JP2007151959A - Steam generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a steam generator for raising a warm bath effect and a beauty effect by squirting steam which is obtained by allowing misty water particles generated by an ultrasonic wave generating means to be made into a fine mist with the use of a far-infrared light radiation member. <P>SOLUTION: The steam generator 1 includes a water storage tank 11 and a lid member 60. The water storage tank 11 includes a first heating means 21 for heating water stored in the water storage tank 11; the ultrasonic wave generating means 30 for making the water into the mist; and a squirting means 24 for squirting the misty water particles. The lid member 60 includes the far-infrared ray radiation member 70 where a squirting hole 71 for squirting the misty water particles to an outer part is formed. The lid member 60 or the far-infrared ray radiation member 70 includes a heating means 80 for heating the far-infrared ray radiation member 70. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a steam generator that generates steam with enhanced bathing effect and beauty effect.

  A conventional steam generator includes a water storage tank, heating means for heating water stored in the water storage tank, ultrasonic generation means for atomizing water stored in the water storage tank, and mist generated by the ultrasonic generation means. And jetting means for jetting water droplets. A conventional steam generator heats water stored in a water tank by a heating means, and activates the ultrasonic wave generation means to generate mist-like water droplets, so-called steam, in the water tank. The mist-like water particles (so-called steam) generated by the generating means are ejected outside the ejecting means (for example, Patent Documents 1 and 2).

The size of the molecular clusters of the mist-like water droplets is 130 to 140 Hz as shown in FIG. The steam generator is used in a sauna by being placed in a bathroom or used for a so-called sitting bath. As shown in FIG. 11 to FIG. 14, the sitting bath is a steam generating device disposed in a stool member 100 such as a chair, seated on the stool member 100, covered with a highly water-tight sheet 105 from the head, and steam generated. This is a sauna bath that is performed by generating steam in the seat 105.
JP 2000-197682 A JP 2002-22217 A

  The conventional steam generator has a problem that the size of the generated mist-like water droplets is large, so that the bathing effect and the beauty / beauty effect cannot be expected so much. That is, the bather is exposed to steam with a large amount of water and a large molecular cluster, so that water droplets adhere to the whole body and the body cools due to the heat of vaporization, thereby impairing the warm bath effect. In addition, since the steam has large water droplets, it is difficult to be absorbed by the skin, and there is a problem that there are few physical and cosmetic effects. Furthermore, since the water tank is made of synthetic resin, there is a problem that environmental hormones may be generated. In addition, there is a problem that noise and electromagnetic waves are generated due to the vibration of the vibrator by the operation of the ultrasonic wave generating means.

  The invention of the present application has been devised in view of the above problems, and by spraying steam in which the mist-like water droplets generated by the ultrasonic wave generation means are further reduced by the far-infrared radiation member, the effect of the hot bath is obtained. A first object is to provide a steam generator with enhanced beauty effects. Furthermore, by providing a far-infrared radiation member on the inner surface of the water tank, it is possible to suppress the generation of harmful substances and to absorb and decompose harmful substances, and to eliminate noise and electromagnetic waves caused by the operation of the ultrasonic generating means. A second object is to provide a steam generator that can prevent leakage.

The steam generator according to claim 1 of the present application has the following configuration in order to achieve the first object.
(B) The device body has a water storage tank and a lid member that closes the upper opening of the water storage tank.
(B) The water storage tank includes a first heating means for heating the water stored in the water storage tank, an ultrasonic generation means for atomizing the water stored in the water storage tank, and a mist generated by the ultrasonic generation means. And jetting means for jetting water droplets.
(C) The lid member is provided with a first far-infrared radiation member.
(D) The first far-infrared radiation member has an ejection hole for ejecting the mist-like water droplets to the outside.

  In order to achieve the first object, the steam generator according to claim 2 of the present application has a second heating means for heating the first far-infrared radiation member on the lid member or the first far-infrared radiation member. Is provided.

In order to achieve the second object, the steam generating apparatus according to claim 3 of the present application has the following configuration in addition to the above configuration.
(B) The water tank is formed by a bottom surface and a peripheral surface.
(B) A second far-infrared radiation member is provided on the bottom surface of the water storage tank.

