KR100387737B1 - steam cosmetic device - Google Patents

Abstract

The condensation stagnant water formed on the outer circumferential surface of the nozzle is reliably plural. It is a steam beauty machine provided with the water supply tank (2), the heater (3) which heats water, and the nozzle (4) for steam jet which ejects the heat vaporized steam.

The plurality of leading-out members 109 are provided in close proximity to or in contact with the lower rear end of the nozzle 4.

Description

Steam cosmetic device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technology for reliably preventing hot water droplets from being discharged by plural condensation formed on the nozzle outer periphery in detail.

Conventionally, in a steam beauty machine equipped with a water supply tank, a heater for heating water, and a steam ejecting nozzle for ejecting steam, the steam vaporized by the heater is ejected toward the human body, and condensed water droplets (drops The broken water which is thrown up and scattered) may be ejected and burns may occur, and therefore, in a steam beauty machine, the ejection of condensed water droplets should not be prevented.

Therefore, the condensation water is generated in the vicinity of the nozzle and around the nozzle during steam generation, so that the condensation water is stagnant (hereinafter referred to as `` condensation condensation water ''), so that the nozzle itself does not eject from the nozzle, as in Japanese Patent Application No. 11-45593. The condensation stagnant water is dropped (hereinafter referred to as dripping), or a mechanism is provided in which water is dropped into the water supply tank.

However, in the dropping port, it takes time until the condensation stagnation number of the nozzle outer periphery is dropped by the dropping port of the nozzle, and until the dropping, the amount of condensation stagnation of the nozzle outer periphery increases gradually, and the steam pressure fluctuates. Etc., the movement of condensation congestion becomes unstable. As the amount of condensed water increases, the instability increases, and there is a problem that the steam is ejected from the nozzle at any moment.

The present invention aims to solve such a problem, and to provide a steam beauty machine capable of reliably dropping the condensation stagnant water generated on the outer circumference of the nozzle and reliably preventing hot water droplets from being discharged. It is.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing of the steam beauty machine which shows 1st Embodiment of this invention.

It is center line cross section of the nozzle part of 1st Embodiment of this invention.

It is a schematic side view of the steam nozzle of 1st Embodiment of this invention.

4 is a schematic side view of a steam nozzle of another embodiment of the present invention.

Fig. 5 (a) is a schematic side view of the steam nozzle of another embodiment as above, and (b) is a schematic front view.

6 is a schematic side view of a steam nozzle of another embodiment as above.

(A) is a schematic side view of the steam nozzle of another example of the above and another embodiment, (b) is a schematic front view.

Fig. 8 (a) is a schematic side view of the steam nozzle according to the above and another embodiment, (b) is a schematic front view, and (c) is a schematic plan view.

Fig. 9 (a) is a schematic side view of the steam nozzle according to the above and another embodiment, (b) is a schematic front view, and (c) is a schematic plan view.

Fig. 10 (a) is a schematic side view of the steam nozzle of another embodiment as above, and (b) is a schematic front view.

11 is a schematic side view of a steam nozzle of another embodiment from above.

12 is a schematic side view of a steam nozzle of another embodiment as above.

13 is a schematic side view of a steam nozzle of another embodiment as above.

14 is a schematic side view of a steam nozzle of another embodiment as above.

15 is a schematic side view of a steam nozzle of another embodiment as above.

[Description of Drawing Reference]

2 ... water tank 3 ... heater

4 ... nozzle

In this invention, it is a steam beauty machine provided with the water supply tank (2), the heater (3) which heats water, and the steam jet nozzle (4) which blows off steam, and it is a plurality of parts in the lower rear part of the nozzle (4). It is characterized in that the lead-out member 109 is provided close to or joined together.

According to such a configuration, the condensation stagnant water on the outer circumferential surface collected at the lower rear end of the nozzle 4 moves to the rear end of the plurality of drawer members 109 with the surface tension of water at the moment of contact with the tip of the plurality of drawer members 109. In this case, the condensation congestion number on the outer circumferential surface is pulled by the plural guiding member 109 while the amount of congestion is small, and moves to the end of the plural guiding member 109 and becomes the condensation congestion number at the rear end. If the amount of stagnation increases, it can be dripped and drained by gravity, and it can prevent that it becomes hot water droplets from the nozzle 4, and it ejects unexpectedly.

By the way, the plural guide members 109 are strap-shaped, and the front ends of the plural guide members 109 are provided at positions far enough from the rear end of the nozzle 4 to prevent fluctuations in steam pressure. Thus, the condensation stagnant water on the outer circumferential surface of the nozzle 4 does not affect steam condensation, and in the condensation condensation water at the rear end of the nozzle 4 where the steam pressure is affected, The holding force of the water can suppress the unstable movement of condensation water in the rear end. In addition, even after the unstable movement of the rear end condensation is difficult to suppress, the condensation condensation of the rear end is maintained at a position far enough from the hole of the nozzle 4, so that the water droplets become hot droplets in the nozzle 4. Condensation water is not discharged and is safe.

In this case, both ends of the string-like plurality of lead-out members 109 may be joined. In such a case, the same effect can be obtained by the tensile force of both of the plurality of lead-out members 109 arranged up and down. In addition, one end of the string-shaped plurality of lead-out members 109 may be connected to the lower rear end of the nozzle 4, and the other end may be folded and bent to form a gap between the front end and the nozzle 4 to be disposed.

In addition, even if the nozzle 4 is provided with the plurality of string-like plurality of water extraction members 109 in parallel, the same effect as described above can be obtained. Furthermore, the plurality of guide members 109 twist or weave a plurality of string-like guide members 109, and accordingly, the plurality of guide members 109 generate a capillary phenomenon. By doing so, the above effect is increased. Furthermore, the above-mentioned effect can also be obtained by using the curved plate as the plural guide members 109 and disposing the ends of the plural guide members 109 in close proximity to the nozzle 4. In this case, a plurality of leading members for the curved plate

109 may combine the both ends, and in this case, the said effect can be acquired by the tensile force of both of the plural guide members 109 arranged up and down. Further, the plural leading members 109 for the curved plate have a thinner plate thickness and a smaller plate width, which increases the pulling force of condensation congestion, and in addition, condensation at the end until the condensation condensation drops. Since the amount is small, since it is difficult to be affected by fluctuations in steam pressure, it is preferable.

