JP2006061402A - Sauna room with electrostatic spraying apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sauna room with an electrostatic spraying apparatus, which moisturizes the skin of a user during use of a sauna and which suppresses the growth of mold in the wet type sauna room. <P>SOLUTION: The electrostatic spraying apparatus B is provided with a water particle discharging part 1, a counter electrode 2 which faces the water particle discharging part 1, and a voltage applying part 3 for applying high voltage between the water particle discharging part 1 to which water is supplied and the counter electrode 2. The electrostatic spraying apparatus B applies high voltage between the water particle discharging part 1 and the counter electrode 2 to generate charged particulate water of a nanometer size from the water in the water particle discharging part 1. The electrostatic spraying apparatus B is provided in the sauna room A. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a sauna room.

Conventionally, a sauna room that encourages the user to sweat and improves metabolism includes a dry sauna room that heats the body with radiant heat as in Patent Document 1, for example, and a heated mist such as that in Patent Document 2 There is known a wet sauna room for heating. By the way, since the user of the sauna room perspires, there exists a problem that the amount of water retention of skin falls. In particular, in a dry sauna room, the room air is also dry, so the amount of water retained in the skin is significantly reduced. In a wet sauna room, mist is generated in the sauna device and the room air is in a high humidity state. However, since the size of the generated mist is larger than the gap width between the keratins of the skin, the mist cannot penetrate into the skin, and the water retention amount inside the skin is reduced. There is also a problem that molds and the like are easily generated in a wet sauna room where the room is in a high humidity environment.
JP-A-8-238289 Japanese Patent Laid-Open No. 11-178883

  The present invention has been invented in view of the above-mentioned conventional problems, and is intended to moisturize a user's skin while using a sauna, and to suppress generation of mold in a wet sauna room. It is an object to provide a sauna room with an activation device.

  In order to solve the above-mentioned problem, a sauna room with an electrostatic atomizer according to claim 1 of the present invention is provided with a water particle discharge part 1, a counter electrode 2 facing the water particle discharge part 1, and water. In addition, a voltage applying unit 3 that applies a high voltage between the water particle emitting unit 1 and the counter electrode 2 is provided, and water particles are released by applying a high voltage between the water particle emitting unit 1 and the counter electrode 2. The water of the part 1 constitutes an electrostatic atomizer B that generates nanometer-sized charged fine particle water, and the electrostatic atomizer B is provided in the sauna room A. According to this, in the nanometer-sized charged fine particle water generated by the electrostatic atomizer B, the particle diameter is smaller than the gap width between the skin stratum corneum, so The amount of water retained in the skin of the user when using the sauna can be maintained well from the inside.

  Moreover, the sauna room with an electrostatic atomizer according to claim 2 is the controller 11 according to claim 1, wherein the controller 11 that operates the electrostatic atomizer B simultaneously with the operation of the sauna apparatus 10 provided in the sauna room A is provided. It is provided. According to this, the electrostatic atomizer B is also operated at the same time when the sauna is operated by the control unit 11, and the charged fine particles that the electrostatic atomizer B always generates in the skin of the user who is using the sauna. The water is infiltrated, so that the water retention amount of the skin of the user while using the sauna can be reliably maintained.

  Moreover, the sauna room with an electrostatic atomizer according to claim 3 is that in claim 1, the sauna apparatus 10 provided in the sauna room A is composed of a wet sauna apparatus 10a for injecting heated mist. Features. The inside of the wet sauna room A1 provided with the wet sauna apparatus 10a for injecting heated mist is in a high humidity environment and is in an environment where germs such as molds are easy to propagate. However, in the charged fine particle water produced by the electrostatic atomizer B, the active species having a characteristic that it exhibits a high sterilizing effect due to its high reactivity but has a short life when present alone. In other words, the active species is encapsulated in water molecules, resulting in a long lifespan.As mentioned above, the nanometer size is extremely small, so it can float in the air for a long time. In addition, since it is highly diffusible and can reach every corner of the sauna room A1, it can also enter the inside of the wall when attached to the inside of the sauna room A1, so the sauna room A1. The disinfection effect can be exerted not only on the inside air but also on the inside of the wall of the sauna room A1. Therefore, it is possible to effectively suppress the propagation of germs and other germs that are a concern in the wet sauna room A1 in a high humidity environment.

