JP4905232B2 - Mist generating device and bathroom heating device provided with the same - Google Patents

Description

  The present invention relates to a mist generating device capable of misting (misting, making fine particles) a liquid such as water, and a bathroom heating device provided with the mist generating device.

  Specific examples of the conventional mist generator include those described in Patent Documents 1 to 3. What is described in these documents includes, for example, a case having a liquid storage part for storing water therein, a rotor rotated by a motor, and a collision wall part located around the rotor. Yes. When the rotor rotates, the water in the liquid storage part is sucked up by the rotor, and then scattered around the water and collides with the collision wall part. By this collision, the water is made into fine water droplets, and mist is generated.

  However, in the prior art, there are points to be improved as described below.

  That is, when generating mist, it may be required to make the particle diameter as small and uniform as possible. For example, when installing a mist generator in a bathroom and using it for a mist shower, to make this mist feel better, make the particle size as small as possible and avoid mixing many large particles. It is desirable to do.

  On the other hand, conventionally, a collision wall portion for causing water to collide to generate mist is made of synthetic resin or metal, and its surface has relatively high water repellency. At first glance, it is considered that the higher the water repellency of the collision wall part, the more difficult the water is to adhere to the surface, which is convenient for generating mist. However, as a result of studies by the inventors, the following has been found. That is, when water is continuously collided with the surface having high water repellency from the rotor, water droplets are likely to be generated on the surface due to the water repellency effect. Then, the proportion of water that indirectly collides with the surface of the collision wall through this water droplet increases, and the particle size of the mist generated in this way is due to the fact that water directly collides with the surface of the collision wall. Compared to the particle size of the mist obtained, it is considerably large. Conventionally, many mists having a large particle size are generated by such a mechanism. Further, a part of the mist generated by the collision of water with the collision wall is brought into contact with the water droplets on the surface of the collision wall and absorbed. Thereby, the effect | action which the generation amount of fine mist reduces more has also arisen.

Japanese Patent Publication No. 1-101414 Japanese Patent No. 3671202 JP 2001-289470 A

  The present invention has been conceived under the circumstances as described above, and includes a mist generator capable of generating a large amount of mist having a finer and uniform particle size, and the same. The problem is to provide a bathroom heating device.

  In order to solve the above problems, the present invention takes the following technical means.

A mist generator provided by the first aspect of the present invention collides a rotor capable of splashing liquid around by a centrifugal force, and a liquid located around the rotor and splashed from the rotor. A plurality of collision wall portions for making the liquid into a mist, and a case in which the rotor is housed and the plurality of collision wall portions are formed. a generating apparatus, the plurality of the collision wall portion, together with the surface thereof is hydrophilic treated surface, aligned radially around the rotor, and is formed in a rib shape extending in the normal direction of the rotor A portion of the gap between the plurality of collision wall portions that is closer to the outer periphery of the case is configured as a mist jet port formed in the peripheral wall portion of the case, and the liquid is applied to the plurality of collision wall portions. collision Mist generated by Rukoto is characterized in that it is configured so as to pass through the gap jetted around the casing from the mist spray port.
Here, the “hydrophilic treatment surface” as used in the present invention refers to a surface subjected to a hydrophilic treatment, for example, when a surface is subjected to a hydrophilic treatment after the formation of a collision wall portion, or a hydrophilic treatment is performed in advance. Either of the case where the collision wall portion is formed using a material may be used. A specific example for performing the hydrophilic treatment will be described in the description section of the later embodiment.

  According to such a configuration, since the surface of the collision wall portion is a hydrophilic treatment surface, when a liquid collides against the collision wall portion, it is difficult to generate a droplet (water droplet) on the surface. . Therefore, the proportion of water splashed from the rotor indirectly colliding with the collision wall portion via the droplets can be reduced, and a large amount of water can be directly collided with the surface of the collision wall portion. As a result, a large amount of mist having a fine particle size can be generated. In addition, the proportion of fine mist absorbed by contact with the droplets on the surface of the collision wall can be reduced.