In addition, the string-like plurality of lead-out members 109 and the curved plate-like lead-out member

It is preferable that 109 is a metal with good thermal conductivity, and as a result, the plurality of induction members 109 rises in temperature at a steam temperature and becomes high temperature.

(109) The amount of dew condensation generated in itself can be reduced, and arbitrary shapes are easily formed.

In addition, the plurality of lead-out members 109 may be formed of a flexible metal. Accordingly, in addition to the above effects, the shape can be reliably maintained even when an external stress such as a drop impact is applied. Over time shape reliability is improved.

It is also preferable to provide the nozzle 4 with a plurality of lead-out members 109 in a chain shape such that both ends of the plurality of lead-out members 109 are close to each other. In this case, the condensation stagnant water on the outer circumferential surface of the nozzle 4 moves to the plurality of drawing members 109 with the surface tension of water at the moment of contact with the tip of the plurality of drawing members 109, and thereafter, for the plurality of chain shaped It is pulled by the capillary phenomenon of the leading member 109 and moves reliably to the end of the plurality of leading members 109 on the chain and becomes the condensation stagnant number at the rear end, and if the stagnant amount of the condensation stagnant number at the rear end is increased by gravity The condensation stagnation number on the outer circumferential surface of the nozzle 4 decreases the amount of stagnation and is not affected by fluctuations in the steam pressure, and also in the condensation stagnation number at the rear end where the steam pressure is affected. It is possible to suppress the unstable movement of the condensation stagnant water at the end by the holding force of the water of the lead-out member 109. The chain-like plurality of lead-out members 109 may join both ends thereof, and in this case, the same effect can be obtained by the tensile force of both of the plurality of lead-out members 109 arranged up and down.

In addition, the plate-shaped plurality of lead-out members 109 may have a large area side cross-section arranged in substantially parallel to the vertical direction, and in this case, a cylindrical shape is formed by the surface tension with the plate-shaped plurality of lead-out members 109. Condensation congestion on the outer circumferential surface of the nozzle 4 of i) can reliably move to the condensation condensation on the rear end, and at the same time, it can suppress the unstable condensation of condensation condensation due to fluctuations in steam pressure during and after the movement. By the way, it is preferable that the rear end of the plate-shaped plurality of leading members 109 be as edged as possible, and thus, the condensation stagnation amount of the rear condensation stagnation can be dropped while the amount of condensation stagnation of the rear end is low. It can be reduced.

Here, the plate | board thickness of the plate-shaped plurality of lead-out member 109 is more preferable, since the number of back dew condensation stagnant numbers is easier to drop.

By the way, in the position sufficiently far from the hole of the nozzle 4, the end of the string-like plurality of leading-out member 109 is inclined at an angle with respect to the central axis of the nozzle cylindrical portion, and the above effect is obtained. At the same time as the load, the number of end condensation jams is more likely to drop. Here, an angle means what was set so that it might become vertical, for example so that the number of end dew condensation stagnations in the movement of the nozzle 4 will be easy to drop.

Further, the wide area side end portions of the plate-like plurality of lead-out members 109 may be arranged in a substantially orthogonal direction with respect to the vertical direction, and furthermore, the wide area side cross-sections of the plate-like plurality of lead-out members 109 are perpendicular to the vertical direction. It may be formed by a combination of those arranged in approximately parallel and approximately orthogonal directions.

Moreover, it is also preferable to provide the plurality of lead-out members 109 formed in the outline V shape which makes the edge part 109b of the plurality of lead-out members 109 into a bend. In this case, the condensation stagnation number W on the outer circumferential surface of the tubular body 105 moves to the end by the surface tension of water at the point of contact with the tip of the plurality of leading members 109, and thus condensation on the outer circumferential surface. The number W moves to the end by the surface tension of the water at the moment of contact with the tip of the plurality of leading members 109 while the amount of stagnation is small. Therefore, the condensation stagnation number W on the outer circumferential surface is derived for the plurality while the amount of stagnation is small. It is tensioned by the member 109 to move to the end of the plurality of leading member 109 to reach the end condensation stagnant number W2, and the stagnant amount of the end condensation stagnant number W2 increases to drop by gravity. Here, while the shape of the plurality of lead-out members 109 is approximately V-shaped, while the number of outer condensation congestion W moves from the tip of the plurality of lead-out members 109 to the end 109b, the plurality of lead-out members 109 The spacing of the holes is narrowed, and the pulling force due to the capillary phenomenon is generated, and the movement to the end portion 109b is smoothly accelerated, thereby enabling a more reliable movement.

In addition, as the end portion 109b is a bent portion, the end condensation stagnant number W2 is more easily dropped by gravity.

Therefore, the condensation stagnation number W on the outer circumferential surface of the tubular body decreases in the amount of stagnation and is not affected by steam pressure fluctuations, and the like. The holding force of water of 109 suppresses the unstable movement of the end condensation stagnation W2. Also, even if the condensation stagnation number W2 at the end continues to be unstable to the extent of unstable movement, the dew condensation stagnation number W2 is maintained at a position far enough from the steam nozzle inner cavity, so that the hot water drops from the nozzle It becomes (iii), and condensation water is not discharged and is safe.

Moreover, it is preferable to equip the lower part of said plurality of lead-out members 109d approximately in parallel with the nozzle center axis C, and in this case, the upper part of the plurality of lead-out members 109d is always the front end of the plurality of lead-out members 109d. Since the inclination located upward from this end is maintained, the condensation stagnant number W2 at the end does not flow back to the condensation stagnant number W side of the outer circumferential surface of the tubular body 105, thus improving the reliability of the above-mentioned effect and becoming more reliable. will be.

