist discharge port 21) when the cosmetic device 10 is used.

  Further, as shown in FIG. 1, a predetermined amount (in this embodiment) of liquid (in this embodiment, water) used to generate warm mist discharged from the mist nozzle 20 is provided on the rear side of the nozzle guard 26. In the embodiment, a water supply tank 33 as a storage tank to be stored is installed in a state where it is accommodated in the cosmetic body 12. The water supply tank 33 is accommodated so that it can be inserted into and removed from the cosmetic device body 12 in the vertical (vertical) direction.

  On the upper surface 13 a of the upper housing 13, a power button 35 that is operated when turning on / off the cosmetic device 10 is provided on the left front side of the mist nozzle 20 (nozzle guard 26). In addition, on the upper surface 13 a of the upper housing 13, a mode switching button 36 that is operated when selecting one operation mode from among a plurality of operation modes of the cosmetic device 10 prepared in front of the mist nozzle 20 is provided. Is provided. In addition, on the upper surface 13a of the upper housing 13, when the operation of the beauty machine 10 is started in the operation mode selected by the operation of the mode switching button 36 so as to be aligned with the mode switching button 36 in the front-rear direction, the operation is stopped. An operation control button 37 that is operated when the operation is performed is provided.

  On the front side of the cosmetic device 10 (main body case 11), at the approximate center in the vertical direction, charged fine particle mist (charged fine particle liquid) generated by atomizing the liquid with an electrostatic atomizer 38a (shown by a dotted line). The charged fine particle mist discharge port 38 is provided for discharging the.

  Next, the piping configuration (internal structure) of the beauty machine main body 12 (beauty machine 10) of this embodiment will be described with reference to FIG. In addition, the water surface W shown in FIG. 3 is kept substantially constant.

  The beauty machine body 12 is provided with a tank holder 33a that opens to the upper surface 13a of the beauty machine body 12 (upper housing 13) and can store the water supply tank 33 therein. An air vent hole 33b is formed in the tank holder 33a. The tank holder 33a has an overflow hole 33c. When the water level in the tank holder 33a rises to the position where the overflow hole 33c is formed, the water in the tank holder 33a is discharged to the outside of the tank holder 33a. It is supposed to be. The lower end of the tank holder 33a is connected to the upstream end of a water supply pipe P1 formed of an elastic material having heat resistance (for example, silicon rubber or fluorine rubber), and the downstream end of the water supply pipe P1. Is connected to the heating mechanism 40. The water supply pipe P <b> 1 forms a water supply path K <b> 1 for supplying water from the water supply tank 33 to the heating mechanism unit 40. Further, the water supply pipe P1 is branched halfway and connected to the air vent hole 33b. For this reason, in this embodiment, the air (air bubbles) in the water supply pipe P1 is discharged to the tank holder 33a through the air vent hole 33b.

  The heating mechanism section 40 of the present embodiment is made of a heat-resistant material (heat-resistant resin, metal, etc.), a path forming member 41 for forming a liquid and warm mist path, and the liquid is heated to generate the warm mist. And a warm mist heater 42 to be generated. As shown in FIGS. 4-6, the path | route formation member 41 forms the boiling chamber 42a as a heating part with this warm mist heater 42 by the storage part 43 and the warm mist heater 42 which can store water being assembled | attached. The chamber forming portion 45 and the lower temperature mist guiding portion 46 for guiding the warm mist generated in the boiling chamber 42a upward (mist nozzle 20) are provided. Details will be described below.

  As shown in FIGS. 3 and 4, the path forming member 41 is provided with a substantially cylindrical connecting portion 43a to which the water supply pipe P1 is connected, and the connecting portion 43a is provided along the vertical direction. An extending bottomed substantially cylindrical storage portion 43 is continuously provided so as to extend upward. An inflow hole 43c is formed in the bottom surface 43b of the storage portion 43 as a stored liquid supply portion that communicates with the inside of the connection portion 43a. Therefore, the water stored in the water supply tank 33 flows into the storage part 43 from the water supply pipe P1 through the inflow hole 43c.

