JP5103499B2 - 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 moisturize the skin by releasing warm mist generated by boiling a liquid such as water with a heater or atomizing with ultrasonic waves toward the human body such as the face. It is used as a device for the purpose of beauty effects such as skin care. In such a mist generating apparatus, it has been proposed to provide a water supply tank for storing water and to discharge the water supplied from the water supply tank into a mist (for example, Patent Document 1).

  In the mist generator of Patent Document 1, a cap having a supply port for supplying water to the tank body of the storage tank is attached, and the cap is mounted on the tank holder in a state where the cap is disposed below. And in the mist generator of patent document 1, if the water stored in the apparatus of the mist generator reduces with generation | occurrence | production of mist, the water in a water supply tank will pass through the supply port inside the apparatus (mist etc. of heaters etc.). Generator).

JP 2007-260058 A

  However, in the mist generator of Patent Document 1, the cap and tank holder of the water supply tank are formed of a hydrophobic resin material (for example, polypropylene or polyethylene). For this reason, in the mist generator of patent document 1, water may become difficult to flow into the clearance gap between the cap and tank holder of a water supply tank by the effect | action of the surface tension of a liquid (water). For this reason, in the mist generating apparatus of patent document 1, a load arises in supply of the liquid (water) from the supply port of a cap by inhibiting the water surface rise in a tank holder, and the liquid with respect to mist generating parts, such as a heater, is produced. The supply of (water) could become unstable.

  The present invention has been made to solve the above-described problems in the prior art, and an object of the present invention is to provide a mist generating device and a beauty device that can suppress the supply of liquid to the mist generating unit from becoming unstable. It is to provide.

In order to solve the above-mentioned problem, the first invention includes a bottomed cylindrical main body case and an upper housing provided on the upper surface of the main body case, and a liquid supplied from a storage tank capable of storing the liquid In the mist generating apparatus that mists the mist generating mechanism and releases the mist from the mist discharge port , a tank holder that opens to the upper housing and can store the storage tank is provided in the main body case. The lower part is provided with a lid member which is formed in a bottomed cylindrical shape and has an opening for supplying liquid from the storage tank to the mist generating mechanism via the tank holder at the center of the bottom. The lid member has an annular shape that prevents the liquid surface in the tank holder from being hindered from rising when the liquid from the storage tank is supplied to the tank holder. And the rib covers the entire circumference so as to surround the opening, and the outer diameter dimension thereof is smaller than the outer diameter dimension of the bottom portion of the lid member. It is characterized in that the inner diameter dimension and the outer diameter dimension are reduced in the liquid supply direction from the opening .

The second invention is Oite to the first invention, the lid member and the rib is characterized in that it is formed of a material exhibiting hydrophilicity.

According to a third aspect of the present invention, there is provided a cosmetic device for cleaning the skin surface by releasing mist, characterized by comprising the mist generating device of the first or second aspect of the invention.

  ADVANTAGE OF THE INVENTION According to this invention, the mist generating apparatus and beauty apparatus which can suppress that the supply of the liquid with respect to a mist generating part becomes unstable 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 BB partial sectional view shown to Fig.1 (a). (A) is a left view of a water supply tank, (b) is CC sectional view taken on the line of (a). The partial expanded sectional view of a tank holder and a water supply tank. (A) And (b) is a schematic cross section which shows the water supply tank 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. . An escape hole 23 a that penetrates the mist guide 23 in the vertical direction is provided at a position corresponding to the base end of the mist guide 23 and below the mist discharge port 21. As shown in FIG. 2, the lower surface of the mist nozzle 20 (the lower surface of the mist guide 23) is in contact with a restricting portion 25 formed on the base member 16, so that downward rotation is restricted. .

  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 FIGS. In addition, the water surface W shown in FIG. 3 is kept substantially constant.

  As shown in FIG. 3, the entire body of the cosmetic device 12 is formed in a substantially cylindrical shape with a bottom, and opens to the upper surface 13 a of the cosmetic device body 12 (upper housing 13) and can store a water supply tank 33. A tank holder 33a is provided. The tank holder 33a is formed from a thermoplastic resin (in this embodiment, polyethylene). An air vent hole 33b is formed in the tank holder 33a. The tank holder 33a is provided with an overflow hole 33d. When the water level in the tank holder 33a rises to the position where the overflow hole 33d is formed, the water in the tank holder 33a is discharged to the outside of the tank holder 33a. It is supposed to be.