Moreover, it is also preferable to equip the plurality of guide members 109d in which the plurality of guide members 109d are dropped on the nozzle center axis C as a reference, and the end portion is positioned downward to form a roughly V-shape. . In this case, in particular, when steam is supplied from the lower part of the steam nozzle 65, the influence of the steam pressure PO on the condensation stagnant number W of the outer circumferential surface of the tubular body 105 is the rear end portion 105b of the tubular body 105. The pressure P1 which pushes up the condensation stagnation number W of the outer peripheral surface from the surface to the inclined upper direction becomes easy to mix into the steam nozzle inner cavity 107. In order to eliminate the influence of the pressure P1, a pulling force F, which is a reaction force of the pressure P1 according to the plurality of drawing members 109, is generated, and the drawing force F is applied to the action of the plurality of drawing members 109. It is equivalent. Therefore, even when steam is supplied from the lower part of the steam nozzle 65, the condensation stagnation number W on the outer circumferential surface reliably moves to the condensation stagnation number W2 on the end, and the condensation stagnation number W on the outer circumferential surface is affected by the fluctuation of steam pressure. Even in the case of condensation stagnation number W2 at the end affected by fluctuations in steam pressure or the like, unstable movement of the condensation stagnation number W2 at the end is suppressed by the holding force of the water of the plural discharge member 109. Further, even when the end condensation stagnation W2 continues to be unstable in an unstable motion, the nozzle condensation stagnant number W2 is maintained at a position sufficiently far from the steam nozzle inner cavity 107. It becomes hot water droplets, and condensation is not discharged, and it is safe.

Further, the rear end portion 109e of the plurality of lead-out members 109 is formed in a substantially V-shape so that the front end 109a of the plurality of lead-out members 109 approaches the rear end 105b of the tubular body 105. It is also desirable to have a plurality of leading-out members 109. In this case, the distance between the rear end portion 105b of the tubular body 105 and the plurality of lead-out members 109 is narrow at the tip of the plurality of lead-out members 109 and is wide at the rear end 109e. Ciliary body

The condensation stagnation number W on the outer circumferential surface of the 105 moves to the end portion 109b with the surface tension of water at the moment of contact with the tip 109a of the plurality of leading-out members 109, so that the condensation stagnation number W on the outer circumferential surface is While the amount of stagnation is small, it is tensioned by the plurality of leading members 109 to move to the end of the plurality of leading members 109 and becomes the condensation stagnation number W2 at the end. Drop by Therefore, a plurality of leading member

As the pulling force at the tip 109a of 109 improves, the above effect becomes more effective.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing.

The longitudinal cross-sectional view of the steam beauty machine which shows an example of embodiment of this invention is shown in FIG.

The main body 1 is formed in the outer case of the housing case 22 and the upper cover 23, the upper cover 23 is the upper end of the removable case 22 detachable so as to cover the upper surface of the housing case 22 Is bound to. The storage case 22 has a mounting part 24 including a boss or the like below, and enters a mouth wall 25a from an upper surface of the mounting part 24 to form an upper wall of the mouth wall 25a. The horizontal wall 25b is rolled up to form the recessed part 25 opened to the lower surface of the mounting part 24. The storage case 22 formed as an inner accommodating portion 26 is defined as an inner accommodating portion 26 formed on the inner side of the accommodating case 22 with the mouth wall 25a and the horizontal wall 26b forming the recess 25 as a boundary. The outer receiving portion is formed in the outer side of the receiving space

We assume (27). A boss having a through hole 29 in the center of the horizontal wall 25b of the recess 25

28 is formed. The can 11 is formed by connecting the first tubular 32 and the second tubular 33, and a water supply tank 2 and a boiling chamber 6 are provided therein. have. Herein, the water supply tank 2 is a combination of the first reservoir 46 provided in the first pipe 32 and the second reservoir 57 provided in the second pipe 33.

The tubular body 11 is fixed to the inner accommodating part 26 of the accommodating case 22 by the pressing member 30 which has the mounting part 24 of the accommodating case 22, and the boss | base etc.

The first pipe body 32 has a bottomed tubular water supply tube 34 and a water supply cylinder portion.

It is formed with the heater installation pipe 35 joined to the circumferential wall 36 of 34. As shown in FIG. The outer end of the heater attachment pipe 35 is an opening 35a, and the heater 3 is provided in the heater attachment portion 52. Side opening part in the position which opposes the heater installation pipe 35 in the circumferential wall 36 of the water supply tank part 34

34c and the side opening part 34d are provided in two rows of upper and lower sides.

The upper part of the water supply part 34 becomes the upper opening part 34a which fully opens the inner side of the circumferential wall 36, and is called the 1st opening part 38. As shown in FIG. On the other hand, in the center of the bottom part 34e of the water supply part 34, the communication pipe 37 of a hollow pipe shape is provided, and the communication pipe 37 is an upper bulge pipe 37a and a lower bulge pipe 37b. It consists of. The upper protrusion pipe 37a extends toward the inside of the water supply barrel 34, and the upper end thereof is somewhat lower than the first opening 38 of the water supply barrel 34. As shown in FIG. This is the steam stagnation chamber formed by the tank cover 40

This is because the 47 is provided above the water supply part 34. The lower protrusion pipe 37b is connected to the through hole 29 of the boss portion 28 formed in the recess 25 with a seal property. In addition, the upper opening part 37c of the communication pipe 37 is called the second opening part 39.

The first opening 38 of the water supply tank 34 is closed by the tank lid 40. The tank cover 40 is provided with a flange portion 44, and the first reservoir portion 46 surrounded by the flange portion 44, the bottom portion 34e of the water supply portion 34 and the circumferential wall 48 is provided. To form.

The inside of the heater installation pipe 35 is a hollow box body as an outer wall of the circumferential wall 36 from slightly above the bottom portion 34e of the water supply tank 34 to a position slightly below the upper inner wall of the heater installation pipe 35. 48 is disposed, and the clearance 91 is formed between the lower surface of the box 48 and the lower inner wall of the heater installation pipe 35, and the lower surface of the box 48 and the heater installation pipe ( The clearance part 92 is formed between the upper inner wall of 35). And hollow box

A longitudinally long gap 93 is formed between the wall forming the 48 and the inner wall surface 3a of the heater 3 provided in the opening 35a, and the gap 93 is boiling. At least one or more protrusions 8 are disposed on the inner wall 7 of the chamber 6, that is, on the wall of the box 48 in the vertical direction. The gap 91 is a water supply passage 49 communicating with the first reservoir 46 and the boiling chamber 6, and the gap 92 is a boiling chamber 6 and a steam stagnation chamber ( 47 is a communication path 50 for communicating. In addition, the heater 3 has a terminal 53 on the outside of the tube body 11, a lead wire is joined thereto, and is connected to a power supply through a power control means or the like.

The second pipe body 33 connects two circular pipes 54 and the circular pipes 55 arranged in two rows in a vertical direction.