In order to achieve the second object, the steam generator according to claim 4 of the present application has the following configuration in addition to the above configuration.
(B) The water tank is formed by a bottom surface and a peripheral surface.
(B) A third far-infrared radiation member is provided on the circumferential surface of the water storage tank.

The steam generator according to claim 5 of the present application has the following configuration in order to achieve the second object.
(B) The device body has a water storage tank and a lid member that closes the upper opening of the water storage tank.
(B) The water storage tank includes a first heating means for heating the water stored in the water storage tank, an ultrasonic generation means for atomizing the water stored in the water storage tank, and a mist generated by the ultrasonic generation means. And jetting means for jetting water droplets.
(C) The lid member has an ejection hole for ejecting the mist-like water droplets to the outside.
(D) The water storage tank is formed of a bottom surface and a peripheral surface.
(E) A second far-infrared radiation member is provided on the bottom surface of the water storage tank.
(F) A third far-infrared radiation member is provided on the circumferential surface of the water storage tank.

  The steam generating apparatus according to the present invention can generate heated steam in the water storage tank by heating the water stored in the water storage tank by the first heating means and operating the ultrasonic wave generating means. . Furthermore, since this steam is ejected through the ejection hole of the far-infrared radiation member, the water droplets of the steam can be further reduced, and there is an effect that the warm bath effect and the physical / beauty effect can be enhanced. That is, in the steam generator according to the present invention, since the bather is exposed to steam with small water droplets, the heat of vaporization of the water droplets is small, so there is little risk of cooling the body, and the bathing effect can be enhanced. effective.

  In addition, the steam generator according to the present invention can make the molecular clusters of the water droplets fine by the far infrared rays of the far infrared radiation member, so that it can be easily absorbed by the skin and can enhance the physical and beauty effects. effective. Thus, since the steam generator according to the present invention has high warm bath effect and physical / beauty effect, there is an effect that steam suitable for sauna bath or sitting bath can be generated.

  In addition, since the steam generator according to the present invention is provided with far-infrared radiation members on the bottom surface and peripheral surface of the water storage tank, it suppresses the generation of harmful substances such as environmental hormones and absorbs harmful substances such as chlorine and trihalomethane. There is an effect that decomposition can be performed. Furthermore, the far-infrared radiation member provided on the bottom surface and the peripheral surface of the water storage tank has an effect that noise and electromagnetic waves caused by the operation of the ultrasonic wave generation means can be prevented from leaking outside.

  An embodiment of a steam generator according to the present invention will be described with reference to FIGS. FIG. 1 is an overall configuration diagram showing one embodiment of a steam generator according to the present invention. FIG. 2 is a cross-sectional view of the main part of the apparatus main body in the steam generator of FIG. FIG. 3 is a cross-sectional view of the main part of the apparatus body viewed from another angle of FIG. FIG. 4 is a top view of the apparatus main body of FIG. 1 with the lid member opened. FIG. 5 is a top view with the lid member of FIG. 4 removed.

  6A and 6B are explanatory views of the lid member of FIG. 1, in which FIG. 6A is a top view and FIG. 6B is a side sectional view. FIG. 7 is an explanatory view of a far-infrared radiation member attached to the lid member of FIG. 1, (a) is a top view, and (b) is a side sectional view. FIG. 8 is a plan view of a far-infrared radiation plate provided on the bottom surface of the water storage tank of FIG. FIG. 9 is an explanatory diagram of a remote controller of the steam generator of FIG. FIG. 10 is a diagram showing measured values of the size of water molecule clusters. FIG. 11 is an exploded perspective view of a seat chair incorporating the steam generator of FIG. FIG. 12 is a front view of the seat chair of FIG. FIG. 13 is a side view of the seat chair of FIG. FIG. 14 is a perspective view showing a use state of the seat chair of FIG.

  As shown in FIG. 2, the apparatus main body 10 of the steam generator 1 includes a water storage tank 11 and a lid member 60 that closes the upper opening 11 a of the water storage tank 11. The water storage tank 11 includes a first heating unit 21 that heats the water stored in the water storage tank 11, an ultrasonic generation unit 30 that atomizes the water stored in the water storage tank 11, and an ultrasonic generation unit 30. There is provided jetting means 24 for jetting the generated mist-like water droplets.