In a preferred embodiment of the present invention, the apparatus further includes a liquid storage section provided at the bottom of the case and capable of storing liquid supplied from the outside. The rotor includes a rotating plate and the rotating plate. A shaft-like portion extending downward from the liquid storage portion and partially immersed in the liquid in the liquid storage portion, and at the time of rotation, the liquid in the liquid storage portion rises to the rotating plate by the shaft-like portion, and this rotation Among the liquid splashed from the rotor around the collision wall portion, the liquid that was not ejected to the outside of the case is transmitted along the inner surface of the case. It is comprised so that it may return to the said liquid storage part, and the inner surface of the said case is also made into the hydrophilic treatment surface.

  According to such a configuration, of the liquid scattered toward the collision wall portion, the liquid that was not ejected as mist to the outside of the case is returned to the liquid storage portion provided at the bottom portion of the case, and again becomes mist. Used for Therefore, there is no difficulty in processing the liquid that has not been ejected to the outside of the case, and an effect of suppressing the liquid consumption can be obtained. Furthermore, the inner surface of the case is also treated with a hydrophilic treatment. However, since it is difficult for droplets (water droplets) to be generated on the inner surface of the case, the liquid easily flows from the upper part to the lower part of the case inner surface. The liquid recovery to the liquid storage part is facilitated. Further, when it becomes difficult for droplets to be generated, the inside of the case is easily dried when the mist generator is turned off. For example, when the mist generating device is installed in a bathroom or the like and used for a mist shower or the like, it is suitable for preventing the growth of mold and bacteria in the case and making it hygienic.

In a preferred embodiment of the present invention, the outer surface and a bottom lower surface of the peripheral wall portion of the case also, there is a hydrophilically treated surface.

  According to such a configuration, when the mist ejected from the mist outlet to the periphery of the case is brought into contact with the outer surface of the peripheral wall portion or the bottom lower surface of the case to form droplets (water droplets), the droplets The effect which can suppress falling below is acquired. That is, unlike the above-described configuration, when the water repellency of the outer surface of the peripheral wall portion or the bottom surface of the case is high, large-sized liquid droplets are generated in this portion and easily fall below the case. According to this, such a situation is suppressed. Therefore, for example, when a mist generating device is installed and used in the upper part of a bathroom, it is suppressed that many water drops dripping on a bather's body.

  In a preferred embodiment of the present invention, the surface of the rotor is also a hydrophilic treatment surface.

  According to such a configuration, it is possible to make it difficult for droplets (water droplets) to be generated on the surface of the rotor, so that it is easy to dry the rotor when the operation of the mist generator is stopped. Therefore, when the mist generating device is installed and used in a bathroom or the like, it is preferable to prevent the growth of mold and bacteria.

  The bathroom heating device provided with the mist generating device provided by the second aspect of the present invention includes a case installed in the upper part of the bathroom, the air in the bathroom sucked into the case, and the air blower A bathroom heating device comprising: a fan blown out into the bathroom; and heating means capable of heating the air sucked into the case by driving of the fan, provided by the first aspect of the present invention. The mist generating device is further provided, and the mist generating device is configured so that water as the liquid is misted and the mist is supplied to the bathroom.

  According to such a configuration, an effect similar to that described for the mist generator provided by the first aspect of the present invention can be obtained. Moreover, it becomes possible to utilize a bathroom heating apparatus as a bracket of a mist generator, and the construction work of a mist generator can also be abbreviate | omitted or simplified. Furthermore, when the operation of the mist generating device is stopped, each part of the mist generating device can be actively dried by the heating action of the bathroom heating device to make it more hygienic.

  Other features and advantages of the present invention will become more apparent from the following description of embodiments of the present invention with reference to the accompanying drawings.

  Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings.