  As shown in FIGS. 5 and 6, the inner bottom portion of the storage portion 43 is erected upward from the bottom surface 43 b of the storage portion 43, and the inner bottom portion of the storage portion 43 is connected to the inflow side region Ra and the outflow side. A partition wall 47 is provided as a partition wall that is equally divided into two regions Rb. The partition wall 47 partitions the internal space of the storage portion 43 so as to have an equal volume within the range of the height of the partition wall 47. The inflow hole 43c described above opens to the inflow side region Ra. In the present embodiment, the cross-sectional area along the horizontal direction of the reservoir 43 (diameter 12 mm in this embodiment) is greater than the cross-sectional area in the direction perpendicular to the center line of the inflow hole 43c (diameter 6 mm in this embodiment). It is set large. With this configuration, in the present embodiment, it is possible to secure a space for forming the partition wall 47 and to increase the amount of water that can be stored in the storage portion 43.

  As shown in FIG. 5A, the partition wall 47 is formed along the diameter direction of the storage portion 43 in plan view and is connected to the inner wall surface of the storage portion 43 at two points. Moreover, the length dimension (height) along the up-down direction of the partition wall 47 is set shorter than the length along the up-down direction of the storage part 43 (in this embodiment, about 1/2). In addition, the length along the vertical direction of the partition wall 47 is set to a length that does not protrude upward from the water surface W in the storage portion 43 (length that is submerged in the storage portion 43).

  Further, as shown in FIG. 5, the upper end portion of the partition wall 47, which is in contact with the inner wall surface of the storage portion 43, is substantially lowered from above to be in contact with the inner wall surface of the storage portion 43. A liquid passing portion 47a formed by cutting out into a square is provided. The liquid passing portion 47a can also be grasped as a part where the length (height) along the vertical direction of the partition wall 47 is set to be partially small (low). For example, when the partition wall 47 of the present embodiment is set to a height of 10 mm, the liquid passing portion 47a sets the length along the vertical direction to 5 mm and the width to 3 mm.

  In the direction perpendicular to the direction in which the connection portion 43a extends at the outer bottom portion of the storage portion 43, a cylindrical communication portion 48 is formed that faces the partition wall 47 and extends in a direction perpendicular to the direction in which the connection portion 43a extends. Has been. The communication part 48 forms an outflow hole 43e as a mixed liquid supply part for supplying water in the storage part 43 to the boiling chamber 42a. In the outflow side region Rb of the reservoir 43, an outflow hole 43e is opened so as to communicate with the boiling chamber 42a. For this reason, the partition wall 47 is interposed between the inflow hole 43c and the outflow hole 43e. Further, as shown in FIG. 5, the liquid passage portion 47 a of the partition wall 47 is the upper end portion of the partition wall 47 and is formed at a position farthest from the inflow hole 43 c and the outflow hole 43 e. That is, the liquid passage portion 47a of the present embodiment is formed at a position where the distance of the liquid path from the inflow hole 43c to the outflow hole 43e via the liquid passage portion 47a is the longest.

  As shown in FIGS. 3, 5, and 6, the communication portion 48 is provided with a lower portion of a substantially flat boiling chamber forming portion 45 extending in the vertical direction. A thin plate-like boiling chamber 42 a extending in the vertical direction is formed on the surface of the boiling chamber forming portion 45 opposite to the storage portion 43. An outflow hole 43e is opened at the bottom of the boiling chamber 42a. The boiling chamber forming portion 45 is assembled with a warm mist heater 42 having a substantially rectangular shape corresponding to the boiling chamber 42a. The temperature mist heater 42 is made of, for example, a PTC (positive temperature coefficient) element.

  A temperature sensor SE is disposed at the outer lower end of the warm mist heater 42. A boiler felt 49 is disposed in the boiling chamber 42a of the boiling chamber forming section 45 so as to cover the entire bottom surface of the boiling chamber 42a and to be in contact with the heating surface 42b of the warm mist heater 42. Note that the saturated water absorption amount of the boiler felt 49 is set to be larger than the amount of water (condensed water or the like) that may flow down the wall surface of the boiling chamber 42a after the use of the cosmetic device 10.