  The lid member 60 is provided with a first far-infrared radiation member 70. As shown in FIG. 7, the first far-infrared radiation member 70 is formed with an ejection hole 71 for ejecting the mist-like water droplets to the outside. As shown in FIG. 2, the lid member 60 or the first far-infrared radiation member 70 is provided with second heating means 80 for heating the first far-infrared radiation member 70.

  As shown in FIG. 3, the water storage tank 11 of the steam generator 1 is formed by a bottom surface 12a and a peripheral surface 13a. A second far-infrared radiation member 40 is provided on the bottom surface 12 a of the water storage tank 11. In addition, third far-infrared radiation members 51 to 55 are provided on the peripheral surface 13 a of the water storage tank 11. In addition, you may form directly the ejection hole which ejects the said mist-like water droplet outside without providing the 1st far-infrared radiation member 70 in the cover member 60. FIG.

  Furthermore, a steam generator is demonstrated in detail. As shown in FIG. 1, the steam generator 1 includes an apparatus main body 10 that generates steam, a water tank 3 for supplying water to the apparatus main body 10, and a control device 5 that controls the electrical configuration of the apparatus main body 10. And a remote controller 90 for controlling the control device 5. The apparatus main body 10 includes the container 2 and a lid member 60 provided in the upper opening 11 a of the container 2.

  As shown in FIG. 3, the container 2 is formed by an outer cover 7 and a water storage tank 11. The outer cover 7 is composed of a disk-shaped bottom wall 8 and a cylindrical peripheral wall 9 erected substantially perpendicularly to the periphery of the bottom wall 8. The water storage tank 11 includes a disk-shaped bottom wall 12, a cylindrical peripheral wall 13 erected substantially perpendicularly to the periphery of the bottom wall 12, and an upper wall 14 protruding substantially horizontally at the upper end of the peripheral wall 13. The engaging wall 15 is suspended substantially perpendicularly to the periphery of the upper wall 14. At the lower end of the engagement wall 15, an engagement recess 16 that is engaged with the upper end of the peripheral wall 9 of the container 2 is formed.

  The water storage tank 11 is formed of a special composite material such as FRP having a heat resistant temperature of 150 ° C. As shown in FIG. 2, in the water storage tank 11, a first heater (first heating means) 21 that heats the water stored in the water storage tank 11 and a water temperature that detects the temperature of the heated water. The detection sensor 22 is fixedly attached with a screw or the like. The first heater (first heating means) 21 is formed in an annular shape, but is not particularly limited in shape. When the first heater (first heating means) 21 is formed in a linear shape or a substantially U shape, the bottom surface 12a can be easily cleaned.

  Further, the peripheral wall 13 of the water storage tank 11 is formed with a supply port 23 for supplying water from the water tank 3 into the water storage tank 11 and a discharge port 25 for discharging the water in the water storage tank 11. The discharge port 25 is provided in the vicinity of the bottom surface 12 a of the water storage tank 11. The supply port 23 is provided above the discharge port 25. It should be noted that the supply port 23 and the discharge port 25 are arranged so that the position of the supply port 23 is lowered in order to reduce the amount of water supplied from the supply port 23 from rebounding on the bottom surface 12a. The discharge ports 25 may be provided to face each other, but are not particularly limited to the mounting position.

  A water supply pipe connected between the water tank 3 and the supply port 23 includes a water supply pump for forcibly feeding the water in the water tank 3 into the water storage tank 11, and a water supply electromagnetic for starting and stopping the water supply. A valve is provided. The drain pipe connected to the drain port 25 is provided with a drain pump for forcibly discharging the water in the water storage tank 11 and a drain electromagnetic valve for starting and stopping drainage of the water.

  Further, as shown in FIG. 2, an air outlet (a jet port) 24 is formed in the upper part of the peripheral wall 13 of the water storage tank 11. The blower opening (spout port) 24 communicates with a blower (not shown), and the blower (spout) by the blower is sent into the water storage tank 11 through the blower port (spout port) 24. The blower and the blower opening (spout port) 24 constitute a blower means. Further, in the water tank 11, an ultrasonic generator 30 that generates ultrasonic waves in the water of the water tank 11 is fixed by an attachment means 27.