  1 and 2 show an example of a bathroom heating device provided with a mist generator to which the present invention is applied. The bathroom heating device H of this embodiment is attached to a ceiling 80 of a bathroom such as a unit bath, and a mist generating device MG is attached to the panel 41 of the bathroom heating device H. Prior to the description of the bathroom heating device H, the configuration of the mist generating device MG will be described with reference to FIGS.

  As clearly shown in FIG. 3, the mist generator MG includes a case 1, a rotor 2, and a motor M.

  The case 1 is made of, for example, a synthetic resin such as polycarbonate, and the overall schematic shape is a cup shape having a circular shape in plan view with an upper portion opened. The case 1 is attached to the lower surface portion of the panel 41 using a plurality of screw holes 10 provided in the upper portion thereof and a screw body 90 screwed into these. The case 1 includes a plurality of rib-shaped collision wall portions 12, a plurality of mist ejection ports 13, a liquid storage portion 14, a drainage hole portion 16, and a plurality of air inflow ports 15.

  The plurality of collision wall portions 12 are portions for causing the water to collide when the rotor 2 rotates and water is scattered from the rotor 2 to the periphery thereof, and mist is generated by the collision. As shown in FIGS. 4 and 6, the plurality of collision wall portions 12 are configured as ribs arranged radially at substantially equal intervals around the central axis of the case 1. Each collision wall portion 12 has a uniform thickness and extends in the radial direction of the case 1, and substantially the entire surface thereof is a hydrophilic treatment surface. As the hydrophilic treatment means, for example, means for generating active species on the target surface such as corona discharge treatment, plasma treatment, ultraviolet irradiation treatment, means for applying a primer or other hydrophilic substance to the target surface, or on the target surface Various means such as a means for roughening the target surface by performing etching or blasting treatment can be employed (the roughening treatment is also included in the hydrophilic treatment in the present invention). When the collision wall 12 is made of a synthetic resin, the collision wall 12 may be molded into a state including a hydrophilic material, and the collision wall 12 itself may be a hydrophilic material. Such a point is the same when other portions of the case 1 and the rotor 2 are subjected to hydrophilic treatment, as will be described later.

  The plurality of mist outlets 13 communicate with the gaps 11 between the adjacent collision wall portions 12 and open to the peripheral wall portion of the case 1. More specifically, the case 1 is configured such that the upper side and the lower side thereof are connected via a plurality of rib-shaped collision wall portions 12. Of the gaps 11 between the collision wall portions 12, the case 1 The portion closest to the outer periphery of 1 is open as it is. The opening portion is a mist ejection port 13, and mist generated by water colliding with the plurality of collision wall portions 12 passes through the mist ejection port 13 and is ejected around the case 1.

  The liquid reservoir 14 is formed at the bottom of the case 1, and an appropriate amount of water can be stored in the liquid reservoir 14. As a means for supplying water to the liquid storage section 14, for example, as shown in FIG. 3, a water supply pipe 92 is inserted into a hole 410 provided in the panel 41, and water is supplied from the water supply pipe 92 to the bottom of the case 1. Means for performing is used. For example, a constant flow pump P is provided in the water supply pipe 92, and the liquid storage unit 14 can be supplied with water by driving the constant flow pump P.

  The case 1 is formed so that the diameter in the vicinity of the bottom portion is smaller than the portion where the mist ejection port 13 of the peripheral wall portion is formed, thereby reducing the capacity of the liquid storage portion 14. Yes. Of the peripheral wall portion of the case 1, most of the inner surface in the range from the vicinity of the formation position of the mist ejection port 13 to the liquid storage portion 14 is an inclined surface, and water droplets adhering to the inner surface smoothly flow into the liquid storage portion 14. It is configured to flow. Similarly, in the peripheral wall portion of the case 1, the outer surface of the lower portion of the peripheral portion of the case 1 is also inclined, and the lower portion of the inclined surface is smoothly connected to the bottom surface of the bottom of the liquid storage portion 14. ing. A protruding portion 17 that protrudes toward the periphery of the case 1 is formed at the lower edge portion of the mist ejection port 13. As will be described later, the protrusion 17 serves as a guide for receiving water flowing from above the protrusion 17 and flowing it into the case 1. Similar to the collision wall 12, substantially the entire area of the inner surface and the outer surface of the case 1 is a hydrophilic treatment surface.

