JP3690166B2 - Steam beauty machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a steam-type beauty device intended to promote metabolism in the skin and moisturize in the hair by applying steam to the skin and hair such as the face, hydration and heat. It is.
[0002]
[Prior art]
Beauty treatments that give steam to the skin and hair such as the face to obtain hydration and a thermal effect have been conventionally performed, and various steam beauty machines used for this purpose have been provided.
[0003]
Especially in the case of a water storage type steam beauty machine that generates steam by supplying a certain amount of water, it is necessary to enlarge the water supply tank in order to increase the duration of steam generation. There was a problem that the waiting time of the person became longer.
[0004]
[Problems to be solved by the invention]
The present invention has been made in view of the above points. The efficiency of converting the supplied water into steam is increased as much as possible regardless of the size of the water supply tank, and the supplied water is quickly converted into steam to generate steam. It aims at providing the steam type beauty device which can shorten the waiting time of the user until.
[0005]
[Means for Solving the Problems]
  The steam beauty machine according to claim 1 of the present invention is longer than the first water storage unit and the first water storage unit, which is located on one side of the first water storage unit and communicates with the bottom of the first water storage unit. A boiling chamber with a small capacity, a heater for water heating arranged on the wall surface of the boiling chamber, and a side projecting from the first water reservoir to the side opposite to the boiling chamber.And the second communicating with the upper part of the first reservoirThe water reservoir and thissecondA steam flow path that is located above the water reservoir and guides steam from the boiling chamber to the nozzle, andsecondThe steam flow path is formed by a condensate hole provided in the wall that partitions the water reservoir and the steam flow path.secondIt is characterized by the fact that the water storage part communicates vertically.
[0006]
  Further, the steam beauty machine according to claim 2 of the present invention is in addition to the configuration of claim 1,The condensate hole is provided at a position away from the tip wall in the protruding direction of the second water reservoir.It is characterized by this.
[0007]
  Moreover, in addition to the structure of Claim 1 or 2, the steam type cosmetic device which concerns on Claim 3 of this invention,The nozzle includes a steam nozzle and a holder for holding the steam nozzle, and a cylindrical water-absorbing felt having a length substantially equal to the length of the steam nozzle is disposed therebetween.It is characterized by this.
[0008]
  Moreover, in addition to the structure in any one of Claims 1 thru | or 3, the steam type beauty device which concerns on Claim 4 of this invention,High-pressure discharge means is arranged in the path from the boiling chamber equipped with a heater to the nozzle.It is characterized by this.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to FIGS.
[0017]
FIG. 1 is a longitudinal sectional view of a steam beauty machine showing an example of an embodiment of the present invention. The main body 1 has an outer case formed of a storage case 22 and an upper cover 23, and the upper cover 23 is detachably locked to the upper end of the storage case 22 so as to cover the upper surface of the storage case 22. The housing case 22 has a placement portion 24 including a boss or the like below. A standing wall 25a is erected from the upper surface of the placement portion 24, and a lateral wall 25b is laid from the upper end of the standing wall 25a. A recess 25 opened to the lower surface is formed. With the standing wall 25a and the lateral wall 25b forming the recess 25 as a boundary, the accommodation space formed on the inner side of the accommodation case 22 is defined as the inner accommodation portion 26, and the accommodation space formed on the outer side of the accommodation case 22 is defined as the outer accommodation portion. 27. A boss 28 having a through hole 29 is formed at the center of the lateral wall 25b of the recess 25.
[0018]
The can body 11 is formed by connecting the first can body 32 and the second can body 33, and the water supply tank 2, the boiling chamber 6, and the like are provided therein. Here, the water supply tank 2 refers to a combination of a first water storage section 46 provided in the first can body 32 described later and a second water storage section 57 provided in the second can body 33.
[0019]
The can body 11 is fixed to the inner housing portion 26 of the housing case 22 by a holding member 24 having a placement portion 24 and a boss or the like of the housing case 22.
[0020]
The first can body 32 is formed by a water supply cylinder portion 34 having a bottomed cylindrical shape and a heater attachment pipe 35 joined to a peripheral wall 36 of the water supply cylinder portion 34. The outer end portion of the heater attachment tube 35 is an opening 35 a, and the heater 3 is attached to the heater attachment portion 52. A side opening 34c and a side opening 34d are provided in two upper and lower rows at a position facing the heater mounting pipe 35 in the peripheral wall 36 of the water supply cylinder 34.