  Furthermore, the water storage tank 11 is provided with an upper water level detection sensor 28 and a lower water level detection sensor 29 for detecting the water level. The upper water level detection sensor 28 is provided below the blower opening (jet port) 24 and detects the water level so as not to rise to the blower port (jet port) 24. The lower water level detection sensor 29 is provided on the upper side of the ultrasonic generator 30 and detects so that the water level does not drop to the ultrasonic generator 30.

  The control device 5 is electrically connected to a first heater (first heating means) 21 and a water temperature detection sensor 22, and the water temperature detection sensor 22 detects the water temperature set by the remote controller 90, The first heater (first heating means) 21 is controlled. In addition, when the lower water level detection sensor 29 detects the water level, the control device 5 starts driving the water supply pump, opens the water injection electromagnetic valve, and supplies the water in the tank 3 into the water storage tank 11. When the upper water level detection sensor 28 detects the water level, the control device 5 stops driving the water supply pump, closes the water injection electromagnetic valve, and stops water supply into the tank 3.

  Thus, since the water in the water tank 11 is automatically replenished, the steam generator 1 can be used continuously, and anyone can check the water in the water tank 11 without checking it. Easy to use. The control device 5 can control the start and stop of the operations of the ultrasonic generator 30 and the air blowing means (jetting means) by operating the remote controller 90.

  As shown in FIG. 5, mounting recesses 31 to 35 are formed at five locations on the inner peripheral surface 13 a of the water storage tank 11 at predetermined intervals in the peripheral surface direction. On the bottom surface 12a of the bottom wall 12 of the water storage tank 11, as shown in FIG. 8, a second far-infrared radiation plate provided with fitting pieces 41 to 45 fitted in the mounting recesses 31 to 35 on the periphery. 40 is fixedly provided. Further, third far-infrared radiation plates 51 to 55 are fixedly attached to the attachment recesses 31 to 35, respectively. The mounting method of the second far-infrared radiation plate 40 and the third far-infrared radiation plates 51 to 55 is fixed by screws, adhesives, crimping, other fixing means such as a heater shaft, but is particularly limited. Is not to be done.

  As for the water storage tank 11, the bottom face 12a is completely covered with the 2nd far-infrared radiation plate 40, and about 2/3 of the internal peripheral surface 13a is covered with the 3rd far-infrared radiation plates 51-55. The second far-infrared radiation plate 40 and the third far-infrared radiation plates 51 to 55 of the water storage tank 11 are designed to make it difficult for harmful substances to be generated in the water inside the water storage tank 11, and to be harmful in the water storage tank 11. Absorbs and decomposes material. In addition, the second far-infrared radiation plate 40 and the third far-infrared radiation plates 51 to 55 of the water storage tank 11 refine the molecular clusters of water in the water storage tank 11 by the radiation of the far-infrared light, and further, electromagnetic waves and Cut off noise.

  As shown in FIGS. 2 and 3, the lid member 60 is attached to the container 2 via a support shaft 66 so as to be rotatable in a horizontal direction (a direction substantially perpendicular to the axial direction of the support shaft 66). As shown in FIG. 6, the lid member 60 has an upper wall 61, an inner peripheral wall 62 formed at the inner end of the upper wall 61, and an outer peripheral wall 63 formed at the outer end of the upper wall 61. The substantially U-shape and the whole are formed in a substantially ring shape. At the lower end of the inner peripheral wall 62, a locking edge 65 protrudes inward. The lid member 60 is formed of a special composite material such as FRP having a heat resistant temperature of 150 ° C., like the water storage tank 11.

  As shown in FIGS. 2 and 3, the support shaft 66 is erected substantially vertically between the peripheral wall 9 of the outer cover 7 and the peripheral wall 13 of the water storage tank 11, and the lower end is attached to the bottom wall 8 of the outer cover 7 by screws 8 a. It is fixed. The support shaft 66 is formed in a pipe shape. A pivot 67 protruding downward is fixed to the upper wall 61 of the lid member 60 with a screw or the like. The pivot 67 is formed in a pipe shape, is inserted into the support shaft 66, and is rotatably attached to the support shaft 66.

  A first far-infrared radiation plate 70 is attached to the lid member 60 with screws or the like. As shown in FIG. 7, the first far-infrared radiation plate 70 is formed in a disc shape and has a plurality of ejection holes 71. The plurality of ejection holes 71 are formed so as to be arranged in a triple ring around the approximate center of the first far-infrared radiation plate 70 and the approximate center. However, the arrangement is not limited to this arrangement. . Moreover, although the ejection hole 71 is formed by a circular hole having a diameter of about 8 mm, it is not limited to this size or this shape.