  Further, as shown in FIG. 4, a tank hook 27 for fixing the water supply tank 33 in the tank holder 33a is provided at a central portion along the vertical direction of the tank holder 33a. The tank hook 27 includes a substantially cylindrical hook holder 27b which is disposed so as to surround the hook hole 27a penetrating the side wall of the tank holder 33a and extends sideways. A proximal end portion of a spring 27c is fixed to the distal end portion of the hook holder 27b, and a hook member 27d that can move in the horizontal direction in the hook hole 27a and the hook holder 27b is connected to the distal end portion of the spring 27c. Has been. The hook member 27d is biased toward the tank holder 33a by a spring 27c.

  A water supply hole 33c penetrating in the vertical direction is formed at the bottom of the tank holder 33a. A connecting portion 29 having a bottomed substantially cylindrical shape extending in the vertical direction is connected to the lower portion of the tank holder 33a. A connecting portion 29a is provided at the lower portion of the connecting portion 29. The connecting portion 29a is connected to a water supply pipe P1 that is formed in a cylindrical shape that bends at right angles toward the side in a side view.

  On the bottom of the tank holder 33a, a water supply bar 28 having a round bar shape is supported so as to be movable in the vertical direction so as to penetrate the bottom of the tank holder 33a and the bottom of the connecting portion 29 in the vertical direction. The lower end of the water supply bar 28 protrudes downward from the bottom surface 12a (shown in FIG. 3) of the cosmetic body 12 and is biased downward by a spring 28a fixed to the bottom bottom surface of the tank holder 33a. Yes. Further, the water supply bar 28 is attached with a substantially conical water stop packing 29b that covers the opening of the connecting portion 29a at the connecting portion 29.

  With such a configuration, in this embodiment, in the state where the water supply bar 28 protrudes from the bottom surface 12a of the beauty device body 12, the water stop packing 29b is brought into close contact with the upper end portion of the connection portion 29a by the biasing force of the spring 28a. For this reason, in the state which the water supply bar 28 protruded from the bottom face 12a, watertightness is maintained between the water stop packing 29b and the upper end part of the connection part 29a.

  On the other hand, when the beauty device 10 is placed on a horizontal surface, the water supply bar 28 is pushed against the horizontal surface by the weight of the beauty device 10, so that the spring 28 a is biased so as to be housed inside the beauty device 10. Moves up against it. At this time, the water-stopping packing 29b is moved upward together with the water supply bar 28, and the watertight state between the water-stopping packing 29b and the upper end of the connecting portion 29a is released.

  The tank holder 33a accommodates the water supply tank 33 so that it can be inserted into and removed from the tank holder 33a in the vertical (vertical) direction. Here, the water supply tank 33 of this embodiment is demonstrated in detail.

As shown in FIG. 5, the water supply tank 33 of the present embodiment includes a tank body 34 and a cap 39 as a lid member that serves as a lid of the tank body 34.
The tank main body 34 has a substantially cylindrical shape with a lid by sealing the upper opening of a substantially cylindrical container main body 34a that opens in the vertical direction with a substantially flat sealing member 34b. The sealing member 34b is formed larger than the container main body 34a in plan view. For this reason, in this embodiment, it becomes easy to take out the water supply tank 33 from the tank holder 33a by hooking a finger on the sealing member 34b. Further, a screw 34c is formed on the lower outer peripheral surface of the tank main body 34, and a cap 39 having a screw (not shown) can be attached to the inner peripheral surface.

  The cap 39 is made of a thermoplastic resin (polypropylene in the present embodiment), and the entire cap 39 has a flat bottomed substantially cylindrical shape. In the cap 39, an opening 39b serving as a supply portion is formed in the center of the bottom 39a having a disk shape in plan view. Around the opening 39b, a water supply rib 40a is formed as an annular rib that continuously surrounds the entire opening 39b.

  The outer diameter dimension of the water supply rib 40a is set to be smaller (one half) than the outer diameter dimension of the bottom 39a (cap 39). Moreover, the height dimension along the up-down direction of the water supply rib 40a is set smaller than the outer diameter (diameter) dimension of the water supply rib 40a, and the water supply rib 40a has a flat annular shape as a whole. In this embodiment, the height dimension along the up-down direction of the water supply rib 40a is set to 5 mm. The lower end portion of the water supply rib 40a has an R shape with a semicircular sectional shape. In addition, the lower end part of the water supply rib 40a is arrange | positioned so that it may correspond to the water surface W set to the cosmetics device 10. FIG.