  The plurality of air inlets 15 are portions for allowing external air to flow into the case 1 from below. When the rotor 2 rotates at a high speed, air around the rotating plate 20 described later becomes turbulent, and this turbulent flow disturbs the operation of generating mist, which causes variation in the mist particle size. On the other hand, if external air is supplied to the lower part of the rotating plate 20 from the plurality of air inlets 15, the above-described turbulent flow can be suppressed. A cylindrical portion 15 a erected upward is provided at the bottom of the case 1 or in the vicinity thereof, and the inside is an air inlet 15. According to such a configuration, the upper part of the air inlet 15 is made higher than the water level of the liquid storage part 14 so that the water in the liquid storage part 14 does not flow down from the air inlet 15 to the lower part of the case 1. Can do. Further, the upper part of the air inlet 15 can be brought close to the rotating plate 20 of the rotor 2.

  The motor M is for driving the rotor 2, is mounted on the panel 41, and is disposed outside the case 1. The panel 41 also plays a role of partitioning between the motor M and the case 1. However, an air circulation portion 33 for allowing external air to flow into the case 1 from the upper side is formed in a portion where the motor M is attached to the panel 41. The air circulation part 33 includes a gap 33a formed by interposing a spacer 32 between the plate part 31 supporting the motor M and the panel 41, and external air formed in the panel 41 and passing through the gap 33a. And an opening 33b that flows into the case 1. Since external air is also supplied to the upper region of the rotating plate 20 of the rotor 2 via the air circulation portion 33, it is possible to more thoroughly suppress the turbulent flow in the air around the rotating plate 20.

  The rotor 2 is supported by the shaft portion 30 of the motor M and is rotatable in the case 1. The rotor 2 includes a disk-shaped rotating plate 20 and a shaft-shaped portion 21 that protrudes downward from the central portion of the rotating plate 20. Have. The rotary plate 20 and the shaft-like portion 21 are integrally formed of synthetic resin, but substantially the entire outer surface of these is also a hydrophilic treatment surface.

  The shaft-like portion 21 of the rotor 2 has a conical shape or truncated cone shape with a larger diameter toward the upper portion, and the lower portion thereof is inserted into a drain hole 16 formed at the bottom of the liquid storage portion 14. . A gap of, for example, about 1 to 3 mm is formed between the inner peripheral surface of the hole portion 16 and the outer peripheral surface of the shaft-shaped portion 21. During the rotation of the rotor 2, as will be described later, the water in the liquid storage part 14 does not leak from the hole part 16, and part of the water rises as a water film along the outer peripheral surface of the shaft-like part 21, It is fried to the lower surface of the rotating plate 20. Then, this water is accelerated from the central region of the rotating plate 20 toward the outer periphery by centrifugal force, and is scattered around the rotating plate 20 and collides with the plurality of collision wall portions 12 to generate mist. .

FIG. 7 is a diagram for explaining the principle of the operation described above. With reference to the figure, the principle of rising by forming a water film on the outer peripheral surface of the shaft-like portion 21 will be described first.
Considering the minute element ΔW of the water film on the outer peripheral surface of the shaft-shaped portion 21, the adhesive force F of water to the outer peripheral surface of the shaft-shaped portion 21 is generated in the direction orthogonal to the outer peripheral surface. If the mass of the minute element ΔW is m, mg acts downward in the vertical direction, but this can be decomposed into component forces mg _n and mg _t . In the horizontal direction, centrifugal force C (C = mrω ² , r: eccentric distance, ω: angular velocity) acts, but this can be broken down into component forces C _n and C _t . In order to prevent the minute element ΔW from being blown off from the outer peripheral surface of the shaft-shaped portion 21, it is sufficient if there is a balanced relationship of the following equation (1).
F = C _n + mg _n Formula (1)
Here, since the mass m of the minute element ΔW is m≈0, mg _n is small, and the centrifugal force C and its component force C _n are also small to satisfy the above formula (1). Is possible.
Further, in order for the minute element ΔW to increase, the relationship of the following equation (2) is sufficient.
C _t > mg _t formula (2)
Here, while mg _n is small, the value of C _t can be increased by increasing the rotational speed of the rotor 2 and increasing the angular speed ω, for example. Therefore, the above formula (2) can also be satisfied.
Thus, if the rotor 2 is rotated at a high speed so as to satisfy the above-described formulas (1) and (2), the pumping action of raising the water in the liquid storage part 14 along the outer peripheral surface of the shaft-like part 21 is achieved. Obtainable.