  As shown in FIGS. 6 and 7, the first far-infrared radiation plate 70 has a heater mounting groove 72 formed on the lower surface. The heater mounting groove 72 is not substantially overlapped with the ejection hole 71 so as to be approximately? The other end 75 is formed in a shape extending from the one end 73 to the outer peripheral surface 76 of the third far-infrared radiation plate 70. The shape of the heater mounting groove 72 is adapted to the shape of the heater mounted here, and is not limited to this shape.

  As shown in FIGS. 6 and 7, a second heater (second heating means) 80 is attached to the heater attachment groove 72. The tip 81 of the second heater (second heating means) 80 extends to one end 73 of the heater mounting groove 72. A base end 82 of the second heater (second heating means) 80 protrudes from the other end 75 of the heater mounting groove 72, is fixed to the pivot 67, and is connected to a conductive wire. The conductive wire extends into the pivot shaft 67, passes through the support shaft 66, and is connected to the control device 5.

  A stopper plate 77 for preventing the second heater (second heating means) 80 from coming off from the heater mounting groove 72 is attached to the back surface of the first far-infrared radiation plate 70 by screws 78. As shown in FIG. 7A, the stopper plate 77 is a circular plate in which a through hole facing the ejection hole 71 of the first far-infrared radiation plate 70 is formed. However, the stopper plate 77 is particularly limited to this shape. It is not a thing. The second heater (second heating means) 80 includes a temperature detection sensor.

  As shown in FIG. 1, the control device 5 is electrically connected to a remote controller 90, and controls each unit by an input signal of the remote controller 90. As shown in FIG. 9, the remote controller 90 includes a power switch 95, a mode selection unit 91, a switch 96 of the ultrasonic generator 30, an ejection means switch 97, a first temperature setting unit 92, 2 temperature setting section 93, time setting section 94, first drain switch 98a, and second drain switch 98b.

  The first drain switch 98a is electrically connected to the control device 6. When the first drain switch 98a is turned on, driving of the drain pump of the water storage tank 11 is started, and when it is turned off, driving of the drain pump of the water storage tank 11 is stopped. The second drain switch 98b is electrically connected to the control device 6. When the second drain switch 98b is turned on, driving of the drain pump of the water tank 3 is started. When the second drain switch 98b is turned off, driving of the drain pump of the water tank 3 is stopped.

  The mode selection unit 91 is where personal settings are stored. For example, if mode 1 stores the preferred temperature and bathing time of person A and mode 2 stores the preferred temperature and bathing time of person B, there is no need to set each time during use. In this embodiment, five people can be stored, but the number is not limited to this number.

  The first temperature setting unit 92 is for setting the temperature of the second heater (second heating means) 80. The second temperature setting unit 93 is for setting the temperature of the first heater (first heating means) 21. The time setting unit 94 is a place where the driving time of the steam generator 1 can be set. The first temperature setting section 92 is formed with a first display section 92a that displays the temperature. In the second temperature setting section 93, a second display section 93a for displaying the temperature is formed. The time setting unit 94 is formed with a time display unit 94a for displaying time.

  As shown in FIGS. 1 and 2, a storage member 19 that stores the herbs 18 is provided in the water tank 11. Herbs 18 are medicinal herbs, herbs, and the like. The storage member 19 is a net bag, a cloth bag, or the like. The storage member 19 is connected to one end of a connection member 20 such as a chain or string. The other end of the connecting member 20 is fixed in the water storage tank 11 with a screw or the like. When water is stored in the water storage tank 11, the herb 18 sinks in the water, and the nutrients of the herb 18 are dissolved in the water.

  The far-infrared radiation plates (members) 40, 51 to 55, 70 described above are so-called charcoal plates, which are formed by shaping charcoal into powder and not only radiating far-infrared rays. It generates negative ions and functions effectively for deodorization, antibacterial, absorption of electromagnetic waves, and the like. However, the far-infrared radiation plate (member) is not limited to this charcoal plate, and may be a ceramic plate or the like.