  A sauna room with an electrostatic atomizer according to claim 4 is characterized in that, in claim 1, the sauna apparatus 10 provided in the sauna room A is constituted by a dry sauna apparatus 10b that generates radiant heat. To do. Although the indoor air of the dry sauna room A2 equipped with the dry sauna apparatus 10b that generates radiant heat is in a dry state, the amount of water retained in the sauna user's skin is significantly reduced. Since the charged fine particle water penetrates into the skin of the sauna user and improves the amount of water retained in the skin, maintenance of the amount of water retained by the charged fine particle water is maintained for users who particularly need skin water retention. The effect can work effectively.

  Further, the sauna room with an electrostatic atomizer according to claim 5 is characterized in that, in claim 3, a control unit 11 for operating the electrostatic atomizer B after the operation of the sauna apparatus 10 is provided. . According to this, the sterilization effect by the charged fine particle water generated by the electrostatic atomizer B can be applied to the wet sauna room A1 after use of the sauna in which the atmosphere of high humidity remains, and it is possible to remove germs such as mold. Breeding can be effectively suppressed.

  Further, the sauna room with an electrostatic atomizer according to claim 6 is the condensation according to any one of claims 1 to 5, wherein water is supplied by causing the electrostatic atomizer B to condense moisture in the air. A water generation device 7 is provided. According to this, since the water necessary for generating the charged fine particle water can be obtained from the moisture in the air, it is possible for the user to appropriately supply the water necessary for generating the charged fine particle water to the electrostatic atomizer B. Therefore, the usability of the electrostatic atomizer B can be greatly improved.

  Moreover, the sauna room with an electrostatic atomizer according to claim 7 is the air channel 21 provided in the air circulation device C for circulating the air in the sauna room A according to claim 6 from the upstream side to the downstream side. The filter 22 for cleaning the air and the electrostatic atomizer B are arranged in this order. According to this, dew condensation water can be obtained by the dew condensation water generating device 7 of the electrostatic atomizer B from the air cleaned by the filter 22, that is, based on clean water from the cleaned air. Charged particulate water can be generated, and contamination in the sauna room A due to dirty charged particulate water can be prevented.

  In the nanometer-sized charged fine particle water generated by the electrostatic atomizer arranged in the sauna room, the particle diameter is smaller than the gap width between the skin stratum corneum. Can penetrate into the inside of the skin from the inside, and has an advantage that the water retention amount of the skin of the user when using the sauna can be maintained well from the inside.

  Hereinafter, the present invention will be described based on embodiments shown in the accompanying drawings.

  1 to 6 show examples of embodiments of the present invention. The sauna room A of this example is a so-called dry-type sauna room A2 as shown in FIGS. 1 to 3, and is of a size suitable for home use where one person can enjoy the sauna. The sauna room A is composed of a box-shaped sauna room body 12 that is open to the front surface formed by the side plate 12a, the top plate 12b, the bottom plate 12c, and the back plate 12d. Is pivotally supported by one side plate 12a, and the other end is attached to be openable and closable so as to contact the other side plate 12a. Inside the sauna room main body 12, surface heaters 14, which are dry-type sauna devices 10b that generate radiant heat, are provided on both side plates 12a and the back plate 12d, respectively, and a horizontal plate-like stool 15 on the back plate 12d side. Is provided. In the lower space of the seat chair 15, an air circulation unit C that circulates air in the sauna room A and an air conditioning unit 17 in which an electrostatic atomizing device B is built are placed along the back plate 12d. In this manner, it is placed on the bottom plate 12c. In addition, the sauna room A is provided with a control unit 11 that controls the operation of the lighting attachment box 16, the surface heater 14, and the air conditioning unit 17, and this control unit 11 is placed on the top 12b. Is provided.