On the other hand, a force similar to that described above also acts on the minute element ΔW ′ located between the inner peripheral surface of the drain hole 16 and the outer peripheral surface of the shaft-shaped portion 21 and in the vicinity thereof. For this reason, a component force C _t ′ similar to the component force C _t described above works as a force that raises the minute element ΔW ′. With this action, when the rotor 2 rotates, the water in the liquid storage section 14 can be prevented from leaking downward from the gap of the hole section 16. Of course, when the rotation of the rotor 2 is stopped, the water in the liquid reservoir 14 leaks downward from the hole 16.

  As shown in FIG. 1, the mist generating device MG also includes an operation remote controller 6 and a control unit 7. However, in the present embodiment, the operation remote controller 6 and the control unit 7 are also used for the bathroom heating device H. The operation remote controller 6 can transmit data to the control unit 7 by performing infrared transmission to an infrared light receiving unit (not shown) provided in the bathroom heating device H, for example, to turn on / off the operation of the mist generating device MG. Command operations such as turning off are possible. The control part 7 is comprised using the microcomputer, for example, and performs operation control of each part of the mist generating apparatus MG and the bathroom heating apparatus H.

  Next, the configuration of the bathroom heating device H will be described.

  As shown in FIG. 1, the bathroom heating device H includes a case 4, a fan 50, and a heat exchanger 51 as an example of a heating unit. The case 4 accommodates the fan 50 and the heat exchanger 51 therein, and includes a case body 40 having a lower opening shape installed on the upper surface side of the ceiling plate 80 of the bathroom, and a panel 41 separate from this. Have. The panel 41 is attached to the ceiling plate 80 so as to close the opening 80 a formed in the ceiling plate 80 and the lower opening of the case main body 40. The panel 41 is provided with an air supply port 41a and a blower port 41b. The air outlet 41b is provided with a louver 42 that can change the air blowing direction.

  In the bathroom heating device H, when the fan 50 is driven, air is sucked into the case 4 from the air supply port 41 a and this air is heated by the heat exchanger 51. The heat exchanger 51 is configured using, for example, a plurality of finned tubes in which heated hot water can flow, and the intake air from the fan 50 is heated when passing between the plurality of tubes. . The heated air is guided to the louver 42 and blown out. The case 1 of the mist generator MG is located on the side of the louver 42.

  Next, the operation of the bathroom heating device H provided with the mist generator MG will be described.

  First, when the operation remote controller 6 is operated and an operation on command is issued, the control unit 7 starts driving the constant flow pump P. Thereby, the water supply to the liquid storage part 14 is started. The drive of the motor M is also started substantially simultaneously with this water supply or at an earlier time. Thereby, water leakage from the drain hole 16 can be prevented, and water can be stored in the liquid storage unit 14. A part of the water stored in the liquid storage part 14 is pumped up to the lower surface of the rotating plate 20 along the outer peripheral surface of the shaft-like part 21 by the rotating action of the shaft-like part 21 of the rotor 2 and then scatters around it. Then, it collides with a plurality of collision wall portions 12. The mist generated by the collision passes through the gap 11 between the collision walls 12 and the mist outlet 13 as it is, and is ejected around the peripheral wall of the case 1.