It connects through 58, and it is formed in substantially U shape. In the grooves provided on the outer periphery of the open end 54a of the upper end 54 and the open end 55a of the lower end 55 of the two original tubes arranged in two rows above and below, 0 rings 87 and (, respectively) 88) equipped with water supply

It is connected with the side opening part 34c and the side opening part 34d which were provided up and down in the circumferential wall 36 of 34 with a sealability.

The primary tube 54 distributed to the upper side of the second tube body 33 is a steam passage 56, the primary tube 55 disposed below the second reservoir portion 57, and the steam passage 56 is a water supply tube portion ( The steam stabilization chamber 47 formed in 34 and the side opening 34c communicate with each other, and the second reservoir 57 communicates with the first reservoir 46 and the side opening 34d of the water supply tube 34. have.

The connecting portion 58 continuous to the steam passage 56 distributed above the second tubular body 33 has a plurality of portions 59, and a plurality of holes 61 are provided on the lower surface of the plurality of portions 59. And the second reservoir portion 57 distributed below the second tube body 33. Moreover, the upper opening part 33a is provided in the upper part of the some part 59, ie, the upper part of the connection part 58 of the 2nd tubular body 33, and is made to communicate with the steam discharge pipe 12. As shown in FIG. Here, what is comprised with the nozzle 4, the connecting pipe 18, and the coupling 60 which are later mentioned with the steam discharge pipe 12 is mentioned.

The steam discharge pipe 12 is connected to the upper opening 33a provided in the upper part of the second pipe body 33 by the coupling 60 (FIG. 2). That is, the coupling 60 consists of the elbow part 60a and the base 60b, the 0 ring 86 is mounted in the groove provided in the outer periphery of the base 60b, and the base 60b is the said base 60b. It is connected to the upper opening 33a with sealability. The elbow portion 60a has a structure in which the elbow portion 60a protrudes in the direction opposite to the extension direction with respect to the base 60b. Therefore, when the coupling 60 is connected to the second tube 33, the elbow portion 60 The lower end opening 60d of 60a is located behind the front wall portion 14 of the second tubular body 33. For this reason, the edge part 15 is formed between the lower end opening 60d of the elbow part 60a of the coupling 60, and the front wall part 14 of the 2nd piping 33. As shown in FIG. This end portion 15 is a water stop portion 16.

The upper opening 60c of the coupling 60 is connected to the connecting pipe 18 with a seal property (FIG. 2). The coupling 60 is designed so that the bent portion 95 is optimized in consideration of the nozzle angle variable range and the plurality of condensation water to the plurality of portions 10.

The nozzle 4 is comprised with the nozzle cap 71, the holder 68, the holder 69, the absorber 70, the packing 67, and the steam nozzle 65 demonstrated below.

The holder 69 is provided with a steam nozzle 65 in a hollow and protruding manner to the steam filling path 66. The steam nozzle 65 is fixed to the packing 67 with a seal property, and the packing 67 is designed to secure a seal property by the fixing force of the holder 68 and the holder 69. As a result, the condensation water droplets in the steam filling path 66 can be prevented from being discharged from the steam nozzle 65. The absorber 70 is provided between the packing 67 and the holder 68 in case the water flows from the steam nozzle 65 at any one time. The nozzle cap 71 is fixed to the holder 68 or is detachably attached to the holder 68.

In addition, the connecting pipe 18 to the nozzle 4 is composed of an elastic body 19, and the movable part 20 has a cutout portion 21, so that the angle of the nozzle 4 at the time of use may be desired. Also, by arranging the cut portions 21 in the movable portion 20 of the elastic body 19, the unevenness of the elastic body 19 due to the angle change of the nozzle 4 can be minimized. This prevents condensation stagnation due to unevenness and prevents condensation from being discharged from hot water droplets in the nozzle 4, thereby making it safe.

By the way, the upper opening part 34a of the water supply part 34 which comprises the said 1st tubular body 32, ie, the 1st opening part 38, is closed by the tank cover 40. As shown in FIG. In addition, a drain cap 84 is fitted to the outer receiving portion 27 disposed below the water supply portion 34. Since the drain cap 84 is below the through hole 29 communicating with the lower opening 34b of the water supply barrel 34, the drain cap 84 flows out of the water supply barrel 34 from the second opening 39 of the water supply barrel 34. It serves as a saucer for the water.

As the steam nozzle 65 which comprises the said nozzle 4, the thing shown to FIG. 3 thru | or 11 is considered to the said exception.

The steam nozzle 65 shown in FIG. 3 is comprised from the cylindrical body 105 and the porous high thermally conductive material (for example, SUS316L) 106 provided in the inner surface of the cylindrical body 105. As shown in FIG. Tubular

(105) is formed of pure brass having good thermal conductivity and equivalently small heat capacity, but may have high thermal insulation properties, for example, may be formed by reducing the heat capacity with a silicone resin. By the way, in the shape of the said steam nozzle 65, there exists a possibility that the outer condensation dew condensation W of the cylindrical body 105 may be unstable by the fluctuation | variation of a steam pressure, etc., and may eject from a nozzle at some instant. Therefore, in the steam nozzle 65 shown in FIG. 3, the rear end part 105b of the cylindrical body 105 covers the porous high thermally conductive material 106, and the rear end part of the cylindrical body 105 is shown.

The edge portion 108 is laid at the lower portion of the 105b, and the edge portion 108 is provided with a plurality of string-like guide members 109, and both ends thereof are adjacent to each other.

Accordingly, the condensation stagnation number W on the outer circumferential surface of the tubular body 105 moves to the end portion 109b with the surface tension of water at the instant of contact with the tip 109a of the plurality of leading members 109, and thus The condensation stagnation number W is pulled by the string-shaped plurality of leading-out members 109 while the amount of stagnation is small, and moves to the end portion 109b of the string-shaped plurality of leading-out members 109 to obtain the number of condensation stagnation W2. As the amount of stagnation increases, it is dropped by gravity.

Here, the end portion 109b of the string-shaped plurality of lead-out members 109 is provided at a position sufficiently far from the rear end portion 105b of the tubular body 105.

Therefore, the condensation stagnation number W is not influenced by fluctuations in the steam pressure, and the unstable movement of the condensation stagnation number W2 is suppressed by the holding force of the water of the cord-shaped plurality of leading-out members 109 even in the condensation stagnation number W2. . Further, even when the condensation stagnant water W2 continues to be unstable, the condensation stagnant W2 is held at a position sufficiently far from the steam nozzle inner cavity 107, so that the water droplets become hot droplets in the nozzle 4. Condensation is not discharged and is safe.