  As shown in FIG. 4, the air conditioning unit 17 is provided with a suction port 19 for sucking air on the front surface of the housing 18 and a discharge port 20 for discharging air on the upper surface of the housing 18. In the air flow path 21 connecting the suction port 19 and the discharge port 20, a filter 22, a fan 23, and an electrostatic atomizer B are arranged in this order from the upstream side to the downstream side of the air flow. Has been. Here, the filter 22 is configured by laminating a fine mesh layer 22a for removing dust and the like, an activated carbon layer 22b for adsorbing odorous components, or an oxidation catalyst honeycomb layer (not shown) for decomposing odorous components.

  As shown in FIGS. 5 to 7, the electrostatic atomizer B includes a water particle emitting unit 1 and a counter electrode 2 that function as a pair of electrodes, and a water particle emitting unit 1 and a counter electrode 2 to which water is supplied. A voltage application unit 3 for applying a high voltage between them, and applying a high voltage between the water particle emitting unit 1 and the counter electrode 2 to charge the nanometer size from the water of the water particle emitting unit 1 It is an apparatus for generating fine particle water M.

  Here, for example, the electrostatic atomizer B shown in FIG. 5 is used. Specifically, the electrostatic atomizer B of this example includes a liquid reservoir 4, a rod-shaped transport unit 5 made of a porous material immersed in water whose lower end is placed in the liquid reservoir 4, and these transports A liquid application electrode 6 for holding the unit 5 and applying a voltage to water; a counter electrode 2 facing the water particle emitting unit 1 at the tip of the transport unit 5; the liquid application electrode 6 and the counter electrode 2; And a voltage application unit 3 for applying a high voltage.

  Both the counter electrode 2 and the liquid application electrode 6 are formed of a synthetic resin mixed with a conductive material such as carbon or a metal such as SUS. The transport unit 5 is formed of a porous material in a rod shape. In this embodiment, the transport unit 5 is made of ceramic particles having a particle size of 2 to 500 μm, and the pores in the gap are arranged in an open cell shape with 1 to 250 μm. It is formed. The upper end of the transport unit 5 is a needle-shaped water particle discharge unit 1, and the upper part of the transport unit 5 projects upward from the liquid application electrode 6, and the lower part projects downward from the liquid application electrode 6. It comes into contact with water stored in the reservoir 4.

  The counter electrode 2 is grounded, and the voltage application unit 3 is connected to the liquid application electrode 6 to apply a high voltage, and the transport unit 5 formed of a porous material is put into the liquid storage unit 4 by capillary action. When water is sucked up, the water particle discharge part 1 at the upper end of the transport part 5 functions as a substantial electrode on the liquid application electrode 6 side. The voltage application unit 3 is preferably one that can provide an electrolytic strength of 500 V / mm or more, particularly 700 to 1200 V / mm.

  And by applying a high voltage between the conveyance part 5 and the counter electrode 2 by the voltage application part 3, the water W of the water particle discharge | release part 1 receives big energy by a high voltage, and exceeds a surface tension, and is split | disrupted. Electrostatic atomization that causes so-called Rayleigh splitting to generate mist M (for example, 10 to 30 nanometers) of ions having a particle size of nanometer size is performed. At this time, reactive species (hydroxy) that are generated at the same time are generated. Substances that are the source of deodorization and sterilization such as radicals and superoxide) are contained in the split water and jump out into the air.