[0021]
The upper part of the water supply cylinder part 34 is an upper opening part 34 a that fully opens the inside of the peripheral wall 36, and is called a first opening part 38. On the other hand, a hollow pipe-shaped communication pipe 37 is provided at the center of the bottom 34e of the water supply cylinder section 34, and the communication pipe 37 is composed of an upper protruding pipe 37a and a lower protruding pipe 37b. The upper projecting pipe 37 a extends toward the upper inside of the water supply cylinder portion 34, and the upper end thereof is at a certain level below the first opening 38 of the water supply cylinder portion 34. This is because a steam reservoir chamber 47 formed by a tank lid 40 to be described later is provided above the water supply cylinder portion 34. The lower protruding pipe 37b is formed to protrude outward from the bottom 34e of the water supply cylinder 34. The lower projecting tube 37b is connected to the through hole 29 of the boss portion 28 formed in the recess 25 while maintaining a sealing property. The upper end opening 37c of the communication pipe 37 is referred to as a second opening 39.
[0022]
  The first opening 38 of the water supply cylinder 34 is closed by a tank lid 40 described later. The tank lid 40 is provided with a flange portion 44, and a bottom portion 34 e of the flange portion 44 and the water supply tube portion 34.Perimeter wall 26The first water reservoir 46 surrounded by is formed.
[0023]
  A hollow box 48 is disposed on the outer wall of the peripheral wall 36 inside the heater mounting pipe 35 from a position slightly above the bottom 34 e of the water supply cylinder 34 to a position slightly below the upper inner wall of the heater mounting pipe 35. And forming a gap portion 91 between the lower surface of the heater and the lower inner wall of the heater mounting pipe 3548 top surfaceAnd heater mounting tube35A gap portion 92 is formed between the upper inner wall and the upper inner wall. A vertically long gap portion 93 is formed between the wall forming the hollow box 48 and the inner wall surface 3 a of the heater 3 attached to the opening 35 a, and this gap portion 93 becomes the boiling chamber 6. . At least one or more protrusions 8 are disposed on the inner wall 7 of the boiling chamber 6, that is, the wall of the box body 48 in the vertical direction. The gap 91 is a water supply passage 49 that connects the first water reservoir 46 and the boiling chamber 6, and the gap 92 is a communication passage 50 that connects the boiling chamber 6 and a steam reservoir chamber 47 described later. . The heater 3 has a terminal 53 for the outside of the can 11, a lead wire is joined to the terminal 53, and the heater 3 is connected to a power source via a power control means or the like.
[0024]
The second can body 33 is formed in a substantially U shape by connecting two circular tubes 54 and circular tubes 55 arranged in two upper and lower rows through a connecting portion 58. Of the two circular tubes arranged in the upper and lower rows, O-rings 87 and 88 are mounted in grooves provided on the outer periphery of the opening end 54a of the upper circular tube 54 and the opening end 55a of the lower circular tube 55, respectively. The side opening 34c and the side opening 34d provided on the upper and lower sides of the peripheral wall 36 of the water supply cylinder 34 are connected to each other while maintaining a sealing property.
[0025]
The circular pipe 54 arranged on the upper side of the second can body 33 is a steam passage 56, the circular pipe 55 arranged on the lower side is a second water storage part 57, and the steam passage 56 is formed in the water supply cylinder part 34. The second water reservoir 35 communicates with the first water reservoir 46 of the water supply cylinder 34 and the side opening 34d.
[0026]
A connecting portion 58 continuing to the steam passage 56 arranged on the upper side of the second can body 33 is a condensate portion 59, and a condensate hole 61 is provided on the lower surface of the condensate portion 59. It communicates with the second water storage part 57 arranged on the lower side of the body 33. An upper opening 33 a is provided at the upper part of the condensate part 59, that is, at the upper part of the connecting part 58 of the second can body 33, and communicates with the steam discharge pipe 12. Here, the steam discharge pipe 12 refers to one constituted by a nozzle 4, a connecting pipe 18, and a joint 60 which will be described later.
[0027]
The steam discharge pipe 12 is connected to an upper opening 33a provided at the upper part of the second can body 33 by a joint 60 (FIG. 2). That is, the joint 60 is composed of an elbow portion 60a and a base portion 60b, and an O-ring 86 is mounted in a groove provided on the outer periphery of the base portion 60b, and the base portion 60b is connected to the upper opening portion 33a while maintaining a sealing property. Since the elbow part 60a has a structure projecting from the base part 60b in the direction opposite to the direction in which the elbow part 60a extends, when the joint 60 is connected to the second can body 33, the lower end opening of the elbow part 60a 60d comes to be displaced rearward from the front wall portion 14 of the second can body 33. Therefore, a step portion 15 is formed between the lower end opening 60 d of the elbow portion 60 a of the joint 60 and the front wall portion 14 of the second can body 33. This step portion 15 becomes the water stop portion 16.
[0028]
The function of the water stop part 16 is demonstrated based on FIG. This figure is a view in which the main body 1 is inclined at an angle. Here, the residual water 62 in the second water storage part 57 flows out through the condensate hole 61, but its movement is suppressed by the step part 15 of the water stop part 16, and there is no outflow from the steam discharge pipe 12. With such a configuration, even if the main body 1 is inclined or falls, the water in the water supply tank 2 can be prevented from flowing out of the steam discharge pipe 12 as much as possible, which is safe.