In addition, both ends of the string-shaped plurality of lead-out members 109 may be coupled, and in this case, the same effect can be obtained by the tensile force between both ends of the plurality of lead-out members 109c and the plurality of lead-out members 109d. have.

In addition, as shown in FIG. 4, the cylindrical tubular body 105 of FIG. 3 is fixedly installed in the string-shaped plurality of lead-out members 109 and the hole 111 of the rear end 105b of the tubular body 105. It is provided in parallel with a plurality of draw-out member 110 is a string. In such a configuration, the above-described effects can be obtained by the tensile force of both the plurality of leading members 109 and the plurality of leading members 110.

In addition, it is preferable that the above-mentioned cord-shaped plurality of lead-out members 109 pinch or weave the plurality of cord-shaped plurality of lead-out members 109, and, according to this, Capillary phenomenon occurs in the derivation member 109, the effect is more effective.

In addition, as in the example shown in FIG. 5, the above-described effects are obtained even when the curved plate 105 is a plurality of guide members 109 and the two ends are provided in close proximity. You can get it.

The plurality of guide members 109 of the curved plate may be coupled to both ends thereof, and in this case, the same effects are obtained by the tensile force of both the guide members 109c and the guide members 109d. You can get it. Incidentally, the thinner the plate thickness and the smaller the plate width, the more the force to pull the condensation stagnation number W increases, and in addition, the amount of stagnation until the condensation stagnation number W2 is dropped, thus reducing the fluctuation of steam pressure. It is preferable because it becomes less susceptible to influence.

In addition, the cord-like plurality of lead-out members 109 and the curved plate-like lead-out members 109 are preferably metals having good thermal conductivity, and, accordingly, the lead-out members 109 for steam at steam temperature. Temperature rises and becomes high temperature

(109) It is possible to reduce the amount of dew condensation generated on the surface thereof, and there is an advantage that any shape can be easily formed.

In addition, the plurality of lead-out members 109 may be formed of a flexible metal, and in addition to the above effects, the shape can be reliably maintained even when external stress such as a drop impact is applied. It is possible to improve the shape reliability over time.

In addition, as shown in the example shown in FIG. 6, in the configuration of the tubular body 105 of FIG. 3, a plurality of lead-out members 109 having a chain shape are provided so that their ends are close to each other. With such a configuration, the condensation stagnant number W on the outer circumferential surface of the tubular body 105 is the plural leading members due to the surface tension of water at the moment of contact with the tip 109a of the plural leading members 109.

Move to 109, and afterwards, it is reliably moved to the end portion 109b of the chain-shaped plurality of lead-out member 109 while being tensioned by the capillary phenomenon of the chain-shaped plurality of lead-out member 109, and condensation stagnant number W2 When the amount of condensation stagnant number W2 increases, the load is dropped by gravity. Therefore, the condensation stagnation number W on the outer circumferential surface of the tubular body 105 is small in stagnation amount, and is not affected by fluctuations in steam pressure, and the like. The water holding force of 109 suppresses the unstable movement of the condensation stagnant water W2. Here, the end portion 109b of the chain-shaped plurality of lead-out members 109 is provided at a position sufficiently far from the steam nozzle inner cavity 107. As a result, the condensation stagnant water W2 is kept at a position sufficiently far from the steam nozzle inner cavity 107 even when the dew condensation stagnation W2 continues to be unstable so that the condensation stagnant water W2 is maintained. ) To be safe without being discharged.

In addition, the chain-shaped plurality of lead-out members 109 may combine both ends thereof, and in this case, the same effect can be obtained by both tensile forces of the plurality of lead-out members 109c and the plurality of lead-out members 109d. Can be.

Next, another Example is shown in FIG. The rear end 105b of the tubular body 105 is a hollow circle having a hole approximately equal to the inner diameter of the porous high thermally conductive material 106, covering the porous high thermally conductive material 106, and the rear end of the cylindrical body 105. The plate-shaped plurality of lead-out members 109 are provided below the hole diameter of 105b. The plate-like plurality of lead-out members 109 are the same as in the present embodiment, and the wide area side cross-sections are arranged in parallel with respect to the vertical direction, whereby condensation occurs at the surface tension with the plate-shaped plurality of lead-out members 109. The stagnant water W reliably moves to the dew condensation number W2, and at the same time, it is possible to suppress the unstable movement of the dew condensation due to the change of the steam pressure during and after the movement.

In addition, the rear end 109b of the plate-like plurality of leading members 109 is preferably edged as much as possible, and accordingly, the dropping amount of condensation stagnation number W2 is dropped while the condensation stagnation number W2 is dropped. It can alleviate unstable movement. The thinner the plate thickness of the plural draw-out members 109, the more condensation stagnant number W2 is more preferable.

In addition, as shown in FIG. 8, in the structure of the cylindrical body 105 of FIG. 7, a cylindrical body is shown.

The plate-shaped plural draw-out member 109 is provided below the hole diameter of the rear side edge part 105b of 105, The wide area side cross-section is orthogonal to a perpendicular direction. As a result, the condensation stagnation number W reliably moves to the condensation stagnation number W2 due to the surface tension with the plate-like plurality of leading-out members 109, and the unstable movement of the condensation stagnation due to the fluctuation of the steam pressure during and after the movement is ensured. It can be suppressed.

In addition, in the Example shown in FIG. 8, it is preferable that the rear end part 109b of the plate-shaped multiple lead-out member 109 should be made as edge as possible, and, accordingly, there is little condensation stagnation amount of condensation stagnant number W2. Since it is dripped during this time, the unstable movement of the condensation congestion number W2 can be reduced. It is preferable that the plate thickness of the plurality of guide members 109 is thin, and the plate width is smaller.

In addition, as the example shown in FIG. 9, the cylindrical body by the structure of the cylindrical body 105 of FIG.

It is provided with the plate-shaped plurality of lead-out member 110 in which the wide area side cross-section is lower than the hole diameter of the rear side edge part 105b of 105, and arranged in parallel with respect to a perpendicular direction. According to this, the condensation stagnation number W reliably moves to the condensation stagnation number W2 due to the surface tension with the plate-like plurality of leading-out members 109, and then the condensation stagnation number W2 is secured by the surface tension with the plate-like leading-out member 110. It is possible to more effectively suppress the unstable movement of the condensation stagnant water W2 due to the change in the steam pressure.