  Further, on the upper surface side of the bottom portion 39a, a cylindrical water supply portion 40 is erected so as to surround the opening portion 39b and extend upward. In the present embodiment, the inner peripheral surfaces of the water supply rib 40a, the opening 39b, and the water supply unit 40 are aligned and matched to form a single inner peripheral surface. A substantially conical cap packing 40b is disposed at the upper end opening of the water supply unit 40 so as to cover the upper end opening. A round bar-like cap pin 40c extending in the vertical direction is assembled to the cap packing 40b. The cap pin 40c is urged downward by a spring 40d, and the cap packing 40b is brought into close contact with the upper end portion of the water supply unit 40. For this reason, between the cap packing 40b and the upper end part of the water supply part 40, watertightness is maintained.

  A square packing 39 c is disposed on the upper surface side of the bottom 39 a of the cap 39 so as to surround the water supply unit 40. For this reason, in a state in which the cap 39 is attached to the tank main body 34, watertightness is maintained between the bottom 39 a of the cap 39 and the lower end (opening 34 d) of the tank main body 34. A plurality of ridges 39e extending in the vertical direction are formed on the outer peripheral surface of the cap 39. Further, on the side surface of the tank main body 34, a groove-shaped locking portion 34e for locking the above-described tank hook 27 (hook member 27d) is provided at a substantially central position along the vertical direction.

  As shown in FIGS. 3-5, the water supply tank 33 is accommodated (set) in the tank holder 33a so that it may be inserted in the state which has arrange | positioned the cap 39 below. Further, the water supply tank 33 is fixed in the tank holder 33a by the hook member 27d being locked to the locking portion 34e.

  Then, as shown in FIG. 6, when the water supply bar 28 is moved upward by an external force, the cap pin 40c is moved upward by the upper end portion of the water supply bar 28, and the watertightness between the water supply unit 40 and the cap packing 40b is increased. The state is to be released. And in this embodiment, the watertight state between the water supply part 40 and the cap packing 40b is cancelled | released, the inside of the water supply tank 33, the tank holder 33a, and the connection part 29 are connected, and water is supplied from the water supply tank 33. Can be supplied. In the present embodiment, a substantially annular water storage space S is formed between the tank holder 33a and the water supply rib 40a.

  As shown in FIG. 3, the upstream end of the water supply pipe P1 formed of an elastic material (for example, silicon rubber or fluororubber) having heat resistance is connected to the connecting portion 29a of the connecting portion 29. At the same time, the downstream end of the water supply pipe P1 is connected to the lower end portion of the storage portion 43 formed in a substantially cylindrical shape with a bottom extending in the vertical direction. 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 storage unit 43. 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.

  A plate-like partition wall 47 extending upward from the inner bottom of the storage unit 43 is formed at the bottom of the storage unit 43 so as to partition the bottom of the storage unit 43 into two regions (spaces). The water supply pipe P <b> 1 is connected to one bottom portion partitioned by the partition wall 47 at the bottom portion of the storage portion 43. In addition, the other bottom portion partitioned by the partition wall 47 at the bottom portion of the storage portion 43 is communicated with the lower end portion of the boiling chamber 42 a for heating the supplied water by the warm mist heater 42 by the communication portion 48. The communication part 48 forms a water supply path K2 for supplying water from the storage part 43 to the boiling chamber 42a. For this reason, in this embodiment, the relatively low-temperature water supplied via the water supply pipe P1 moves upward along the partition wall 47 after being supplied into the storage part 43 from the lower end part, and the storage part 43 It is mixed with the water stored inside. And in this embodiment, the water which mixed the comparatively low temperature water supplied newly and the water already stored in the storage part 43 is supplied to the boiling chamber 42a (arrow). Yd, Ye).

  The boiling chamber 42a is formed in a thin flat plate shape extending in the vertical direction along the heating surface 42b of the warm mist heater 42 erected along the vertical direction. The temperature mist heater 42 is made of, for example, a PTC (positive temperature coefficient) element. The water supplied to the boiling chamber 42a via the communication portion 48 is heated by the warm mist heater 42 in the boiling chamber 42a to be warm mist. The temperature mist heater 42 is provided with a temperature sensor SE.