  In the upper part of the boiling chamber forming part 45, a lower warm mist guiding part 46 formed in a flat bottomed substantially cylindrical shape is connected to the surface on the storage part 43 side. The upper part of the boiling chamber 42 a of the boiling chamber forming part 45 is communicated with the side face part 46 a of the lower temperature mist guiding part 46. In addition, the bottom 46 b of the lower temperature mist guiding portion 46 is open to the inside of the storage portion 43 provided continuously to the lower portion of the lower temperature mist guiding portion 46, and the inside of the lower temperature mist guiding portion 46 and the storage portion 43. Is connected to the inside. The lower temperature mist guiding section 46 forms a lower temperature mist path M1 that guides the temperature mist upward (mist nozzle 20).

  Thus, in the heating mechanism unit 40 of the present embodiment, the storage unit 43, the communication unit 48 (outflow hole 43e), the boiling chamber forming unit 45 (boiling chamber 42a), and the lower temperature mist guiding unit 46 (lower temperature mist path). A square annular conduit is formed by M1).

  At the upper end portion of the lower temperature mist guiding portion 46, a discharging portion that guides the warm mist that has passed through the lower temperature mist guiding portion 46 further upward (mist nozzle 20) and refines (ionizes) the warm mist by high-pressure discharge. An upper temperature mist guiding member 51 having 50 is continuously provided. At the lower part of the upper temperature mist guiding member 51 (upper part of the lower temperature mist guiding part 46), the bottom part of the upper temperature mist guiding member 51 is formed, and the bottom part of the lower temperature mist guiding part 46 and the upper temperature mist guiding member 51 A prevention wall 53 that forms a step (step structure) with the bottom is provided. The prevention wall 53 prevents the relatively high temperature water splashing from the boiling chamber 42a from directly entering the upper part (the mist nozzle 20 side) from the lower temperature mist guiding part 46. For this reason, in this embodiment, it is suppressed that the comparatively high temperature water scattered from the boiling chamber 42a is discharge | released from the mist nozzle 20. FIG.

  A discharge part 50 is provided above the prevention wall 53 in the upper temperature mist guiding member 51. The discharge unit 50 includes a pair of discharge needles 50a to which a high voltage is applied, and an intermediate electrode unit 50b disposed between the discharge needles 50a. In the discharge part 50, a warm mist is refined | miniaturized by the high voltage | pressure discharge from each discharge needle 50a.

  An upper end (lower end) of a bellows member 55 made of an elastic material having heat resistance (for example, silicon rubber or fluororubber) and formed in a bellows shape is connected and fixed to the upper end of the upper warm mist guide member 51. Yes. The downstream end (upper end) of the bellows member 55 is connected and fixed to a nozzle holder 56 formed in a substantially cylindrical shape. The nozzle holder 56 is connected and fixed to a substantially annular nozzle packing 57 fixed inside the mist nozzle 20 (nozzle cover 22) and around the mist discharge port 21. In the present embodiment, an upper mist path M <b> 2 that guides the warm mist generated by the warm mist heater 42 to the mist discharge port 21 is formed by the upper warm mist guiding member 51 and the bellows member 55.

  In the present embodiment, the water supply tank 33, the tank holder 33a, and the water supply pipe P1 constitute a water supply mechanism, and the upper temperature mist guide member 51, the bellows member 55, and the mist nozzle 20 (mist discharge port 21) serve as the mist discharge mechanism. It is composed. And in this embodiment, the heating mechanism part 40 and the mist discharge | release mechanism part comprise the mist generating mechanism 59 as a mist generating means.

Next, the electrical configuration of the cosmetic device 10 of the present embodiment will be described.
As shown in FIG. 1, the beauty machine main body 12 is provided with a control board 58 for controlling the operation of the beauty machine 10. A warm mist heater 42, an electrostatic atomizer 38a, and a discharge unit 50 are electrically connected to the control board 58. In addition, a power button 35, a mode switching button 36, and an operation control button 37 are electrically connected to the control board 58. A temperature sensor SE is connected to the control board 58.