  In this way, nanometer-sized charged fine particle water containing active species is generated from the water particle emitting portion 1. Active species are very reactive, and thus have a high effect on the decomposition of malodorous components and the suppression of mold generation. However, when they are present alone, their lifetime is short. However, in the nanometer-sized charged fine particle water obtained by the electrostatic atomizer B, the active species are present as if encapsulated in water molecules, and thus the life is increased, and as described above. Because it is very small with nanometer size, it floats in the air for a long time and has high diffusivity, and it can enhance the deodorizing effect in the air, the sterilization effect of mold and fungi, and the suppression effect of breeding in a wide range of space . Furthermore, since the charged fine particle water is as small as a nanometer size, it can enter the pores on the wall surface, and the odor and mold attached to the wall surface can be removed. The deodorization reaction formula of the active species contained in the odor and the charged water of nanometer size is shown below.

Ammonia 2NH ₃ +6 ・ OH → N ₂ + 6H ₂ O
Acetaldehyde CH ₃ CHO + 6 ・ OH + O ₂ → 2CO ₂ + 5H ₂ O
Acetic acid CH ₃ COOH + 4 ・ OH + O ₂ → 2CO ₂ + 4H ₂ O
Methane gas CH ₄ +4 ・ OH + O ₂ → CO ₂ + 4H ₂ O
Carbon monoxide CO + 2 ・ OH → CO ₂ + H ₂ O
Nitric oxide 2NO + 4 ・ OH → N ₂ + 2O ₂ + 2H ₂ O
Formaldehyde HCHO + 4 ・ OH → CO ₂ + 3H ₂ O
In the above deodorization reaction formula, .OH represents a hydroxy radical.

  By the way, although the charged fine particle water generated by the electrostatic atomizer B has the effect of suppressing the sterilization and propagation of mold and fungi and the deodorizing effect as described above, the electrostatic atomizer B is installed in the sauna room A. The main purpose of the arrangement is to supply charged fine particle water into the sauna room A to moisturize the skin of the user who is using the sauna. The charged fine particle water generated by the electrostatic atomizer B is discharged into the sauna room A from the outlet 20 of the air conditioning unit 17, and this charged fine particle water is a very small water particle having a nanometer size. Because the particle size is smaller than the gap width between the skin stratum corneum, it can penetrate into the skin through the gap between the skin stratum corneum, and the water retention amount of the user's skin when using the sauna is improved from the inside It can be maintained.

Moreover, it is also preferable to use the electrostatic atomizer B shown in FIG. In the example of the electrostatic atomizer B shown in FIG. 6, the dew condensation water production | generation apparatus 7 which supplies water to the water particle discharge | release part 1 by condensing the water | moisture content in air is provided. Specifically, the condensed water generation device 7 is configured by a Peltier unit including a heat radiating unit 8 and a cooling unit 9. In the Peltier unit, a pair of Peltier circuit boards P (P ₁ , P ₂ ) in which a circuit is formed on one side of an insulating plate Z made of alumina or aluminum nitride having high thermal conductivity, the circuit sides face each other. The Peltier input lead wires L are sandwiched between the Peltier circuit boards P ₁ and P _{2 and the} adjacent thermoelectric elements N are electrically connected by the circuits on both sides. which it was provided as heat is transferred towards the one Peltier circuit board P ₁ side by energizing the thermoelectric elements N, made by the Peltier unit power supply 40 to the other Peltier circuit board P ₂ side through the , connect the other Peltier circuit board P ₂ to the radiator 8 side with connecting Peltier circuit board P ₁ of the one in the cooling section 9 side. As in the present embodiment shown in FIG. 6, with connecting insulation plates Z provided with a Peltier circuit board P ₂ to the heat radiation fins 24 of the radiator 8, cooling to below the insulating plate Z provided with a Peltier circuit board P ₁ The unit 9 is connected.