  On the side of the upper end portion of the boiling chamber 42a, a lower temperature mist guiding portion 46 formed in a flat bottomed substantially cylindrical shape is continuously provided. In the present embodiment, the lower temperature mist guide 46 forms the lower temperature mist path M1. The lower temperature mist guiding portion 46 temporarily stores the water vapor (warm mist) generated in the boiling chamber 42a and guides it upward (where indicated by the arrow Yf) where the mist nozzle 20 is disposed. ). Further, the storage portion 43 described above is connected to the bottom surface of the lower temperature mist guiding portion 46 so as to open to the bottom surface of the lower temperature mist guiding portion 46. For this reason, in this embodiment, water generated by dew condensation inside the lower temperature mist guiding portion 46 or water scattered due to boiling in the boiling chamber 42a is relatively high (about 80 to 100 ° C.). Water is refluxed to the storage part 43 through the lower temperature mist guiding part 46 (indicated by an arrow Yg). That is, 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, tank holder 33a, and water supply pipe P1. It will be. 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. For this reason, in the present embodiment, it is possible to supply preliminarily heated hot water to the boiling chamber 42a, as compared with a case where relatively low temperature (room temperature) water supplied from the water supply pipe P1 is directly supplied to the boiling chamber 42a. And it can suppress that the temperature fall of the heating surface 42b of the warm mist heater 42 is suppressed, and the generation amount of warm mist falls. Thus, in this embodiment, the storage part 43 functions also as a reflux path.

  Moreover, in this embodiment, while the storage part 43 (reflux path) and the boiling chamber 42a are arrange | positioned in parallel, the communication part 48 (water supply path | route K2) and the lower temperature mist guidance | induction part 46 (lower temperature mist path | route M1) are provided. They are arranged in parallel. That is, a square annular pipe line is formed by the storage part 43, the communication part 48 (water supply path K2), the boiling chamber 42a, and the lower temperature mist guiding part 46 (lower temperature mist path 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 portion 51 having 50 is continuously provided. In the lower part of the upper temperature mist induction part 51 (the upper part of the lower temperature mist induction part 46), the bottom part of the upper temperature mist induction part 51 is formed, and the bottom part of the lower temperature mist induction part 46 and the upper temperature mist induction part 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 in the upper temperature mist guiding part 51 above the prevention wall 53. 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 guiding portion 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. For this reason, in this embodiment, the warm mist that has passed through the lower warm mist guiding portion 46 is guided to the mist nozzle 20 (mist discharge port 21) by the upper warm mist guiding portion 51 and the bellows member 55 (indicated by an arrow Yh). ). In the present embodiment, the upper warm mist path 51 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 guide 51 and the bellows member 55.

  In the present embodiment, the tank holder 33a and the water supply pipe P1 constitute a water supply mechanism unit 62 as a liquid supply mechanism, and a storage unit 43 (reflux path), a boiling chamber 42a, a warm mist heater 42, and a lower warm mist guiding unit 46. Constitutes a heating mechanism 60 as a mist generating mechanism. In the present embodiment, the upper temperature mist guiding portion 51, the bellows member 55, and the mist nozzle 20 (mist discharge port 21) constitute a mist discharge mechanism portion 61 as a mist discharge mechanism. Moreover, in this embodiment, the water supply tank 33 and the tank holder 33a comprise a liquid supply apparatus.

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. FIG. 6 shows a state where liquid (water) is stored in the water supply tank 33 and the water supply bar 28 is moved upward by the cosmetic device 10 being placed on a horizontal surface.

  As shown in FIG. 6, when the amount of water in the boiling chamber 42a, the reservoir 43, and the tank holder 33a decreases as the water is heated to mist in the boiling chamber 42a, the water surface W falls downward (down) To do). And since the water in the water supply tank 33 flows into the water supply tank 33 from the water supply rib 40a as the water surface falls below the lower end portion of the water supply rib 40a of the cap 39, It is supplied into the tank holder 33a so as to be replaced. The water surface W rises again when water is supplied from the water supply tank 33 into the tank holder 33a. Then, the supply of water from the water supply tank 33 is terminated by stopping the inflow of air into the water supply tank 33 as the water surface W rises above the lower end of the water supply rib 40a. The supply of water from the water supply tank 33 to the tank holder 33a is not terminated when the water surface W exactly coincides with the lower end of the water supply rib 40a, but the water surface can rise further upward. ing.

  Here, as described above, in the present embodiment, the tank holder 33a is made of polyethylene, and the cap 39 is made of polypropylene. Polyethylene and polypropylene, which are thermoplastic resins, are excellent in processability, but generally have a contact angle θ with water of more than 90 °, and are therefore considered to be hydrophobic materials. In general, when liquid flows into the gaps between structures, it is known that a force proportional to the interface distance along the horizontal direction between the structure (solid) and the liquid acts due to the influence of the surface tension of the liquid. It has been. That is, when the water storage space S is formed by the tank holder 33a made of a hydrophobic material and the water supply rib 40a as in this embodiment, the water surface W is prevented from rising due to the influence of the surface tension of water. The force will work in the direction (downward). Such a force in a direction that prevents the rise of the water surface W becomes a load when water is supplied from the water supply tank 33 to the tank holder 33a (heating mechanism unit 60).