[0029]
Moreover, the structure as FIG. 7 can also be considered as another example in which the water stop part 16 is provided. In this case, a step portion 15 for water stop is formed between the front wall portion 14 of the second can body 33 and the upper opening portion 33a, and the water stop tank portion 17 is disposed continuously to the step portion 15. To do. In FIG. 7, when L1 is horizontal, that is, in a normal use state, the water stop tank 17 of the water stop portion 16 is empty. Next, when L2 is horizontal, that is, when the main body 1 is inclined at a certain angle, the remaining water 62 in the second water storage portion 57 flows out through the condensate hole 61, but the step portion 15 of the water stop portion 16 is. The movement is suppressed, the water is stored in the water stop tank 17 and takes the form of residual water 62, and the residual water 62 does not flow out of the steam discharge pipe 12. By adopting such a configuration, it is possible to minimize the amount of water in the water supply tank 2 flowing out of the steam discharge pipe 12, and it is safer.
[0030]
The upper end opening 60c of the joint 60 is connected to the connecting pipe 18 while maintaining a sealing property (FIG. 2). The joint 60 is designed so that the bent portion 95 is optimal in consideration of the variable nozzle angle range and the condensate condensate to the condensate portion 10 described later.
[0031]
The connecting pipe 18 is formed of an elastic body 19 and is fixed to the connecting portion 69 a of the holder 69 while maintaining a sealing property. Here, the movement of the connecting pipe 18 will be described with reference to FIGS. FIG. 2 is a diagram in which the angle of the nozzle 4 to be described later is minimized with respect to the horizontal. FIG. 3 is a diagram in which the angle of the nozzle 4 is maximized with respect to horizontal when the nozzle 4 is movable. In either case, the constriction 21 is designed so that the unevenness of the movable portion 20 of the connecting pipe 18 is minimized.
[0032]
The nozzle 4 includes a nozzle cup 71, a holder 68, a holder 69, a water absorbent body 70, a packing 67, and a steam nozzle 65, which will be described below.
[0033]
A steam nozzle 65 is disposed in the holder 69 so as to protrude from the steam filling path 66. The steam nozzle 65 is fixed by a packing 67 while maintaining a seal, and the packing 67 is designed so that a sealing property can be secured by a fixing force of the holder 68 and the holder 69. Thereby, it is possible to prevent the condensed water droplets from being discharged from the steam nozzle 65 in the steam filling path 66. The water absorbing body 70 is installed between the packing 67 and the holder 68 in case water should flow from the steam nozzle 65. The nozzle cup 71 is fixed to the holder 68 or is detachably engaged with the holder 68.
[0034]
As described above, the connecting pipe 18 to the nozzle 4 is formed of the elastic body 19, and the movable portion 20 has the constriction 21, so that the angle of the nozzle 4 can be changed smoothly during use. By disposing the constriction 21 on the movable portion 20 of the elastic body 19, the unevenness of the elastic body 19 due to the change in the angle of the nozzle 4 can be minimized, the accumulation of condensation due to the unevenness is prevented, and hot water drops from the nozzle 4. Condensation is not discharged and it is safe.
[0035]
Other examples of the nozzle 4 may be those shown in FIGS. 8 to 10.
[0036]
The nozzle 4 (excluding the nozzle cup 71) shown in FIG. 8 will be described. Since the configuration other than the holder 69 is substantially the same as the above-described example, the description thereof is omitted. The inner peripheral surface 100 of the holder 69 has a gradient shape that is not horizontal in the movable range of the nozzle 4. As a result, the condensed water 115 attached to the upper slope 101 of the inner peripheral surface 100 is directed to the lower slope 102 via the packing 67, and flows down together with the condensed water 115 attached to the lower slope 102, and passes through the connecting pipe 18 and the joint 60. Water is condensed into the condensing unit 59 (FIG. 1). As a result, the condensate efficiency is improved, and the condensed water 115 attached to the inner peripheral surface 100 is not dripped onto the steam nozzle 65, so that dew is discharged from the nozzle 4 as hot water droplets. It will be safe.
[0037]
Next, the nozzle 4 (excluding the nozzle cup 71) shown in FIG. 9 will be described. In this example, since the configuration other than the holder 69 is substantially the same as the above-described example, the description thereof is omitted. The inner peripheral surface 100 of the holder 69 has a gradient shape that does not become horizontal in the movable range of the nozzle 4, and a condensate passage 103 is disposed below the holder 69. The condensate path 103 is connected to the condensate part 59 via the connecting pipe 18 and the joint 60. As a result, the condensed water 115 on the inner peripheral surface 100 flows into the opening 103 a of the condensate passage 103 and is condensed to the condensate portion 59 through the condensate passage 103. As a result, the condensate efficiency is improved, and the dew condensation water 115 attached to the inner peripheral surface 100 is not dripped onto the steam nozzle 65, and the dew condensation water 115 is condensed through a separate path from the steam filling path 66. Therefore, the steam is not affected by the unstable behavior of the dew condensation water 115 at the time of condensate, and the hot water droplets are not discharged from the nozzle 4 so that dew condensation is not discharged.