In addition, in the Example shown in FIG. 8, it is preferable that the rear end part 109b of the plate-shaped multiple lead-out member 109 should be made as edge as possible, and, accordingly, there is little condensation stagnation amount of condensation stagnant number W2. Since it is dripped during this time, the unstable movement of the condensation congestion number W2 can be reduced. It is preferable that the plate thickness of the plurality of guide members 109 is thin, and the plate width is smaller.

In addition, in the structure of the cylindrical body 105 of FIG. 7, as shown in the example shown in FIG.

A wide area side cross section is provided below the hole diameter of the rear end portion 105b of the 105 in the form of a plurality of plate-shaped leading members 109 arranged in parallel with respect to the vertical direction, and the rear side end portion 109b has a large area side. Plate-like plural guide members arranged so that the cross section is orthogonal to the vertical direction

110 is provided. Accordingly, the condensation stagnation number W reliably moves to the condensation stagnation number W2 due to the surface tension with the plate-like plural leading members 109, and then the number of condensation stagnation number W2 with the surface tension with the plate-like plural leading members 110. It is maintained reliably to more effectively suppress the unstable movement of the condensation stagnant water W2 due to the change of steam pressure. In addition, in the Example shown in FIG. 9, the plate-shaped plurality of lead-out members 110 may protrude on the both sides of the wide area side of the plate-shaped plurality of lead-out members 109, and may also protrude only on one side like this embodiment. good. Further, the rear end surface 110b of the plate-like plurality of lead-out members 110 is to be edged as much as possible, and the plate thickness of the plate-shaped plurality of lead-out members 109 and 110 is thinner. There is little and it is easy to add at the same time, and it is preferable.

Next, another Example is shown in FIG. Rear end of tubular body 105

The back side end of the tubular body 105 is made into a hollow hollow shape having a hole approximately equal to the inner diameter of the porous high thermally conductive material 106, covering the porous high thermally conductive material 106.

The small cylindrical part 112 which is the same as the hole diameter of the rear end part 105b is continuously installed in 105b, and it is a string type so that the front outer peripheral part of the small cylindrical part 112 and the rear end part 105b of the cylindrical body 105 may be contacted. The plurality of guide members 109 on the upper side, and the end portion 113 of the cord-shaped plurality of guide members 109 is perpendicular to the central axis X of the small cylindrical portion 112 from the steam nozzle internal hole 107. It is spaced far enough apart. According to this, the condensation number W generated on the outer circumference of the small cylindrical portion 112 and the rear end 105b of the cylindrical body 105 is collected by the string-shaped plural draw-out member 109, and the string plural As the condensation number W can be dripped at the end 113 of the lead-out member 109, the unstable movement when the condensation number W moves to the condensation condensation number W2 can be greatly reduced, and condensation condensation is caused by fluctuations in steam pressure. Even if the water W2 is unstable, the water condensation stagnant water W2 is held and dripped at a position far enough from the steam nozzle inner cavity 107, so that condensation is discharged from the nozzle 4 as hot water droplets. It's safe. Incidentally, as shown in the example shown in FIG. 11, the end portion 113 of the string-shaped plurality of leading-out members 109 is positioned with respect to the central axis X of the small cylindrical portion 112 at a position sufficiently far from the steam internal cavity 107. By inclining at any angle, the above effects are obtained, and the number of dew condensation stagnants W2 is more likely to drop more effectively. Here, an angle means what was set so that it might become perpendicular, for example so that the dew condensation number W2 will drop easily in the operation of the nozzle 4.

12 shows another embodiment. In this embodiment, in the structure of the steam nozzle 65 of FIG. 3, the some guiding member 109 formed in the outline V shape which makes the edge part 109b of the plural guide member 109 into a bend part is provided. will be. The condensation stagnant number W on the outer circumferential surface of the tubular body 105 is moved to the end portion 109b with the surface tension of water at the moment of contact with the tip 109a of the plurality of lead-out members 109. The outer condensation congestion number W is pulled by the plural guiding member 109 while the amount of congestion is small, and moves to the end portion 109b of the plural guiding member 109 to become the condensation congestion number W2, which increases the condensation amount of the condensation condensation number W2. If you drop by gravity. Here, when the condensation stagnant number W of the outer peripheral surface moves from the front-end | tip 109a of the plurality of drawer members 109 to the edge part 109b by having the shape of the plurality of drawer members 109 roughly V-shaped, The gap between the members 109 is narrowed to generate a pulling force due to capillary action, so that the movement to the end 109b is smoothly accelerated, and more reliable movement is possible. In addition, as the end portion 109b is a bent portion, the number of dew condensation stagnation weight W2 is more easily dropped by gravity.

Therefore, the outer condensation congestion number W of the tubular body 105 has a small amount of condensation, and is derived from a plurality of condensation congestion numbers W2 to which the fluctuation of steam pressure and the like affects the fluctuation of steam pressure. The holding force of the water of the member 109 suppresses the unstable movement of the condensation stagnant water W2. In addition, even if the condensation stagnant water W2 continues to be unstable, the condensation stagnant water W2 is maintained at a position sufficiently far from the steam nozzle inner cavity 107, so that the dew condensation is discharged as hot water droplets from the nozzle 4. It becomes safe without being done.

In addition, in the Example shown in FIG. 13, in the structure of the steam nozzle 65 of FIG. 12, the several extraction | generating member 109d is provided in parallel with nozzle center axis C. FIG. In such a configuration, the plurality of guide members 109c have the condensation stagnation number W2 flowing back toward the condensation stagnation number W side of the outer circumferential surface so that the tip 109a always has an inclination upwardly from the end 109b. Therefore, the reliability of the said effect improves and it becomes more reliable.