  When the power is turned on by depressing the power button 35, the control board 58 of the present embodiment initially sets a “charged particle mode” for discharging charged particle mist from the charged particle mist discharge port 38 as an initial operation mode. The control board 58 releases the “charged particle mode” and the warm mist from the mist nozzle 20 (mist discharge port 21) every time an operation signal output when the mode switching button 36 is pressed is input. Switch to “Warm Mist Mode”.

  When the charged fine particle mode is set, the control substrate 58 controls the electrostatic atomizer 38a to generate charged fine particle mist when an operation signal output when the operation control button 37 is pressed is input. Then, it is discharged from the charged fine particle mist discharge port 38. In addition, when the control board 58 of the present embodiment is set to the “warm mist mode”, when an operation signal is input from the operation control button 37, energization of the warm mist heater 42 and the discharge unit 50 is started and the warm mist is generated. At the same time, the warm mist is discharged from the mist nozzle 20 (mist discharge port 21). In addition, when the surface temperature of the warm mist heater 42 measured by the temperature sensor SE reaches a predetermined temperature (for example, 128 ° C.), the control board 58 stops energization of the warm mist heater 42 to prevent emptying. ing.

Next, the effect of the cosmetic device 10 of this embodiment is demonstrated.
As shown in FIG. 3, the water supplied from the water supply tank 33 (tank holder 33 a) passes through the water supply pipe P <b> 1 (water supply path K <b> 1) and passes through the inflow hole 43 c (connection portion 43 a), and enters the inflow side of the storage portion 43. It flows into the region Ra (indicated by arrows Yc and Yd). The water supplied from the inflow hole 43c to the reservoir 43 (inflow side region Ra) is relatively low temperature (room temperature) water.

  The water supplied to the inflow side region Ra from the inflow hole 43 c moves upward along the partition wall 47 and is mixed with the water stored in the storage unit 43. And in this embodiment, after the water newly supplied from the water supply tank 33 and the water already stored in the storage part 43 are mixed, this mixed water passes the outflow side area | region Rb. It passes through the outflow hole 43e and is supplied to the boiling chamber 42a (indicated by an arrow Ye). In this embodiment, the water mixed in the storage part 43 becomes a mixed liquid.

  The water supplied to the boiling chamber 42a is heated by the warm mist heater 42 and is also warmed (vaporized). The warm mist (water vapor) generated in the boiling chamber 42a is temporarily housed in the lower warm mist guiding section 46 (lower warm mist path M1) and is guided upward where the mist nozzle 20 is disposed. (Shown by arrow Yf).

  In addition, water that has dewed in the lower temperature mist guiding section 46 (lower temperature mist path M1) or water that has been scattered as the water has boiled in the boiling chamber 42a has a relatively high temperature (about 80 to 100 ° C.). The water is refluxed from the lower temperature mist guiding part 46 to the storage part 43 (indicated by an arrow Yg). Therefore, in this embodiment, the lower temperature mist induction | guidance | derivation part 46 comprises a reflux path and a heating liquid supply part. During the generation of warm mist (during heating by the warm mist heater 42), hot water is constantly supplied to the reservoir 43 as compared to the water in the water supply tank 33, the tank holder 33a, and the water supply pipe P1. Become. For this reason, the water stored in the storage part 43 becomes high temperature compared with the water newly supplied from the water supply tank 33 via the inflow hole 43c.

  As in the present embodiment, a configuration is adopted in which relatively high temperature water is recirculated from above the storage portion 43 extending in the vertical direction, while relatively low temperature water is supplied from the water supply tank 33 from below the storage portion 43. In such a case, there is a problem that mixing by natural convection is difficult to be performed due to a specific gravity difference due to a temperature difference of water. However, in this embodiment, by providing the partition wall 47 at the inner bottom portion of the storage portion 43, the relatively low temperature water supplied from the water supply tank 33 is forcibly moved upward and stored in the storage portion 43. It promotes mixing with relatively hot water. Thus, in this embodiment, the partition wall 47 comprises a mixing promotion means.