[0038]
Next, the nozzle 4 (excluding the nozzle cup 71) shown in FIG. 10 will be described. In this example, the configuration other than the holder 69 and the water-absorbing felt 104 is substantially the same as the above-described example, so the description thereof is omitted. Between the steam nozzle 65 and the holder 69 holding the steam nozzle 65, a cylindrical water absorbing felt 104 having a length substantially equal to the length of the steam nozzle 65 is disposed. As a result, the water absorption felt 104 absorbs the dew condensation water 115 generated in the holder 69 and the packing 67, and the dew condensation water 115 that has been absorbed flows out from the lower part of the water absorption felt 104 to the holder 69, and is condensed through the connecting pipe 18 and the joint 60. Condensed to section 59. As a result, it is possible to prevent the dew condensation water 115 from dripping onto the steam nozzle 65, and it becomes safe without dew condensation being discharged from the nozzle 4 as hot water droplets.
[0039]
As the steam nozzle 65 constituting the nozzle 4 described above, those shown in FIGS. 11 to 17 can be considered in addition to the above example.
[0040]
A steam nozzle 65 shown in FIG. 11 includes a cylindrical body 105 and a porous high thermal conductive material (for example, SUS316L) 106 provided on the inner surface of the cylindrical body 105. The cylindrical body 105 is formed of brass, copper, or the like having good thermal conductivity with a small heat capacity, but may have a high heat insulation property, for example, may be formed of silicon with a small heat capacity. By the way, in the shape of the steam nozzle 65 described above, when the porous high thermal conductive material 106 continues to supply water to the outer peripheral dew condensation pool W of the cylindrical body 105, a water absorption saturation state occurs, and the inner peripheral surface of the porous high thermal conductive material 106. There is a possibility that condensation will occur and the condensation rides on the flow of steam and is discharged as hot water droplets from the nozzle 4. Therefore, in the steam nozzle 65 shown in FIG. 11, the rear end portion 105 b of the cylindrical body 105 is formed into a hollow circle having a hole substantially equal to the inner diameter of the porous high heat conductive material 106, and the porous high heat conductive material 106 is covered. Even if the angle of the outer peripheral condensation pool W of the cylindrical body 105 changes when the nozzle 4 is moved, it can be dropped without touching the porous high thermal conductive material 106, so that the porous thermal conductive material 106 is in a saturated water absorption state. It will be safe without becoming.
[0041]
Next, another example is shown in FIG. In this example, in addition to the configuration of the cylindrical body 105 in FIG. 11, an edge portion 108 is extended below the rear end portion 105 b of the cylindrical body 105 so as to serve as a dripping path for the outer peripheral condensation pool W of the cylindrical body 105. A linear condensate part 109 is attached to the edge part 108. Thereby, since the outer periphery dew condensation pool W of the cylindrical body 105 is surely dripped along the condensing part 109, the outer periphery dew condensation pool W can be induced | guided | derived and a dew condensation is discharged from the nozzle 4 as a hot water droplet. It will be safe. The condensing unit 109 may be, for example, a chain, and is designed so that it always hangs vertically within the movable range of the nozzle 4.
[0042]
Next, another example is shown in FIG. In this example, in addition to the configuration of the cylindrical body 105 in FIG. 11, a water absorbing felt 110 is disposed on the outer periphery of the cylindrical body 105 so as not to protrude from the rear end portion 105 b of the cylindrical body 105. Thereby, all the outer periphery dew pools W of the cylindrical body 105 can be reliably absorbed, and the absorbed dew condensation can be reliably held, and the pulsation due to the steam pressure of the outer periphery dew pools W can be suppressed. Further, when water absorption is saturated, condensation absorbed from the end of the water absorption felt 110 is dropped, so that the outer peripheral condensation reservoir W does not touch the porous high thermal conductive material 106. For this reason, it becomes a safe thing without the dew condensation being discharged from the nozzle 4 as hot water droplets. In addition, the water absorption capacity of the water absorption felt 110 is set to be equal to or greater than the dew condensation amount due to the single operation of the product.