14 shows yet another embodiment. In this embodiment, in the structure of the steam nozzle 65 of FIG. 12, the plurality of leading-out members 109d are drooped on the nozzle center axis c (horizontal) as a reference and the end 109b is lowered. It is provided with a plurality of leading members 109 positioned to form a rough V-shape. With such a configuration, in particular, when steam is supplied from the lower part of the nozzle 65, the influence of the steam pressure PO of the condensation stagnation number W on the outer circumferential surface is due to the surface of the outer circumferential surface on the surface of the rear end 105b of the tubular body 105. The pressure P1 which pushes up the condensation stagnant water W to the inclined upward direction makes it easier for the condensation stagnant water W to enter the steam nozzle inner cavity 107. In order to eliminate the influence of the pressure P1, the pulling force F, which is the reaction force of the pressure P1 by the plurality of leading members 109, is generated, and the pulling force F is the plurality of leading nozzles of the steam nozzle 65 of FIG. This corresponds to the action of the member 109. Therefore, even when steam is supplied from the lower part of the steam nozzle 65, the condensation stagnation number W on the outer circumferential surface surely moves to the condensation stagnation number W2, and the condensation stagnation number W on the outer circumferential surface is not affected by fluctuations in steam pressure. Also in the condensation stagnant water W2 affected by fluctuations in steam pressure, etc., unstable movement of the condensation stagnant water W2 is suppressed by the holding force of the water of the plurality of leading members 109. In addition, even when the condensation stagnant water W2 continues to be unstable, the condensation stagnant water W2 is maintained at a position far enough from the steam nozzle inner cavity 107. Thus, condensation is not discharged and is safe.

FIG. 15 shows another embodiment, and in this embodiment, in addition to the configuration of the steam nozzle 65 of FIG. 14, the front end 109a of the plurality of leading members 109 is the rear end of the tubular body 105. A plurality of guide members 109 in which the rear end 109e of the plurality of guide members 109 is formed in a substantially V-shape so as to be close to 105b is provided. With such a configuration, the distance position of the rear end portion 105b of the tubular body 105 and the plurality of lead-out members 109 is narrow at the tip 109a of the plurality of lead-out members 109, and the rear end 109e. ), The outer condensation congestion number W of the tubular body 105 moves to the end portion 109b with the surface tension of water at the moment of contact with the tip 109a of the plurality of leading members 109, and thus, the outer circumferential surface The condensation congestion number W of the condensation condensation member W is tensioned by the plural guiding member 109 while moving to the end 109b of the plural guiding member 109 while the congestion amount is small, and the condensation congestion number W2 is stagnant. When the amount increases, it is dripped by gravity. Therefore, the tip of the plurality of leading-out members 109

As the pulling force in 109a improves, the above effects become more effective.

In the present invention, in the steam beauty machine provided with a water supply tank, a heater for heating water, and a nozzle for steam ejecting steam, a plurality of leading members are provided close to or joined to the lower rear end of the nozzle. Therefore, the condensation stagnation number of the outer circumferential surface collected at the lower rear end of the nozzle moves to the rear end of the plural guiding member with the surface tension of water at the moment of contact with the tip of the plural guiding member. It is pulled by the plural guide members during a short period of time and moves to the end of the plural guide members and becomes the condensation number at the rear end, and when the stagnant amount of the condensation at the rear end increases, it can be dropped by the gravity and drained. It becomes hot water droplets, and can prevent it from blowing out unexpectedly.

In addition, the same effect as described above can also be obtained when the nozzles are provided with a plurality of string-like plurality of lead-out members in parallel. Moreover, it is more preferable to twist or weave a plurality of string-shaped plurality of lead-out members, and, as a result, a capillary phenomenon occurs in the plurality of lead-out members, thereby enhancing the above-mentioned action. . Furthermore, the above-mentioned effect can also be obtained by using the curved plate as a plurality of guide members and disposing both ends of the plurality of guide members in close proximity to the nozzle. In this case, the plurality of guide members of the curved plate may join both ends thereof, and according to such a configuration, the above-described action can be obtained by the tensile force of both of the plurality of guide members arranged up and down. Furthermore, the plural leading members of the curved plate have a smaller plate thickness and a smaller plate width, which increases the pulling force of the condensation congestion. In addition, the amount of condensation condensation at the end until the condensation condensation is dropped is small. Therefore, since it is difficult to be affected by fluctuations in steam pressure, it is preferable.

In addition, it is preferable that the string-shaped plurality of lead-out members and the curved plate-shaped lead-out members are metals having good thermal conductivity, and accordingly, the plurality of lead-out members causes a temperature rise at a steam temperature to become a high temperature. The amount of condensation generated on the plurality of leading-out members itself can be reduced, and arbitrary shapes can be easily formed.

In addition, the plurality of lead-out members may be formed of a flexible metal. Accordingly, in addition to the above effects, the shape can be reliably maintained even when external stress such as a drop impact is added. Timely shape reliability improves.

It is also preferable to provide a plurality of chain leading members with the nozzle so that both ends of the plurality of leading members come close to each other. In this case, the condensation stagnant water on the outer circumferential surface of the nozzle moves to the plurality of induction members by the surface tension of water at the moment of contact with the tip of the plurality of induction members, and then is pulled by the capillary phenomenon of the plurality of induction members in the chain shape. The condensation stagnant number of the rear end part is reliably moved to the end of the plurality of leading members of the shape, and when the stagnant amount of the rear part condensation stagnation amount increases, it is dropped by gravity, and the condensation stagnation number of the outer peripheral surface of the nozzle is small. In this way, the unstable movement of the end condensation water can be suppressed by the holding force of the water in the chain-shaped plurality of leading members even in the condensation water at the rear end, which is not affected by the steam pressure fluctuation or the like. The chain-shaped plurality of lead-out members may join both ends thereof, and in such a case, the same effect can be obtained by both tensile forces of the plurality of lead-out members arranged up and down.

In addition, in the plate-shaped plurality of lead-out members, a large area side cross-section may be arranged substantially parallel to the vertical direction, and in this case, the condensation stagnant number of the cylindrical nozzle outer peripheral surface is determined by the surface tension with the plate-shaped plurality of lead-out members. It is possible to reliably move up to the condensation congestion number at the rear end and to suppress the unstable movement of condensation condensation due to the change of steam pressure during and after the movement. By the way, it is preferable that the rear end of the plate-shaped plurality of lead-out members should be edged as much as possible, and accordingly, since the dew condensation stagnant amount of the rear end condensation stagnant number can be dropped, the unstable movement of the end condensation stagnant number can be reduced. You can do it.