  Since the surface of the collision wall portion 12 is a hydrophilic treatment surface, the water that has collided with the collision wall portion 12 is unlikely to form water droplets having a relatively large size on the surface of the collision wall portion 12. For this reason, the ratio of the water splashed from the rotor 2 indirectly colliding with the collision wall portion 12 with a water droplet interposed therebetween is reduced, and a lot of water can be directly collided with the surface of the collision wall portion 12. As a result, a lot of mist having a fine particle size is generated. Further, the mist generated in this way is also prevented from being absorbed by contact with water droplets on the surface of the collision wall portion 12. Most of the mist is generated in the gap 11 of the collision wall 12, but the path from the gap 11 to the mist outlet 13 is straight and the distance is short. Therefore, the mist generated in the case 1 is easily ejected to the outside of the case 1, and the ratio of water droplets before reaching the mist ejection port 13 is reduced. For this reason, the amount of mist ejected to the outside of the case 1 can be increased.

  Some of the water scattered from the rotor 2 toward the collision wall 12 remains in the case 1 without being ejected outside the case 1. Such water is returned to the liquid storage part 14 along the inner surface of the case 1. Since the wide area | region of the inner surface of case 1 is made into the inclined surface, it is possible to make the above-mentioned water flow smoothly toward the liquid storage part 14. FIG. When the water that has not been ejected to the outside of the case 1 is returned to the liquid storage unit 14 in this way, the water is repeatedly sucked up by the rotor 2 and then repeatedly used for mist generation. Therefore, there is no problem that it is difficult to treat water that has not been ejected to the outside as mist. Moreover, the consumption of water can be suppressed and the amount of water supplied to the liquid storage unit 14 from the outside can be reduced.

  A part of the mist ejected around the case 1 may come into contact with the outer surface of the peripheral wall portion of the case 1, and water droplets may be generated in this portion. When such a phenomenon occurs, most of this water flows along the inclined surface of the outer surface of the case 1 to the bottom lower surface of the liquid storage section 14 and reaches the location where the drain hole 16 is formed. Then, this water is sucked into the hole 16 by the pumping action generated by the rotation of the shaft-like part 21 of the rotor 2 and flows into the liquid storage part 14. By such an action, it is possible to prevent many water droplets from dropping downward from the outer surface of the case 1. Moreover, since the outer peripheral surface of the peripheral wall part and the lower surface of the bottom part of the case 1 are hydrophilic treatment surfaces, it is difficult for large-sized water droplets to be generated in these parts. This more suitably prevents water drops from dropping from the outer surface of the peripheral wall portion of the case 1 and the lower surface of the bottom portion downward.

  When the mist is generated, for example, as shown in FIG. 1, when heated air is blown out from the air blowing port 41 b of the bathroom heating device H toward the lower part of the case 1 or near the lower part, the mist blown around the case 1 is heated. While being heated by the air, it is sent to a certain area in the bathroom along the flow of the heated air. Therefore, the user can concentrate on the warm mist. If the heating operation of the heat exchanger 51 is stopped, unheated mist can be bathed. Further, unlike these, it is also possible to stop the operation of the bathroom heating device H and use the mist generator MG alone in a state where the air blowing from the air blowing port 41b is stopped. In this case, the mist ejected around the case 1 only falls spontaneously, but the mist supply in such a manner is also rich in taste.

  When stopping the operation of the mist generating device MG, the water in the liquid storage unit 14 can be discharged downward from the hole 16 by immediately stopping the rotation of the rotor 2. However, in this case, there is a risk that the water will splash on the body of the bather. As a means for avoiding this, in the present embodiment, when the operation remote controller 6 is operated to turn off the operation, the control unit 7 turns off the constant flow pump P and stops the water supply to the liquid storage unit 14, The motor M continues to be driven for a while after that. As a result, the operation in which the water in the liquid storage unit 14 is misted and consumed is continued, and substantially the entire amount of water in the liquid storage unit 14 can be discharged to the outside of the case 1. The driving of the motor M may be stopped, for example, when a predetermined time has elapsed.