[0043]
Next, another example is shown in FIG. In this example, the rear end 105b of the cylindrical body 105 is extended in a cylindrical shape. As a result, even if the outer peripheral condensation pool W pulsates due to the steam pressure at the end of the rear end 105b of the cylindrical body 105 and enters the inner peripheral surface of the cylindrical body 105, it can touch the porous high thermal conductive material 106. Absent. For this reason, it becomes a safe thing without the dew condensation being discharged from the nozzle 4 as hot water droplets. In this example, the cylindrical body 105 can be easily formed. Note that if the extension distance of the cylindrical body 105 is too long, the heat capacity of the cylindrical body 105 increases and the water absorption performance of the porous high thermal conductive material 106 decreases, so that the outer peripheral condensation that has entered the inner peripheral surface of the cylindrical body 105. The reservoir W is designed to have a minimum distance that does not reach the porous high thermal conductive material 106.
[0044]
Next, another example is shown in FIG. In this example, in addition to the configuration of the cylindrical body 105 of FIG. 11, a small cylindrical portion 111 having a hole diameter equal to the hole diameter of the rear end portion 105b is continuously provided at the rear end portion 105b of the cylindrical body 105. . Thus, even if the outer peripheral dew pool W at the rear end 105b of the cylindrical body 105 pulsates due to the steam pressure, it drops without entering the inner peripheral surface of the cylindrical body 105 by the small cylindrical portion 111. W does not touch the porous high thermal conductive material 106. Therefore, the hot water droplets from the nozzle 4 are not discharged, and it is safe. Note that the length of the small cylindrical portion 111 is such that the outer peripheral dew condensation pool W of the cylindrical body 105 does not reach the porous high thermal conductive material 106, and is within the movable range of the nozzle 4 from the steam outlet 107 of the cylindrical body 105. Is always designed to be positioned at the lower level.
[0045]
Next, another example is shown in FIG. In this example, in addition to the configuration of the cylindrical body 105 in FIG. 11, a plate-shaped dew condensation holding section 112 having a through hole or a slit hole is extended to the lower part of the rear end portion 105 b of the cylindrical body 105. is there. Thereby, the retention force of dew condensation can be increased by the surface tension of water, dew condensation can be collected and held in one place, and the outer periphery dew condensation pool W can be dripped. In this way, the outer peripheral dew pool W reliably drops from one place, so that the outer peripheral dew pool W does not move in an unstable manner, and the hot water droplets are not discharged from the nozzle 4 and it is safe. It will be something.
[0046]
Next, another example is shown in FIG. In this example, in addition to the configuration of the cylindrical body 105 of FIG. 11, a disc-shaped flange 113 is provided continuously on the outer periphery of the rear end 105b of the cylindrical body 105, and a hole in the rear end 105b is provided. A tapered portion 114 having a passage having the same diameter as that of the rear end portion 105b is provided continuously behind the rear end portion 105b. As a result, due to the gradient of the tapered portion 114 and the steam pressure, the outer peripheral condensation pool W of the cylindrical body 105 is likely to gather at the lower portion of the disc-shaped flange portion 113, and the outer peripheral condensation pool W collected at the lower portion of the flange portion 113 is tapered. Because of the gradient of the portion 114, the porous body 105 cannot be touched because it cannot enter the cylindrical body 105. For this reason, it becomes a safe thing without the dew condensation being discharged from the nozzle 4 as hot water droplets. Note that the outer diameter of the disk-shaped flange 113 is determined in consideration of the amount of condensation on the outer periphery of the cylindrical body 115. If the amount of condensation is large, the outer diameter of the flange 113 is increased. In addition, the gradient of the tapered portion 114 is designed to be an angle that does not become horizontal in the movable range of the nozzle 4.
[0047]
By the way, the upper opening 34a of the water supply cylinder 34 constituting the first can 32, that is, the first opening 38 is closed by a tank lid 40 described later. Further, a drain cup 84 is fitted into the outer housing part 27 disposed below the water supply cylinder part 34. Since the drainage cup 84 is below the through hole 29 communicating with the lower opening 34b of the water supply cylinder 34, it serves as a tray for water flowing out of the water supply cylinder 34 from the second opening 39 of the water supply cylinder 34. To do.
[0048]
The tank lid 40 includes a lid portion 41 provided with a hook 41a corresponding to the groove 34f on the inner peripheral surface, a base portion 42 having an outer diameter substantially equal to the inner wall of the peripheral wall 36, and a center erected on the central lower surface of the base portion 42. The shaft portion 43, the flange portion 44 having a slightly smaller diameter than the inner diameter of the peripheral wall 36 connected to the end portion of the central shaft portion 43, and a closing portion 45 are configured (FIG. 4). An O-ring 85 is attached to the outer periphery of the base portion 42. Then, the tank lid 40 is engaged with the groove 35f of the water supply cylinder portion 34 and the hook 41a provided on the lid portion 41 of the tank lid 40 by the turning operation, and closes the first opening 38 and the second opening 39. It is like that. The O-ring 85 is slidably in close contact with the peripheral wall 36 and reliably closes the first opening 38 and becomes the first closing portion 97. Further, the flange portion 44 has a through-hole 72 having a small diameter at the top and a large diameter at the bottom, and a lower portion of the large diameter portion extending in a chamfered shape, and a coil spring 75 and a spring guide at the large diameter portion. A diaphragm 73 that inserts 76 and hermetically closes the through hole 72 is fixed to the closing portion 45. The diaphragm 73 closes the second opening 39 and becomes the second closing portion 98. Further, the flange portion 44 is slightly smaller in diameter than the inner diameter of the peripheral wall 36, and a communication hole 81 is formed between the flange portion 44 and the peripheral wall 36.