  However, in this embodiment, the water supply rib 40a set smaller than the outer shape of the bottom 39a of the cap 39 is formed so as to protrude downward from the lower surface of the bottom 39a. For this reason, in this embodiment, compared with the structure which does not provide the water supply rib 40a, the interface distance along the horizontal direction between the tank holder 33a and the water supply rib 40a (cap 39) and water can be made small. That is, in this embodiment, when water is supplied from the water supply tank 33 to the tank holder 33a, it is possible to suppress the rise of the water surface W from being hindered by the surface tension of the water. For this reason, in this embodiment, it can be made easy to supply water from the water supply tank 33 to the tank holder 33a. In this embodiment, the water supply rib 40a functions as a load reducing unit.

Therefore, according to the present embodiment, the following effects can be obtained.
(1) The water supply rib 40 a is provided on the cap 39 of the water supply tank 33. For this reason, the load at the time of supplying water from the water supply tank 33 to the heating mechanism part 60 can be reduced. Therefore, it is possible to suppress the supply of water to the heating mechanism 60 from becoming unstable.

  (2) The water supply tank 33 is provided with a cap 39 having an opening 39b for supplying water from the water supply tank 33 to the heating mechanism 60, and the cap 39 is provided with a water supply rib 40a. For this reason, the load at the time of supplying water from the water supply tank 33 to the heating mechanism part 60 can be reduced.

  (3) The load at the time of supplying water from the water supply tank 33 to the heating mechanism 60 is reduced by the water supply rib 40a provided in the cap 39. For this reason, it can suppress that the supply of the water with respect to the heating mechanism part 60 becomes unstable, setting it as a simple structure.

  (4) The water supply rib 40 a is formed so as to surround the opening 39 b of the cap 39. For this reason, when supplying water from the water supply tank 33 via the opening part 39b, the load at the time of supplying water from the water supply tank 33 to the heating mechanism part 60 can be reduced more reliably.

  (5) The water supply rib 40a is formed so as to protrude downward from the lower surface of the bottom 39a of the cap 39, and the outer diameter is made smaller than the outer diameter of the cap 39 (bottom 39a). By comprising in this way, in this embodiment, compared with the structure which does not provide the water supply rib 40a, the interface distance along the horizontal direction between the tank holder 33a and the water supply rib 40a (cap 39) and water. Can be reduced. That is, when water is supplied from the water supply tank 33 to the tank holder 33a, it is possible to suppress the rise of the water surface W from being hindered by the surface tension of the water. Therefore, it can suppress that the supply of water with respect to the heating mechanism part 60 becomes unstable, and can suppress that the generation amount of warm mist becomes unstable.

In addition, you may change the said embodiment as follows.
In the above embodiment, the shape of the water supply rib 40a may be different. For example, as shown to Fig.7 (a), you may form the water supply rib 40a in a taper shape so that an outer diameter dimension (outer periphery length) may become small toward the downward direction which becomes a supply direction. By comprising in this way, the outer diameter dimension of the water supply rib 40a can be made small toward the lower end part (tip part) of the water supply rib 40a, and it can suppress that the water surface W is prevented from rising by the surface tension of water. . Moreover, as shown in FIG.7 (b), you may form the water supply rib 40a in the shape of a nozzle squeezed so that an internal diameter size and an outer diameter size may become small toward the downward direction. By comprising in this way, the outer-diameter dimension (periphery length) of the water supply rib 40a is made smaller toward the lower end part (front-end | tip part) of the water supply rib 40a, and the raise of the water surface W is prevented by the surface tension of water. This can be further suppressed.

  In the above-described embodiment, the cap 39 of the water supply tank 33 may be formed of a hydrophilic material such as glass. By comprising in this way, contact angle (theta) with water shall be 90 degrees or less, and it can suppress that the raise of the water surface W is prevented by the surface tension of water. Further, when the contact angle θ is set to less than 90 °, an upward force is generated by the surface tension of water, and the rise of the water surface W can be promoted. For this reason, while reducing the load at the time of supplying water from the water supply tank 33 to the heating mechanism part 60, it can suppress that the supply of water with respect to the heating mechanism part 60 becomes unstable. In this case, the water supply rib 40a can be omitted. In this modification, the cap 39 made of a hydrophilic material is the load reducing means.