  Moreover, in this embodiment, the water supplied to the boiling chamber 42a from the storage part 43 (outflow side area | region Rb) via the outflow hole 43e is the relatively low temperature water supplied from the water supply tank 33, and lower temperature mist. It becomes the water mixed with the relatively high temperature water refluxed from the induction part 46. That is, in the present embodiment, water having a temperature higher than that of the water supplied from the water supply tank 33 can be supplied from the reservoir 43 (outflow side region Rb) to the boiling chamber 42a. Therefore, in this embodiment, the relatively low temperature water supplied from the water supply tank 33 is prevented from being supplied to the boiling chamber 42a as it is.

  The warm mist guided upward by the lower warm mist guiding portion 46 passes through the side of the prevention wall 53 and is refined by high-pressure discharge by the discharge portion 50. The refined warm mist passes through the bellows member 55 and the nozzle holder 56 and is discharged from the mist nozzle 20 (mist discharge port 21) (indicated by an arrow Yh).

Therefore, according to the present embodiment, the following effects can be obtained.
(1) A partition wall 47 is provided at the inner lower portion of the reservoir 43 through which relatively high temperature water is circulated from the lower temperature mist guiding section 46, and the relatively low temperature water supplied from the water supply tank 33 is forced upward. It was made to move and to promote mixing with the relatively high temperature water stored in the storage part 43. For this reason, the relatively low temperature water supplied from the water supply tank 33 and the relatively high temperature water in the reservoir 43 are supplied to the boiling chamber 42a without being sufficiently mixed, so that the heating surface 42b of the warm mist heater 42 It can suppress that temperature falls and the generation amount of warm mist falls.

  (2) From the lower temperature mist guiding portion 46, relatively high-temperature dew condensation water or water scattered from the boiling chamber 42a is returned to the storage portion 43. For this reason, the relatively high-temperature water that has been refluxed and the relatively low-temperature water supplied from the water supply tank 33 can be mixed before being supplied to the boiling chamber 42a. Therefore, by supplying relatively low temperature water to the boiling chamber 42a, it is possible to suppress the temperature of the heating surface 42b of the warm mist heater 42 from being lowered and the generation amount of warm mist from being lowered. In addition, the configuration of the cosmetic device 10 can be simplified as compared with a case where a mechanism for generating relatively high temperature water for mixing with the water supplied from the water supply tank 33 is separately provided.

  (3) In the internal space of the storage unit 43, the relatively high temperature water returned from the lower temperature mist guiding unit 46 and the relatively low temperature water supplied from the water supply tank 33 are mixed, and then the outlet hole 43e is formed. Then, water is supplied to the boiling chamber 42a. For this reason, compared with the case where the piping for water recirculated from the lower temperature mist guiding portion 46 and the water supply pipe P1 are simply connected, the water recirculated from the lower temperature mist guiding portion 46 and the water supply tank 33 are supplied. It is possible to more reliably perform mixing with the water.

  (4) The partition wall 47 is interposed between the inflow hole 43c and the outflow hole 43e at the inner bottom of the storage unit 43. For this reason, the relatively low temperature water from the water supply tank 33 that has flowed in via the inflow hole 43c is supplied from the outflow hole 43e to the boiling chamber 42a without being sufficiently mixed with the relatively high temperature water in the reservoir 43. Can be suppressed.

  (5) The partition wall 47 is provided to divide the inner bottom of the storage portion 43 into two regions, and the inflow hole 43c is provided in the inflow region Ra, while the outflow hole 43e is provided in the outflow region Rb. For this reason, the relatively low temperature water supplied from the water supply tank 33 cannot flow into the outflow hole 43e (outflow side region Rb) unless it passes over the partition wall 47. Therefore, the mixing of the relatively low temperature water supplied from the water supply tank 33 and the relatively high temperature water stored in the storage unit 43 can be further promoted.

  (6) The partition wall 47 is provided with a liquid passage portion 47a. For this reason, even if the water surface W is lowered to a position lower than the height of the partition wall 47, it becomes possible to supply water from the inflow side region Ra to the outflow side region Rb via the liquid passing portion 47a. It is possible to prevent the water in the boiling chamber 42a from running out.

  (7) The liquid passage portion 47a of the partition wall 47 is formed at a position where the distance of the liquid path from the inflow hole 43c through the liquid passage portion 47a to the outflow hole 43e is the longest. For this reason, mixing of the relatively low temperature water supplied from the water supply tank 33 and the relatively high temperature water stored in the storage unit 43 can be further promoted.