[0049]
The communication pipe 37 originally has a function of discharging excess water when the excess water is supplied to the water supply tank 2 and a function of releasing the pressure to the outside when the internal pressure rises abnormally. In addition, when the opening of the tank lid 40 is opened, when the first opening 38 is still closed, the second opening 39 is opened first and the pressurized steam inside is released to the outside. It also has a function of releasing.
[0050]
  As shown in FIG. 4, the diaphragm 73 has a valve body portion 73a having a diameter slightly larger than that of the second opening 39 at the center, a mounting portion 73b at the outer peripheral edge, and a thin elastic portion 73c connecting them. Is done. The diaphragm 73 is fixed to the closing portion 45 by the disk-shaped fixing plate 74 being fused or screwed to the closing portion 45 while pressing the mounting portion 73b. The upper surface of the valve body 73 a abuts on the spring guide 76, and the lower surface abuts on the second opening 39. FIG. 4 shows a state where the tank lid 40 is locked to the water supply tank 2 and the second opening 39 is closed. In this state, the coil spring 75 is compressed by a predetermined amount. Therefore, the diaphragm 73 receives the spring force F and the atmospheric pressure P0 downward, and the pressure P1 corresponding to the steam pressure upward and the atmospheric pressure P0 from the through hole 8. Is receiving. Since the spring force F is sufficiently larger than the normal pressure P1, the valve body 73a normally closes the second opening 39 reliably.
  However, when the steam nozzle 65 is clogged with foreign matter or the like and the pressure in the water supply tank 2 rises abnormally, the pressure P1 becomes larger than the spring force F, lifts the valve body 73a, and the second opening 39 opens. Then, the pressure is released to the outside. Accordingly, the coil spring 75 is appropriately designed according to how much pressure is raised when the second opening 39 is opened. That is, the diaphragm 73 is an elastic operating body having a valve function, but the second closing portion 98 may be configured by a member that replaces the diaphragm 73 as long as it has such an action.
  Next, the opening operation of opening the tank lid 40 is performed. When the tank lid 40 is rotated halfway to open, the spring force F of the coil spring 75 applied to close the second opening 39 is steam. The pressure becomes smaller than the pressure P1, the valve body 73a is lifted, and the steam is discharged to the outside through the communication pipe 37. Of course, at this time, the first opening 38 is closed by the O-ring 85. As a result, the internal pressure becomes the atmospheric pressure P0, and when the tank lid 40 is further rotated, the blockage of the first opening 38 is released, and the hook 41a and the groove 35f of the lid 41 are also released. At this time, since the internal pressure is already at the atmospheric pressure P0, the phenomenon that steam is blown out or the tank lid 40 is blown off does not occur. Also nozzle4Even when the tank lid 40 is clogged, the tank lid 40 can be opened safely in the same manner. Therefore, the groove 35f is formed on the outer periphery in the vicinity of the opening edge of the peripheral wall 36 so that the above-described opening operation can be performed with the hook 41a.
[0051]
As described above, the water supply tank 2, the heater 3 for heating water, and the nozzle 4 for discharging steam are provided, and the boiling chamber 6 having the heater 3 is disposed in an intermediate path 5 from the water supply tank 2 to the nozzle 4. Thus, the water stored in the water supply tank 2 is in a separate chamber from the water supply tank 2 and only a part of the amount of water stored in the water supply tank 2 is sent to the boiling chamber 6 communicating with the water supply tank 2. Can be heated by the heater 3 provided in the boiling chamber 6, water can be quickly heated and vaporized, and the waiting time of the user until the occurrence of steam can be shortened.
[0052]
Moreover, since the capacity | capacitance of the boiling chamber 6 provided with the heater 3 is a small capacity | capacitance compared with the capacity | capacitance of the water supply tank 2, ie, the capacity | capacitance of the capacity | capacitance of the 1st water storage part 46 and the 2nd water storage part 57, in the said structure. The aforementioned action is further promoted.
[0053]
Moreover, since the boiling chamber 6 is vertically long and has a cross section in which the area of the water surface is small, the area in which the water in the boiling chamber 6 is in contact with the heater 3 is increased, and the above-described operation is further promoted. Is done.