  The cooling unit 9 is formed in a substantially dish shape that opens upward so that the liquid reservoir 4 that can store the dew condensation water W is formed therein, and the liquid application electrode 6 is formed on the inner upper surface of the cooling unit 9. Is provided. The liquid application electrode 6 has an upper end serving as the water particle discharge portion 1 and is formed of a porous material or has a fine hole or a fine groove (a fine hole 6a in the example of FIG. 6). The dew condensation water W stored in the cooling unit 9 is a transfer unit 5 that can transfer the dew condensation water W to the water particle discharge unit 1 at the upper end that becomes a discharge unit by capillary action. In addition, by forming the water particle emitting portion 1 with metal or forming a metal surface film to form a surface with high thermal conductivity and being attached to be thermally connected to the cooling portion 9, The condensed water W may be condensed directly on the surface of the water particle discharge unit 1 and the condensed water W may be electrostatically atomized to generate nanometer-sized charged fine particle water. Alternatively, the liquid application electrode 6 may be provided on the transport portion 5 made of porous ceramic or the like whose upper end portion becomes the water particle discharge portion 1.

  Since the electrostatic atomizer B in FIG. 6 automatically supplies water for generating charged fine particle water, the user appropriately supplies water for generating charged fine particle water to the liquid reservoir 4. Compared with the electrostatic atomizer B of FIG. 5 that has to be replenished, there is an advantage that the usability is remarkably improved. Moreover, the electrostatic atomizer B is arrange | positioned downstream from the filter 22 in the air flow path 21 of the air-conditioning unit 17 which is the air circulation apparatus C as mentioned above, and after this is cleaned with the filter 22 Condensed water can be obtained from the air by the condensed water generating device 7, that is, it is possible to generate charged fine particle water based on clean water from the cleaned air, and thus contaminated charged fine particles. Contamination of the sauna room A with water is prevented.

  Thus, the air-conditioning unit 17 incorporating the electrostatic atomizer B is disposed in the dry sauna room A2 of this example, and the electrostatic atomizer is placed on the circulating air in the sauna room A by the air-conditioner unit 17. Since the charged fine particle water generated in B is discharged into the sauna room A, the charged fine particle water penetrates into the skin through the gaps between the skin of the user's skin when using the sauna, and the user when using the sauna. The water retention amount of the skin can be maintained well from the inside. Specifically, the dry sauna room A2 originally had a problem that the indoor air in the sauna room A was in a dry state, and the water retention amount of the user's skin when using the sauna was significantly reduced. By arranging the electrostatic atomizer B in the dry sauna room A2 as in this example, it is possible to effectively give the skin moisture retention effect to the user who needs the skin moisture retention. It is a thing. Further, in this example, since the operation of the surface heater 15 and the operation of the air conditioning unit 17 are performed simultaneously by the control unit 11, water retention by charged fine particle water is surely performed inside the user's skin when using the sauna. An effect can be given.

  In this example, the air conditioning unit 17 is disposed in the lower space of the sitting chair 15 in the sauna room A1, but the air conditioning unit 17 is not limited to this position as long as it does not interfere with the use of the sauna. It can be at any position. In addition, the radiation direction of the charged fine particle water from the water particle emitting unit 1 is substantially the same as the opposing direction (arrow D) between the counter electrode 2 and the water particle emitting unit 1. When there is an obstacle such as a sitting chair 15 near the upper portion of the discharge port 20, the counter electrode 2 and the water particle discharge unit 1 of the electrostatic atomizer B are discharged from the air conditioning unit 17 as in the example of FIG. The exposed charged fine particle water is obstructed by facing the outlet 20 and forming the facing direction of the counter electrode 2 and the water particle emitting portion 1 so that an obstacle such as a sitting chair 15 is directed in an appropriate direction not on the extension line. You may make it regulate the radiation | emission direction of the charged fine particle water from the water particle discharge | release part 1 so that it may not hit against an object.