In addition, you may change the said embodiment as follows.
In the above embodiment, a reflux unit 60 that refluxes relatively high temperature water from the lower temperature mist guiding unit 46 may be provided separately. In this case, for example, as shown in FIG. 7, an inflow hole 43 c into which water from the water supply tank 33 flows is formed in the upper portion of the storage portion 43, while the lower temperature mist guiding portion 46 is formed in the lower portion of the storage portion 43. A cylindrical reflux section 60 for refluxing relatively high-temperature water is connected. And in the storage part 43, what is necessary is just to form the outflow hole 43e between the inflow hole 43c and the connection part of the recirculation | reflux part 60. FIG. According to such a configuration, by mixing relatively high-temperature water from below the reservoir 43, mixing of the relatively low-temperature water supplied from the water supply tank 33 and the refluxed relatively high-temperature water. Can be promoted by natural convection in the reservoir 43. Therefore, according to this modification, it can suppress that the temperature of the heating surface 42b of the warm mist heater 42 falls, and the generation amount of warm mist falls by supplying comparatively low temperature water to the boiling chamber 42a. . In this modification, a reflux path 60 a is formed by the lower temperature mist guiding portion 46 and the reflux portion 60. Moreover, in this modification, the storage part 43 comprises a mixing promotion means.

  In the above embodiment, as shown in FIG. 3, a preheating heater 61 as a tank preheating mechanism is disposed around the tank holder 33a, and water in the water supply tank 33 and the tank holder 33a is preheated. It may be. According to such a configuration, the temperature of the water supplied from the water supply tank 33 can be set high, and the temperature of the heating surface 42b of the warm mist heater 42 is obtained by supplying low temperature water to the boiling chamber 42a. It can suppress more reliably that fall and the generation amount of warm mist fall.

  In the above embodiment, as shown in FIG. 3, a preheating heater 62 as a path preheating mechanism is disposed around the water supply pipe P1, and the water passing through the water supply pipe P1 (water supply path K1) is preheated. You may make it do. According to such a structure, it can suppress more reliably that the temperature of the heating surface 42b of the warm mist heater 42 falls, and the generation amount of warm mist falls. In this modification, in addition to the preheating heater 62 of the water supply pipe P1, a preheating heater 61 may be provided around the tank holder 33a.

  In the above embodiment, as indicated by a two-dot chain line in FIGS. 4 and 6, a slit 43 d that extends upward from the outer bottom of the storage portion 43 may be formed so as to correspond to the partition wall 47. That is, the partition wall 47 may be formed to have a hollow structure.

  In the above-described embodiment, the storage unit 43 may be disposed along the heat radiation surface opposite to the heating surface 42 b of the warm mist heater 42. According to such a structure, it can suppress that the temperature of the water in the storage part 43 falls using the heat | fever from the warm mist heater 42. FIG.

-In the said embodiment, you may provide the heater for heating and / or heat-retaining the water in the storage part 43 separately.
In the above embodiment, the position of the liquid passage portion 47a may be changed as appropriate or further omitted. Even if comprised in this way, mixing of water can be accelerated | stimulated by the partition wall 47. FIG.

  In the above embodiment, the partition wall 47 may be provided with a single or a plurality of communication holes that connect the inflow side region Ra and the outflow side region Rb, or may be formed by a mesh-like member. Even if comprised in this way, while the partition wall 47 can suppress that water flows directly into the outflow hole 43e from the inflow hole 43c, mixing can be accelerated | stimulated.

  In the above embodiment, the partition wall 47 is formed in a straight line that passes through the center of the storage part 43 in plan view, but may be formed in other shapes. For example, it may be bent in a plan view or may be formed in a wavy shape.

  In the above embodiment, the partition wall 47 is formed so as to partition the inner bottom portion of the storage portion 43 into two regions, but may be partitioned into three or more regions. In this case, any one of the inflow hole 43c, the outflow hole 43e, and the reflux path 60a (the reflux part 60) is formed for each formed region.