  The steam generator 1 has the above-described configuration and can be used as follows. Needless to say, when the steam generator 1 is used, the upper opening 11 a of the container 2 is closed by the lid member 60. When the power switch 95 of the remote controller 90 is turned on and the mode is selected by the mode selection unit 91, the heating temperature of the second heater (second heating means) 80 is displayed on the first display unit 92a, and the second display The heating temperature of the first heater (first heating means) 21 is displayed on the part 93a, and the driving time of the steam generator 1 is displayed on the time display part 94a.

  The heating temperature of the second heater (second heating means) 80 can be changed by the first temperature setting unit 92. The heating temperature of the first heater (first heating means) 21 can be changed by the second temperature setting unit 93. The driving time of the steam generator 1 can be changed by the time setting unit 94. The water in the water storage tank 11 is heated in the range of 50 ° C. to 95 ° C. by the first heater (first heating means) 21, but is not limited to this temperature range.

  When the switch 96 of the remote controller 90 is turned on, the ultrasonic generator 30 is activated. When the switch 97 is turned on, the jetting means, that is, the blower is activated, and air is blown into the water storage tank 11 from the blower port (spout port) 24. The water in the water storage tank 11 is heated to a set temperature by the first heater (first heating means) 21. The water temperature is detected by the water temperature detection sensor 22, and when the water temperature becomes higher than the temperature displayed on the second display section 93a, the control device 5 uses the first heater (first heating means). ) 21 is stopped, and when the water temperature becomes lower than the temperature displayed on the second display section 93a, the control device 5 operates the first heater (first heating means) 21.

  Further, the first far-infrared radiation plate 70 is heated to a set temperature by the second heater (second heating means) 80. In this embodiment mode, heating to 95 ° C. is possible, but the temperature is not limited to this. If the temperature detection sensor of the second heater (second heating means) 80 causes the temperature of the first far-infrared radiation plate 70 to be higher than the temperature displayed on the first display unit 92a, the control device 5 When the second heater (second heating means) 80 is stopped and the temperature becomes lower than the temperature displayed on the first display portion 92a, the control device 5 switches the second heater (second heating means) 80 on. Operate.

  When the ultrasonic generator 30 is actuated, mist-like water droplets of hot water heated by the first heater (first heating means) 21 in the space S between the water surface in the water storage tank 11 and the lid member 60 ( So-called steam) occurs. The thermal steam generated in the space S is ejected from the ejection hole 71 of the first far-infrared radiation plate 70 by the blower opening (ejection means) 24.

  When the control device 5 drives and controls a water supply pump (not shown), the water in the water storage tank 11 is supplied from the water tank 3, and when the water level in the water storage tank 11 is detected by the lower water level detection sensor 29, the control device 5 drives the water supply pump to supply the water in the water tank 3 into the water storage tank 11. When the water level in the water storage tank 11 is detected by the upper water level detection sensor 28, the control device 5 drives the water supply pump. Since it is stopped, a certain amount of water is always secured.

  As shown in FIG. 10, the water in the water tank 11 is separated from the second far-infrared radiation plate 40 provided on the bottom surface 12a and the third far-infrared radiation plates 51 to 55 provided on the peripheral surface 13a. Due to the infrared rays, the molecular cluster is as small as 50 to 60 Hz, and the water droplets of the hot steam generated in the space S in the water storage tank 11 are small. The molecular cluster of steam generated by a steam generator without a conventional far-infrared radiation plate is 130 to 140 Hz.

  Further, since the steam in the water storage tank 11 is ejected from the ejection hole 71 of the first far-infrared radiation plate 70, the steam generator 1 is configured such that the small steam molecular cluster is the first far-infrared radiation plate. Further refined to 15-20 Hz by 70 far infrared rays. Therefore, the steam generator 1 of the present invention can make the molecular cluster about one-tenth smaller than a steam generator that steams normal tap water and ejects it.

  In addition, the water molecule cluster of steam can be sufficiently miniaturized with only the first far-infrared radiation plate 70 without the second far-infrared radiation plate 40 and the third far-infrared radiation plates 51 to 55. On the contrary, the steam generator 1 does not have the first far-infrared radiation plate 70, and the second far-infrared radiation plate 40 and the third far-infrared radiation plates 51 to 55 can sufficiently form the water molecule cluster of steam. It can be miniaturized. In this case, it is desirable to form an ejection hole for ejecting steam to the outside in the lid member 60.