  -In the said embodiment, you may modify | reform so that the outer peripheral surface of the water supply rib 40a may show hydrophilic property. By comprising in this way, contact angle (theta) with the water in the outer peripheral surface of the water supply rib 40a can be made small, and it can suppress that the raise of the water surface W is prevented by the surface tension of water. In this case, the lower end portion of the water supply rib 40a may not be modified so as to exhibit hydrophobicity. With this configuration, for example, when the water supply tank 33 is taken out, it is possible to make it difficult for water to adhere to the lower ends of the water supply ribs 40a. In addition, even though the water surface W has been lowered below the lower end of the water supply rib 40a, the surface tension of the water makes it difficult for air to enter the water supply tank 33, and on the contrary, water supply to the heating mechanism 60 is hindered. This can be suppressed.

  -In the said embodiment, you may change the height dimension of the water supply rib 40a suitably. That is, the water supply rib 40a may protrude downward from the lower surface of the bottom 39a of the cap 39, and the lower end of the water supply rib 40a may be disposed on the water surface W set in the cosmetic device 10.

-In the said embodiment, you may change suitably the planar view shape of the water supply rib 40a. For example, instead of forming a circle in plan view, it may be formed in a quadrangle, a triangle, or an ellipse.
-In above-mentioned embodiment, you may form the cross-sectional view shape of the lower end part of the water supply rib 40a in a taper shape or a flat square shape.

  In the above embodiment, the water supply rib 40 a may be formed away from the opening 39 b of the cap 39. Similarly, the size and position of the water supply rib 40a may be changed as appropriate. That is, the water supply rib 40a may be formed so as to surround the opening 39b inside the cap 39 in a plan view. Even if comprised in this way, the interface distance along the horizontal direction between the water supply rib 40a (cap 39) and water can be made small compared with the structure which does not provide the water supply rib 40a.

-In the said embodiment, the lower end part of the water supply rib 40a may comprise diagonal form or a wave form.
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. At this time, a plurality of warm mist nozzles from which the warm mist is discharged may be provided, or a plurality of cold mist nozzles from which the cold mist is discharged may be provided. One or a plurality of warm mist nozzles and one or a plurality of cold 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.

In the above embodiment, a cold mist may be discharged from the mist nozzle 20 (mist discharge port 21) instead of the warm mist.
In the above embodiment, the present invention is embodied in a cosmetic device, but may be embodied in a humidifier or the like.

The technical ideas that can be grasped from the above-described embodiments and modifications will be described below.
(A) In a liquid supply apparatus that supplies a liquid supplied from a storage tank capable of storing liquid to a liquid supply destination, a load reduction unit that reduces a load when supplying the liquid from the storage tank to the supply destination. A liquid supply apparatus comprising the liquid supply device.

  DESCRIPTION OF SYMBOLS 10 ... Beauty device (mist generator, beauty device), 21 ... Mist discharge port, 33 ... Water supply tank (storage tank, liquid supply device), 33a ... Tank holder (liquid supply device), 60 ... Heating mechanism (mist generation) Mechanism), 39... Cap (lid member, load reducing means), 39 b... Opening part (supplying part), 40 a.

Claims (3)

A bottomed cylindrical main body case and an upper housing provided on the upper surface of the main body case are provided, and the liquid supplied from the storage tank capable of storing the liquid is misted by a mist generating mechanism and discharged from the mist discharge port. In the mist generator,
In the main body case, a tank holder that opens to the upper housing and can store the storage tank is provided,
The bottom of the storage tank is formed in a bottomed cylindrical shape, and has an opening for supplying the liquid from the storage tank to the mist generating mechanism through the tank holder at the center of the bottom. A lid member is provided,
The lid member is formed with an annular rib that prevents the liquid surface in the tank holder from being hindered from rising when the liquid from the storage tank is supplied to the tank holder.
The rib covers the entire circumference so as to surround the opening, and the outer diameter is formed smaller than the outer diameter of the bottom of the lid member,
The rib is formed such that an inner diameter dimension and an outer diameter dimension become smaller toward a liquid supply direction from the opening . The mist generator according to claim 1 , wherein the lid member and the rib are formed of a hydrophilic material. In a beauty device that releases mist and cleans the skin surface,
A cosmetic device comprising the mist generating device according to claim 1 .

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