[0054]
In addition, since the protrusions 8 are arranged on a part of the inner wall 7 of the boiling chamber 6 in the vertical direction, the protrusions 8 of boiling water heated and boiled in the boiling chamber 6 are suppressed by the protrusions 8, and the outside of the boiling chamber 6. In order to prevent jumping out of the nozzle 4, bumping is not discharged from the nozzle 4, which is safe. Further, since boiling water can be held in the boiling chamber 6, it becomes possible to continuously generate steam, no pulsation occurs in the discharge of steam, and so-called breathing phenomenon does not occur.
[0055]
In the above configuration, steam vaporized in the boiling chamber 6 flows into the steam reservoir chamber 47 through the communication passage 50, and a part of the steam is formed between the flange portion 44 of the tank lid 40 and the peripheral wall 36. It flows into the upper part of the first water reservoir 46 through the hole 81 and further flows into the upper part of the second reservoir 57 through the side opening 34d. And it can flow into the condensate part 59 through the condensate hole 61 provided in the upper part of the 2nd water storage part 57, and can discharge a steam from the nozzle 4. FIG. Thus, the steam vaporized in the boiling chamber 6 passes through the upper part of the water supply tank 2 and can be discharged from the nozzle 2, so that it is vaporized in the boiling chamber 6 without providing a separate steam passage. Since the steam that has passed through the upper portion of the water supply tank 2 can be discharged from the nozzle 2, the number of steam passage parts can be reduced.
[0056]
Further, when the steam passes through the steam reservoir chamber 47, the steam filling the steam reservoir chamber 47 strikes the lower surface of the base portion 42 and the upper surface of the flange portion 44 of the tank lid 40, whereby the flow of the steam is rectified. Therefore, a uniform steam flow can be discharged. Further, even if bumping from the boiling chamber 6 occurs, it is suppressed by the tank lid 40 and only safe steam is discharged from the nozzle 4.
[0057]
In addition, by providing the second water storage unit 57, that is, the condensing unit 59 for condensing the condensed water generated in the vicinity of the nozzle 4 to the water supply tank 2, there is no condensation accumulation, and hot water is discharged from the nozzle 4. It is safe because no condensation is discharged as droplets. In addition, the condensed water generated by the steam loss is condensed again into the water supply tank 2, so that the amount of water supplied is surely steamed, so that the steam generation duration is increased and the waste water can be minimized. Steam efficiency can be increased.
[0058]
Next, the discharge part 78 is demonstrated based on FIG. This figure is a cross-sectional view taken along the line AA of FIG. The steam 82 that has entered the discharge passage 77 through the steam passage 56 passes between the discharge electrodes 79 and 80 of the discharge portion 78. At this time, the potential difference between the discharge electrodes 79 and 80 is a high potential, and the discharge electrodes 79 and 80 are designed and installed at a distance between the electrodes that can be discharged in the air. The steam 82 receives the high-pressure discharge, and becomes ion steam 83. In this way, the high pressure discharge means 9 is disposed in the intermediate path 5 from the boiling chamber 6 provided with the heater 3 to the nozzle 4, and the high pressure discharge is applied to the steam 82 vaporized in the boiling chamber 6. By changing to the ion steam 83, the ion steam 83 good for the skin such as the face and hair can be discharged from the nozzle 4.
[0059]
As a preparatory work, such a steam beauty machine first opens the tank lid 40 that closes the water supply cylinder portion 34 and supplies water to the water supply tank 2. The water is divided into a first water reservoir 46 and a second water reservoir 57. Next, the tank lid 40 is locked by the hook 41a and the groove 35f so that the base 42 to which the O-ring 85 is attached closes the first opening 38 and the diaphragm 72 closes the second opening 39, respectively. The water supplied to the water supply tank 2 flows into the boiling chamber 6 through the water supply passage 49, and the water levels in the water supply tank 2 and the boiling chamber 6 are substantially equal. Then, the upper cover 23 is locked to the housing case 22.
[0060]
When the heater 3 is energized after this preparatory work is completed, the water in the boiling chamber 6 is heated and steam is generated after several tens of seconds, and this steam is stored in the steam storage chamber 47 through the communication passage 50. Eventually, the steam storage chamber 47 becomes high pressure, and the steam is discharged from the nozzle 4 through the steam passage 56. Since the steam stored in the steam storage chamber 47 is isolated from the water in the water supply tank 2, steam loss can be reduced. Further, since the pressure in the steam reservoir chamber 47 is fed back to the water supply tank 2 through the communication hole 81, the pressures on the water surfaces of the boiling chamber 6 and the water supply tank 2 are equalized. Therefore, even if the water in the boiling chamber 6 is vaporized and the water level is lowered and a difference occurs between the water level in the water supply tank 2, the water in the water supply tank 2 passes through the water supply channel 49 due to the above-described pressure. It is supplied to the boiling chamber 6 until the water level is reached. Along with the water level balancing action, steam is continuously generated in the boiling chamber 6, so that no pulsation occurs in the discharge of the steam, and therefore the operation of so-called breathing phenomenon does not occur.