  -In above-mentioned embodiment, although the partition wall 47 was comprised so that the inner bottom part of the storage part 43 might be divided equally, you may make it the volume of inflow side area | region Ra and outflow side area | region Rb differ. For example, when the volume of the inflow side region Ra is set to be small, the relatively low-temperature water supplied from the water supply tank 33 can be moved upward more vigorously, and the mixing of water can be promoted.

-In the said embodiment, you may provide the partition wall 47 so that it may incline.
-In above-mentioned embodiment, although the storage part 43, the communication part 48, the boiling chamber formation part 45, and the lower temperature mist induction | guidance | derivation part 46 were integrally formed, even if one or all of these are formed as an independent member, Good.

  In the above embodiment, the temperature mist heater 42 is used to generate water mist by boiling water (or other liquid is acceptable), but an apparatus or an electrostatic atomizer that mists liquid by ultrasonic vibration. You may produce | generate a warm mist using the apparatus etc. which make it mist using.

In the above embodiment, one mist nozzle 20 that discharges warm mist is provided, but two or more mist nozzles may be provided.
In the above embodiment, the electrostatic atomizer 38a and the charged fine particle mist discharge port 38 may be omitted.

  In the cosmetic device 10 of the above-described embodiment, in combination with the mist nozzle 20, a nozzle that discharges negative ions, positive ions, and the like, a nozzle that discharges chemicals such as a moisturizing agent and a whitening agent, and the like may be provided.

  In the above embodiment, a liquid containing a moisturizer or a whitening agent or a liquid containing a fragrance is stored in the water supply tank 33 as the liquid for generating the warm mist by heating with the warm mist heater 42. Good.

  DESCRIPTION OF SYMBOLS 10 ... Beauty device (mist generating apparatus, beauty apparatus), 21 ... Mist discharge port, 33 ... Water supply tank (storage tank), 42a ... Boiling chamber (heating part), 43 ... Storage part, 43c ... Inlet hole (reserved liquid supply) Part), 43e ... outflow hole (mixed liquid supply part), 46 ... lower temperature mist guiding part (reflux path, heated liquid supply part), 47 ... partition wall (mixing promoting means, partition wall), 47a ... liquid passing part, 59 ... Mist generation mechanism (mist generation means), 60a ... Recirculation path, 61 ... Preheating heater (tank preheating mechanism), 62 ... Preheating heater (path preheating mechanism), Ra ... Inflow side region, Rb ... Outflow side region.

Claims (7)

In a mist generating apparatus including a storage tank capable of storing liquid, a heating unit that heats the supplied liquid to generate warm mist, and a mist discharge port that discharges the warm mist generated in the heating unit,
A reflux path for refluxing liquid that has been preheated in the heating section and then flows into the mist path from the mist discharge port ;
A reservoir for storing the liquid mixture obtained by mixing the liquid supplied from the liquid and the reservoir tank was refluxed through the reflux passage,
Mixing promoting means for promoting mixing of the mixed liquid ,
The mixing promoting means is a partition wall that partitions a part of the storage section into two regions,
One of the two regions is provided with a mixed liquid supply unit that communicates with the heating unit and supplies the mixed liquid to the heating unit, and the other of the two regions. The area | region is provided with the storage liquid supply part which is connected to the said storage tank and the liquid is supplied from this storage tank, The mist generator characterized by the above-mentioned . The mist generating device according to claim 1 , wherein a liquid passing portion through which a liquid can pass is provided in the partition wall. The liquid passing part, claim 2, characterized in that provided from the stored liquid supply unit to the longest position the length of the liquid path up to the mixed liquid supply portion via the liquid passing part The mist generator described in 1. The return path, mist generating device according to any one of claims 1 to 3, characterized in that it is connected to the lower portion of the reservoir. The mist generator according to any one of claims 1 to 4 , further comprising a tank preheating mechanism that preheats the liquid stored in the storage tank. From said storage tank to the supply path for supplying liquid to the liquid mixture supply portion, of the claims 1 to 5, characterized in that a path preheating mechanism for heating the liquid in the supply path in advance further The mist generator as described in any one of Claims. In a beauty device that releases mist and cleans the skin surface,
A beauty device comprising the mist generating device according to any one of claims 1 to 6 .

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