  The steam generator 1 is placed in a bathroom and used for a sauna bath or a so-called sitting bath. As shown in FIGS. 11 to 14, the sitting bath houses the steam generating device 1 in a seated chair 100, sits on the seated chair 100, covers a highly water-tight sheet 105 from the head, and the steam generating device 1. Generate and generate steam. That is, the seat 100 is provided with a drawer 102 for storing the steam generator 1 at the lower part of the seat 101, while a rectangular opening 103 through which the steam of the steam generator 1 is passed is formed in the seat 101. Has been. As shown in FIG. 14, when the user sits on the seat 101 of the seat 100, wears a highly water-tight sheet 105 from the head, and operates the remote controller 90, the user steams into the seat 105 through the opening 103. Can fill up and sit down.

  In the steam generator 1, since the lid member 60 can rotate in the horizontal direction around the support shaft 66, the inside of the water storage tank 11 is completely opened, and cleaning and repair are easy. In addition, since the cover member 60 is in sliding contact with the upper wall 14 of the water storage tank 11, a load applied to the support shaft 66 is reduced.

  The steam generator 1 heats the water stored in the water storage tank 11 with a heater 21 and activates the ultrasonic generator 30 to generate steam in the water storage tank 11, and this steam is used as a first far infrared ray. Since it ejects through the ejection hole 71 of the radiation plate 70, the water droplets contained in the steam can be further refined by far infrared rays, and the warm bath effect and the barber effect can be enhanced. That is, in the steam generator 1, since the bather is exposed to steam with small water droplets, the heat of vaporization of the water droplets is small, so there is little risk of cooling the body, and the warm bath effect can be enhanced.

  Moreover, since the steam generator 1 can make the water molecule cluster of steam small by the far infrared rays of the first far-infrared radiation plate 70, it can be easily absorbed by the skin, and the barber effect can be enhanced. Since this steam generator 1 has high warm bath effect and barber effect, it can generate steam suitable for sauna bath and seat bath. Further, since the first far-infrared radiation member 70 provided on the lid member 60 is close to the human body, the far-infrared radiation effectively acts on the human body.

  Further, the steam generator 1 is provided with a first far-infrared radiation plate 70 on the lid member 60, a second far-infrared radiation plate 40 on the bottom surface 12 a of the water storage tank 11, and a peripheral surface 13 a of the water storage tank 11. Since the third far-infrared radiation plates 51 to 55 are provided in the first far-infrared radiation plate 70, the second far-infrared radiation plate 40, and the third far-infrared radiation plates 51 to 55, To suppress the generation of harmful substances such as hormones, and to absorb and decompose harmful substances such as chlorine and trihalomethane, and to prevent the leakage of noise and electromagnetic waves due to the operation of the ultrasonic generator 30 to the outside Can do.

  Furthermore, when the herb 18 is provided in the water tank 11, the steam generator 1 dissolves the components of the herb 18 in the water in the water tank 11. Helps relieve stress, relaxes and makes you feel refreshed, and the water droplets of the steam are in the form of fine water molecule clusters that are easily absorbed by the skin by the first far-infrared radiation plate 70 The nutrients of herb 18 soak into the skin, further enhancing the barber / beauty effect.

  In addition, since the water in the water tank 11 has a fine molecular cluster by the radiation of the far infrared rays by the second far infrared radiation plate (member) 40 and the third far infrared radiation plates (members) 51 to 55. The dissolving power is improved, and the nutrients of the herb 18 are easily penetrated throughout. The steam generator 1 has a structure that can be easily cleaned and repaired because the lid member 60 can rotate in the horizontal direction about the support shaft 66.

It is a whole lineblock diagram showing one embodiment of a steam generating device concerning the invention in this application. It is principal part sectional drawing of the apparatus main body in the steam generator of FIG. It is principal part sectional drawing of the apparatus main body seen from another angle of FIG. It is a top view of the state which opened the cover member of the apparatus main body of FIG. It is the top view which removed the cover member of FIG. It is explanatory drawing of the cover member of FIG. It is explanatory drawing of the far-infrared radiation | emission member attached to the cover member of FIG. It is a top view of the far-infrared radiation board provided in the bottom face of the water storage tank of FIG. It is explanatory drawing of the remote controller of the steam generator of FIG. It is a figure which shows the measured value of the magnitude | size of a water molecule cluster. It is a disassembled perspective view of the seat chair incorporating the steam generator of FIG. It is a front view of the seat chair of FIG. It is a side view of the seat chair of FIG. It is a perspective view which shows the use condition of the seat chair of FIG.