[0061]
【The invention's effect】
  In the first aspect of the present invention, only a part of the stored water amount is fed into the boiling chamber, and the water is quickly heated and vaporized in order to heat a small volume of water with a heater provided in the boiling chamber. And the waiting time of the user until the occurrence of steam is shortened. Moreover, it is formed so as to protrude from the first water reservoir to the side opposite to the boiling chamber.And the second communicating with the upper part of the first reservoirThe water reservoir and thissecondA steam flow path that is located above the water reservoir and guides steam from the boiling chamber to the nozzle, andsecondThe steam flow path is formed by a condensate hole provided in the wall that partitions the water reservoir and the steam flow path.secondBecause the water reservoir communicates verticallyEven if the steam flow path from the boiling chamber to the nozzle is long, the presence of the second water storage section and the condensate hole, which also increases the amount of stored water,Condensation does not occur, and hot water drops from the nozzle are not discharged, and it is safe. Also, the condensed water generated by steam lossWater reservoirBy condensing water, the amount of water supplied is surely converted to steam, so that the duration of steam generation is increased, and the waste water can be minimized and the steam efficiency can be increased.
[0062]
  In the invention according to claim 2 of the present invention, in addition to the effect of the invention according to claim 1,Since the condensate hole is provided at a position away from the tip wall in the protruding direction of the second water reservoir, water is prevented from flowing out to the nozzle side through the condensate hole when the main body is inclined or falls. can do.
[0063]
  In the invention according to claim 3 of the present invention, in addition to the effect of the invention according to claim 1 or 2,The water absorption felt absorbs the condensed water generated outside the steam nozzle and prevents the condensed water from dripping into the steam nozzle, so that the hot water droplets are not discharged from the nozzle and it is safe. Become.
[0066]
  Claims of the invention4In the described invention, claims 1 to3In addition to the effects described above, high-pressure discharge can be reliably applied to steam vaporized in the boiling chamber, and the action of the high-pressure discharge changes steam into ion steam, which is applied to the skin and hair such as the face. Can be discharged from the nozzle.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of a steam beauty machine showing an example of an embodiment of the present invention.
FIG. 2 is a vertical cross-sectional view of the nozzle part.
FIG. 3 is a vertical cross-sectional view of the nozzle part.
FIG. 4 is a longitudinal sectional view of the same tank lid.
FIG. 5 is a cross-sectional view taken along the line AA of FIG.
FIG. 6 is an explanatory view of the water stop part.
FIG. 7 is an explanatory diagram of a water stop portion of another example of an embodiment of the present invention.
FIG. 8 is an explanatory diagram of a nozzle portion according to another example of the embodiment of the invention.
FIG. 9 is an explanatory diagram of a nozzle portion according to another example of the embodiment of the invention.
FIG. 10 is an explanatory diagram of a nozzle portion according to another example of the embodiment of the invention.
FIG. 11 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
FIG. 12 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
FIG. 13 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
FIG. 14 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
FIG. 15 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
FIG. 16 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
FIG. 17 is an explanatory diagram of a steam nozzle according to another example of the embodiment of the present invention.
[Explanation of symbols]
2 Water supply tank
3 Heater
4 nozzles
5 intermediate route
6 Boiling chamber
7 inner wall
8 Projections
9 High pressure discharge means
10 Condensate department
11 Can body
13 Protruding base opening
14 Front wall
15 steps
16 Water stop
17 Water stop tank
18 Connecting pipe
19 Elastic body
20 moving parts
21 Constriction
60 fittings
65 Steam nozzle
69 holder
82 Steam
104 Absorbing felt

Claims (4)

A first reservoir, a vertically long boiling chamber located on one side of the first reservoir and communicating with the bottom of the first reservoir and having a smaller capacity than the first reservoir, and a wall of the boiling chamber A heater for water heating, a second water storage part formed to protrude from the first water storage part to the side opposite to the boiling chamber and communicated with the upper part of the first water storage part, and the second water storage part And a steam flow path for guiding the steam from the boiling chamber to the nozzle, and the steam flow path and the second through a condensate hole provided in a wall partitioning the second water storage section and the steam flow path . A steam beauty machine characterized by the fact that the water reservoir communicates vertically. 2. The steam beauty machine according to claim 1, wherein the condensate hole is provided at a position away from the tip wall in the protruding direction of the second water reservoir.   The nozzle includes a steam nozzle and a holder for holding the steam nozzle, and a cylindrical water-absorbing felt having a length substantially equal to the length of the steam nozzle is disposed therebetween. The steam beauty machine according to 1 or 2.   The steam beauty machine according to any one of claims 1 to 3, wherein high-pressure discharge means is disposed in a path from a boiling chamber provided with a heater to a nozzle.

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