  8 to 10 show other examples of the embodiment of the present invention. The sauna room A of this example is constituted by a bathroom 25 provided with a wet sauna apparatus 10a for injecting heated mist. A washing place 27 is provided in the bathroom 25 so as to be adjacent to the bathtub 26, a rising wall 28 is provided on the floor pan of the washing place 27, and a counter 29 is integrally provided at the upper end of the rising wall 28. A faucet 30 such as a hot and cold water faucet is installed on the upper surface of the counter 29, and a wall surface 25 a of the bathroom 25 rises from the rear of the counter 29. A wet sauna device 10 a is installed on the front side of the rising wall 28 at a position corresponding to the faucet 30, and a front cover 31 covering the front surface of the sauna device 10 is arranged. In addition, it is preferable that the front cover 31 covers not only the front surface side but also the upper surface side of the wet sauna device 10a. A mist outlet 32 is provided at the lower portion of the front cover 31, and the mist generated by the wet sauna apparatus 10a is blown out from the mist outlet 32 into the bathroom 25. The wet sauna apparatus 10a is an apparatus for injecting heated mist. As shown in FIG. 9, a mist nozzle 33, a heater (not shown), an electric valve 34, a thermostat 35, a constant flow valve 36, a stop cock 37, A hot water outlet 38 and the like are provided. According to this wet type sauna apparatus 10a, mist is blown out into the bathroom 25 from the mist outlet 32, and a sauna bath in a state where the mist is filled in the bathroom 25 can be performed. A basin table 39 is disposed on the upper surface of the wet sauna apparatus 10a and is attached to the rising wall 28 with a bracket or the like. This basin cradle 39 is one step lower than the upper surface of the counter 29, and when the basin is placed on the basin cradle 39, the basin can be positioned directly below the spout 30a of the faucet 30. . In the bathroom 25, an air-conditioning unit 17 containing the same electrostatic atomizer B as in the previous example is arranged. Although the arrangement position of this air conditioning unit 17 is arbitrary, in this example, it is attached to the wall surface 25a of the bathroom 25 which stands up from the back of the counter 29 in order to prevent the bath water from being caught. The operation control of the wet sauna device 10a and the air conditioning unit 17 is performed by the control unit 11 disposed on the ceiling of the bathroom 25 (FIG. 10). The operation control of the wet sauna device 10a and the air conditioning unit 17 by the control unit 11 is performed in the same manner as the previous example, in addition to the air conditioning unit 17 being operated simultaneously with the operation of the wet sauna device 10a. The air conditioning unit 17 is controlled so as to continue to operate for a predetermined time after the end of the operation.

  In such a wet sauna room A1, a sauna bath is performed by injecting the mist heated by the wet sauna apparatus 10a into a high humidity environment. Even in the sauna bath in the wet sauna room A1, the user who is using the sauna sweats and the amount of water retained in the skin is reduced. Specifically, since the moisture in the bathroom 25 in a high humidity environment is filled with mist, the moisture on the surface of the skin in contact with the mist does not decrease significantly. Since it is larger than the gap width between the stratum corneum of the skin, it does not penetrate into the inside of the skin. Therefore, the amount of water retained inside the skin of the user when using the sauna is reduced. However, the air conditioning unit 17 incorporating the electrostatic atomizer B is disposed in the bathroom 25 which is the wet sauna room A1 of the present example, and the air conditioning unit 17 together with the wet sauna device 10a is controlled by the operation control of the control unit 11. Since the charged particulate water generated by the electrostatic atomizer B is discharged into the bathroom 25 by being put on the circulating air in the bathroom 25 by the air conditioning unit 17, the control unit 11 ensures that the air conditioning unit is used when using the sauna. 17 is operated so that charged fine particle water can penetrate into the skin of the user when using the sauna, and the water retention amount of the user's skin when using the sauna can be maintained well from the inside.