Explanation of symbols

S space 1 steam generator 2 container 3 water tank 5 control device 7 outer cover 8 bottom wall 8a screw 9 peripheral wall 10 device main body 11 water storage tank 11a upper opening 12 bottom wall 12a bottom surface 13 peripheral wall 13a peripheral surface 14 upper wall 15 engagement wall 16 Engaging recess 18 Herb 19 Storage member 20 Connecting member 21 First heater (first heating means)
22 Water temperature detection sensor 23 Supply port 24 Blower port, jet outlet (spouting means)
25 Discharge port 27 Mounting means 28 Upper water level detection sensor 29 Lower water level detection sensor 30 Ultrasonic generator (ultrasonic generation means)
31 Mounting recess 32 Mounting recess 33 Mounting recess 34 Mounting recess 35 Mounting recess 40 Second far-infrared radiation plate (far-infrared radiation member)
41 Fitting piece 42 Fitting piece 43 Fitting piece 44 Fitting piece 45 Fitting piece 51 Third far-infrared radiation plate (far-infrared radiation member)
52 Third far-infrared radiation plate (far-infrared radiation member)
53 Third far-infrared radiation plate (far-infrared radiation member)
54 Third far-infrared radiation plate (far-infrared radiation member)
55 Third far-infrared radiation plate (far-infrared radiation member)
60 Lid member 61 Upper wall 62 Inner peripheral wall 63 Outer peripheral wall 65 Locking edge 66 Support shaft 67 Pivot axis 70 First far-infrared radiation plate (far-infrared radiation member)
71 Ejection hole 72 Heater mounting groove 73 One end 75 The other end 76 Outer peripheral surface 77 Stopper plate 78 Screw 80 Second heater (second heating means)
81 tip 82 base 90 remote controller 91 mode selection unit 92 first temperature setting unit 92a first display unit 93 second temperature setting unit 93a second display unit 94 time setting unit 94a time display unit 95 power switch 96 Switch 97 Switch 98a First drain switch 98b Second drain switch 100 Seat chair (seat member)
101 Seat 102 Drawer 103 Opening 105 Seat

Claims (5)

A steam generator characterized by having the following requirements.
(B) The device body has a water storage tank and a lid member that closes the upper opening of the water storage tank.
(B) The water storage tank includes a first heating means for heating the water stored in the water storage tank, an ultrasonic generation means for atomizing the water stored in the water storage tank, and a mist generated by the ultrasonic generation means. And jetting means for jetting water droplets.
(C) The lid member is provided with a first far-infrared radiation member.
(D) The first far-infrared radiation member has an ejection hole for ejecting the mist-like water droplets to the outside.   2. The steam generator according to claim 1, wherein the lid member or the first far-infrared radiation member is provided with second heating means for heating the first far-infrared radiation member. The steam generator according to claim 1 or 2, wherein the steam generator has the following requirements.
(B) The water tank is formed by a bottom surface and a peripheral surface.
(B) A second far-infrared radiation member is provided on the bottom surface of the water storage tank. The steam generator according to any one of claims 1 to 3, comprising the following requirements.
(B) The water tank is formed by a bottom surface and a peripheral surface.
(B) A third far-infrared radiation member is provided on the circumferential surface of the water storage tank. A steam generator characterized by having the following requirements.
(B) The device body has a water storage tank and a lid member that closes the upper opening of the water storage tank.
(B) The water storage tank includes a first heating means for heating the water stored in the water storage tank, an ultrasonic generation means for atomizing the water stored in the water storage tank, and a mist generated by the ultrasonic generation means. And jetting means for jetting water droplets.
(C) The lid member has an ejection hole for ejecting the mist-like water droplets to the outside.
(D) The water storage tank is formed of a bottom surface and a peripheral surface.
(E) A second far-infrared radiation member is provided on the bottom surface of the water storage tank.
(F) A third far-infrared radiation member is provided on the circumferential surface of the water storage tank.

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