  Moreover, when the control part 7 stops the water supply to the liquid storage part 14, as shown in FIG. 2, it also performs control which blows warm air with respect to the case 1 from the ventilation opening 41b of the bathroom heating apparatus H. . When the bathroom heating apparatus H is already in an operating state as shown in FIG. 1, for example, it is possible to set the state shown in FIG. 2 may be set to the state shown in FIG. 2 after the operation of the bathroom heating device H is started. As described above, when the case 1 is blown with warm air, the case 1 and the rotor 2 are heated, and the water adhering to the case 1 and the rotor 2 is positively evaporated to sufficiently dry them. be able to. If water droplets having a large size are generated on the inner and outer surfaces of the case 1 or the surface of the rotor 2, it takes a long time to sufficiently dry the portion. Since the inner and outer surfaces and the surface of the rotor 2 are treated with hydrophilic surfaces to prevent such water droplets from being generated, the case 1 and the rotor 2 can be dried at an early stage. The bathroom heater H may be stopped when the predetermined time is up, for example.

  Since the mist generator MG is disposed in the upper part of the bathroom, when the operation is stopped, for example, shower water may be poured and the water may enter the case 1. On the other hand, a hole 16 is provided at the bottom of the case 1, and a gap through which water can easily pass is formed between the inner peripheral surface and the shaft-like portion 21 of the rotor 2. Therefore, the water can be appropriately discharged from this portion. As a result, when the operation is stopped, the water staying in the case 1 is preferably suppressed, and the case 1 can be excellent in terms of hygiene.

  8 and 9 show another embodiment of the present invention. In these drawings, elements that are the same as or similar to those in the above embodiment are given the same reference numerals as in the above embodiment.

  In the embodiment shown in FIG. 8, no drainage hole is provided at the bottom of the liquid reservoir 14, and the lower end of the shaft-like portion 21 of the rotor 2 penetrates the bottom of the liquid reservoir 14. Not. Even with such a configuration, the water in the liquid storage part 14 can be pumped up by the shaft-like part 21 and then scattered toward the collision wall part 12.

  In the embodiment shown in FIG. 9, the shaft-like portion 21 of the rotor 2 has a pipe shape having a hole 210. In the present embodiment, when the rotor 2 rotates, the water located in the hole 210 of the shaft-shaped portion 21 rises as a film along the inner peripheral surface of the hole 210 due to the action of centrifugal force, and rotates. It reaches the upper surface of the plate 20. Next, the water is accelerated by centrifugal force on the upper surface of the rotating plate 20 to form a water film, and scatters around the rotating plate 20. Therefore, water can be made to collide with the collision wall portion 12 even with such a configuration.

  The present invention is not limited to the embodiment described above. The specific configuration of each part of the mist generating device according to the present invention and the bathroom heating device including the mist generating device can be varied in design in various ways.

  As a rotor, unlike the above-described embodiment, for example, when water is supplied directly on a rotating plate using a water supply pipe or the like, this water is directly scattered around by a centrifugal force. It can also be adopted. The collision wall portion does not necessarily have a rib shape with a constant thickness. Further, the collision wall portion and the mist ejection port do not have to be provided over the entire circumference of the rotor. For example, the collision wall portion and the mist outlet should not be provided in a part of the area around the rotor. It can also be set as the structure by which the ejection was prevented. When the surface of the collision wall portion is a hydrophilic treatment surface, preferably, the entire surface is preferably a hydrophilic treatment surface, but is not limited thereto. For example, only a portion where water substantially collides is a hydrophilic treatment surface. May be. In the case where a liquid storage part is provided, the liquid storage part is preferably integrated with a case having a collision wall part and a mist ejection port, but is not limited to this, and can be formed separately from the case. .