  By the way, the wet sauna room A1 is in a high humidity environment during the operation of the wet sauna apparatus 10a for injecting heated mist, and therefore, it is in an environment in which various germs such as mold are likely to propagate. However, the air conditioning unit 17 incorporating the electrostatic atomizer B is disposed in the bathroom 25 which is the wet sauna room A1 of this example, and the electrostatic atomization is carried on the circulating air in the bathroom 25 by the air conditioning unit 17. Since the charged fine particle water generated by the apparatus B is released into the bathroom 25, the propagation of various germs such as mold in the bathroom 25 is suppressed. Specifically, the charged fine particle water generated by the electrostatic atomizer B exhibits a high sterilizing effect because of its high reactivity, but has an activity having a short life when present alone. Species are inherent, that is, active species exist as if encapsulated in water molecules, so the lifetime is long, and as mentioned above, it is very small with nanometer size, so it floats in the air for a long time. It is possible to spread to every corner of the bathroom 25, and when it adheres to the inside of the wall in the bathroom 25, it can also enter the inside of the wall. The sterilizing effect can be exerted not only on the air but also on the inside of the bathroom 25 and the like. Therefore, the propagation of germs such as molds that are a concern in the wet sauna room A1 is effectively suppressed. In this example, the air conditioning unit 17 is continuously operated by the control unit 11 for a predetermined time after the operation of the sauna device 10 is completed. The sterilization effect by the charged fine particle water generated by the atomizer B can be exerted, and the propagation of germs such as mold is effectively suppressed.

It is front sectional drawing of the sauna room of the example of embodiment of this invention. It is side surface sectional drawing same as the above. It is a perspective view same as the above. It is a schematic side view of an air conditioning unit same as the above. It is a schematic side view of the example of an electrostatic atomizer same as the above. It is a schematic side view of the other example of the electrostatic atomizer same as the above. It is a schematic side view of the other example of the electrostatic atomizer same as the above. It is a perspective view of the principal part of the sauna room of other examples of an embodiment of the invention. It is a sectional side view of the principal part same as the above. It is a perspective view of a sauna room same as the above.

Explanation of symbols

A Sauna Room A1 Wet Sauna Room A2 Dry Sauna Room B Electrostatic Atomizer C Air Circulation Device 1 Water Particle Discharge Part 2 Counter Electrode 3 Voltage Application Part 7 Condensation Water Generation Device 10 Sauna Device 10a Wet Sauna Device 10b Dry sauna device 11 Control unit 21 Air flow path 22 Filter

Claims (7)

  A water particle emitting unit, a counter electrode facing the water particle emitting unit, and a voltage applying unit for applying a high voltage between the water particle emitting unit to which water is supplied and the counter electrode. The electrostatic atomizer is configured so that the water in the water particle discharge part generates nanometer-sized charged fine particle water by applying a high voltage between the electrode and the counter electrode, and the electrostatic atomizer is provided in the sauna room. A sauna room with an electrostatic atomizer.   The sauna room with an electrostatic atomizer according to claim 1, further comprising a control unit that operates the electrostatic atomizer simultaneously with the operation of the sauna apparatus provided in the sauna room.   The sauna room with an electrostatic atomizer according to claim 1, wherein the sauna apparatus provided in the sauna room is configured by a wet sauna apparatus that ejects heated mist.   The sauna room with an electrostatic atomizer according to claim 1, wherein the sauna apparatus provided in the sauna room is constituted by a dry type sauna apparatus that generates radiant heat.   4. The sauna room with an electrostatic atomizer according to claim 3, further comprising a control unit that operates the electrostatic atomizer after the operation of the sauna apparatus is completed.   6. The sauna with an electrostatic atomizer according to any one of claims 1 to 5, further comprising a condensed water generating device that supplies water by causing moisture in the air to condense in the electrostatic atomizer. Room.   The static air filter according to claim 6, wherein a filter for cleaning air and an electrostatic atomizer are arranged in order from an upstream side to a downstream side in an air flow path provided in an air circulation device for circulating air in a sauna room. Sauna room with electric atomizer.

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