It is also preferable to provide a plurality of draw-out members formed in a substantially V-shape having an end portion of the plurality of draw-out members as a bend. In this case, the condensation stagnation number on the outer circumferential surface of the tubular body moves to the end with the surface tension of water at the moment of contact with the distal end of the plural guiding member, and consequently, the condensation stagnation number on the outer circumferential surface is transferred to the plural leading members while the stagnation amount is small. This is because it is pulled to move to the end of the plurality of leading members, and becomes the condensation congestion number at the end. When the amount of condensation congestion at the end is increased, it is dropped by gravity. Here, the shape of the plurality of lead-out members is roughly V-shaped, so that when the condensation stagnation number on the outer circumferential surface moves from the front end to the end of the plurality of lead-out members, the spacing of the plurality of lead-out members becomes narrow and the pulling force due to the capillary phenomenon is reduced. This occurs and the movement to the end is accelerated smoothly, and more reliable movement is possible. In addition, the condensation stagnant number at the end is more easily dropped by gravity due to the fact that the end is a bent portion.

Therefore, the condensation stagnation number on the outer circumferential surface of the tubular body is reduced in the amount of stagnation and is not affected by fluctuations in steam pressure, and the like. The holding force of the water suppresses the unstable movement of condensation water at the end. In addition, condensation is retained at the end at a position far enough from the steam nozzle inner cavity even if the condensation is unstable so that the condensation can not be continuously suppressed. To be safe.

In addition, the lower portion of the plurality of lead-out members is preferably provided in parallel with the nozzle central axis, and in this case, the upper portion of the plurality of lead-out members always has an inclination in which the tip of the plurality of lead-out members is positioned upward from the end. Since the condensation stagnant number at the end does not flow back to the condensation stagnant number side of the outer circumferential surface of the tubular body, the reliability of the above-mentioned effect is improved and it becomes more reliable.

Moreover, it is also preferable to provide the plurality of lead-out members in which the said plurality of lead-out members were drooped, the edge part was located downward, and formed the outline V shape. In this case, in particular, when steam is supplied from the lower part of the steam nozzle, the influence of the steam pressure of the condensation stagnant water on the outer circumferential surface of the tubular body is a pressure that pushes up the condensation stagnant water on the outer circumferential surface from the surface of the rear end of the tubular body in an inclined upward direction. As a result, condensation stagnation on the outer circumferential surface easily enters the steam nozzle inner cavity. In order to eliminate the influence of this pressure, the pull-out force which is a reaction force of pressure is generated by the draw-out member for multiple uses, and this pull-in force corresponds to the action | action of the said draw-out member for multiple uses. Therefore, even when steam is supplied from the lower part of the steam nozzle, the condensation condensation water on the outer circumferential surface reliably moves to the condensation condensation water on the end, and the condensation condensation water on the outer circumferential surface is not affected by the fluctuation of steam pressure and the like. Even in the condensation stagnant number of the end affected by the fluctuation, the unstable movement of the end condensation stagnation is suppressed by the holding force of the water of the plural leading members. In addition, the condensation condensation at the end is maintained at a position sufficiently far from the steam nozzle inner cavity even if the condensation condensation continues at an unstable level so that the condensation condensation is discharged as hot water droplets from the nozzle. It becomes safe without work.

It is also preferable to provide a plurality of lead-out members in which the trailing end of the plurality of lead-out members is formed in a substantially V-shape so that the front end of the plurality of lead-out members approaches the rear end of the tubular body. In this case, the distance between the rear end of the tubular body and the plural leading members is narrow at the tip of the plural leading members and is wide at the rear end, so that the condensation congestion on the outer peripheral surface of the tubular body is the tip of the plural leading members. At the moment of contact with the surface tension of the water, it moves to the end, so that the condensation stagnation number on the outer circumferential surface is pulled by the plural guide members while the stagnation amount is small, and moves to the end of the plural guide members to become the condensation stagnant water at the end. If the amount of stagnant water increases, it is loaded by gravity. Therefore, the above-mentioned effect becomes more effective because the pulling force in the front-end | tip of a plurality of lead-out members improves.

Claims (17)

A steam beauty machine comprising a water supply tank, a heater for heating water, and a steam ejecting nozzle for ejecting steam, the apparatus being provided by adjoining or joining a plurality of ejection members at a lower rear end of the nozzle. Steam beauty machine. The steam beauty machine as claimed in claim 1, wherein the steam extracting device is formed in a plurality of string shapes, and a plurality of string-shaped extracting members are formed in parallel. The steam beauty machine according to claim 2, wherein the steam beauty machine is formed by twisting a plurality of string-shaped plurality of lead-out members. The steam beauty machine according to claim 1, wherein the plurality of leading members are formed in a curved plate. The steam beauty machine according to claim 1, wherein the plurality of leading members are made of metal. The steam beauty machine according to claim 5, wherein the plurality of leading members are made of a flexible metal. The steam beauty machine according to claim 1, wherein the plurality of leading members are formed in a chain shape. The steam beauty machine according to claim 1, wherein the plurality of leading members are formed in a plate shape. The steam beauty machine according to claim 1 or 8, wherein an edge is provided at an end of the plurality of leading-out members. The steam cosmetic machine according to claim 8, wherein a wide area side cross section of the plate-shaped plurality of leading-out members is arranged in substantially parallel to the vertical direction. The steam cosmetic machine according to claim 8, wherein a wide area side cross-section of the plate-shaped plurality of leading-out members is arranged in a substantially orthogonal direction with respect to the vertical direction. 9. The steam beauty machine according to claim 8, wherein a wide area side cross section of the plate-like plural leading members is formed by a combination of ones arranged in substantially parallel and approximately orthogonal directions with respect to the vertical direction. The steam beauty machine as set forth in claim 1, wherein a plurality of string-shaped guide members are provided around the lower rear end of the nozzle. The steam beauty machine according to claim 2, wherein an end portion of the plurality of leading-out members is formed in a substantially V-shape. 15. The steam beauty machine as claimed in claim 14, wherein a lower portion of the plurality of leading-out members directed from the nozzle end to the upstream side of the steam is formed in parallel with the nozzle central axis. The steam beauty machine as claimed in claim 2, wherein an end portion of the plurality of leading-out members dropped from the nozzle end is formed in a substantially V-shape. The steam beauty machine according to claim 16, wherein the rear end portion of the plurality of lead-out members is formed in a substantially V-shape so that the front end of the plurality of lead-out members is close to the lower rear end of the nozzle.