  The mist generating apparatus according to the present invention is attached to a so-called wall-mounted bathroom heating apparatus that is attached to, for example, a location near the ceiling of the bathroom side wall, instead of the ceiling-mounted bathroom heating apparatus as in the above-described embodiment. It can also be used. Alternatively, for example, it may be directly attached to a ceiling part (ceiling panel or the like) of a bathroom and operated independently regardless of the presence or absence of the bathroom heating device.

  Although the mist generator according to the present invention is suitable for generating mist in a bathroom (including a shower room), its specific application is not limited to this. The mist generating apparatus according to the present invention can be used for various liquid fine particle applications or spray applications. For example, it can also be used as a device for atomizing paint, a spraying device for spraying agricultural chemicals, a spraying device for liquid fuel, and the like.

It is sectional drawing which shows an example of the bathroom heating apparatus provided with the mist generating apparatus which concerns on this invention. It is operation | movement explanatory drawing of the bathroom heating apparatus provided with the mist generating apparatus shown by FIG. It is principal part sectional drawing of the mist generator shown by FIG. It is IV-IV sectional drawing of FIG. It is VV sectional drawing of FIG. FIG. 4 is a plan view of a case used in the mist generator shown in FIG. 3. It is explanatory drawing which shows the effect | action by which water is pumped up by the rotor of the mist generator shown by FIG. It is sectional drawing which shows the other example of the mist generator which concerns on this invention. It is sectional drawing which shows the other example of the mist generator which concerns on this invention.

Explanation of symbols

MG Mist generator H Bathroom heater 1 Case (Mist generator)
2 Rotor 4 Case (for bathroom heater)
12 Collision Wall 13 Mist Jet 14 Reservoir 20 Rotating Plate 21 Shaft 41b Blower 50 Fan 51 Heat Exchanger (Heating Unit)
92 Water supply piping (liquid supply means)

Claims (5)

A rotor capable of splashing liquid around by centrifugal force;
A plurality of collision wall portions that are located around the rotor and that make the liquid mist by colliding with the liquid splashed from the rotor;
A case that houses the rotor therein and that forms the plurality of collision walls; and
A mist generating device comprising:
The surface of the plurality of collision walls is a hydrophilic treatment surface, and is radially formed around the rotor and formed in a rib shape extending in the normal direction of the rotor,
Of the gap between the plurality of collision wall portions, a portion near the outer periphery of the case is configured as a mist outlet formed in the peripheral wall portion of the case, and the liquid collides with the plurality of collision wall portions. The mist generated by the mist generating device is configured to pass through the gap and to be ejected from the mist ejection port to the periphery of the case . Provided at the bottom of the case, and a reservoir capable of storing a liquid that has been supplied from the outside, and further comprising,
The rotor has a rotating plate and a shaft-like portion that extends downward from the rotating plate and can be partially immersed in the liquid in the liquid storage portion, and at the time of rotation, the liquid in the liquid storage portion is the shaft-like portion. Is raised to the rotating plate, and is configured to scatter from the rotating plate toward the collision wall,
Among the liquid splashed around the rotor, a part of the liquid that was not ejected to the outside of the case is configured to return to the liquid storage part along the inner surface of the case,
The mist generator according to claim 1, wherein an inner surface of the case is also a hydrophilic treatment surface. The mist generating device according to claim 1 or 2, wherein an outer surface and a bottom lower surface of the peripheral wall portion of the case are also hydrophilic treatment surfaces.   The mist generator according to any one of claims 1 to 3, wherein a surface of the rotor is also a hydrophilic treatment surface. A case installed at the top of the bathroom;
A fan that sucks the air of the bathroom into the case, and blows out the air from the air outlet to the bathroom;
Heating means capable of heating the air sucked into the case by driving the fan;
A bathroom heating device comprising:
It further comprises the mist generating device according to any one of claims 1 to 4, wherein the mist generating device is configured to mist the water as the liquid and supply the mist to the bathroom. A bathroom heating device provided with a mist generating device.

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