JP5397660B2 - Mist generator and bathroom air conditioner equipped with the same - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a mist generating device of a type that makes a liquid mist using a rotating rotor, and a bathroom air conditioner equipped with the mist generating device.

  As a specific example of the mist generating device, for example, as described in Patent Document 1, there is a structure in which a rotor that can be driven and rotated is housed in a housing having a predetermined shape. The rotor plays a role of generating mist by scattering the water supplied directly or indirectly to the rotor around the rotor by centrifugal force. The generated mist is ejected from the mist ejection port provided in the housing to the outside of the housing.

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

  That is, when the mist generating device is installed in a bathroom, for example, for use in a mist shower, the mist generating device is prevented from becoming unsanitary, and the mist generated by the mist generating device is cleaned. It is requested to make it. In order to accurately meet such demands, after the operation of the mist generating device is completed, it is configured so that many water droplets do not remain on the housing and the rotor located inside the housing, and these parts can be dried quickly. It is requested to do. This is because the water droplets promote the growth of molds and bacteria in the housing.

  On the other hand, in the past, when stopping the operation of the mist generating device, there is actually no means for positively eliminating the remaining water remaining on the rotor. there were. More specifically, when the housing has an upper wall portion that covers the top of the rotor, after the operation of the mist generating device is stopped, water droplets adhering to the upper wall portion flow down onto the rotor. A lot of water may remain on the rotor. However, conventionally, no means for removing such residual water from the rotor is taken, and much water remains on the rotor. In order to make the mist generating device superior in hygiene, it is desirable to reduce not only the rotor but also the residual water present on the surface of the housing, but the rotor is formed relatively large and has a large amount on the upper surface. Therefore, it is important to prevent a lot of water from adhering to the rotor. Conventionally, there is room for improvement in this respect.

JP-A-8-182727

  The present invention has been conceived under the circumstances as described above, and can appropriately prevent a large amount of liquid from remaining on the rotor when the operation is stopped. It is an object of the present invention to provide a mist generating device suitable for drying and excellent hygiene, and a bathroom air conditioner equipped with the mist generating device.

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

The mist generator provided by the first aspect of the present invention includes a rotor, control means for controlling the rotational operation of the rotor, and an upper wall portion that houses the rotor and is positioned above the rotor. And a mist ejection port formed in the housing, and the mist is generated by scattering the liquid supplied in the housing around the rotor by the rotation of the rotor. And a mist generating device capable of ejecting the mist from the mist outlet to the outside of the housing, wherein the control means performs the mist generating operation by rotating the rotor. when to terminate the mist generating operation from being state by stopping the rotation of the rotor, then the first predetermined time rotation stop shape of the rotor The advance is maintained, the at the time when the first predetermined time has elapsed, said rotor a second predetermined time at least part of the liquid present on the rotor may speed be excluded from the rotor It is characterized by performing control to re-rotate over a range.

  According to such a configuration, after the operation of the mist generating device is stopped, even if the liquid flows down from the upper wall portion of the housing onto the rotor, the rotor is re-rotated when the first predetermined time has passed thereafter. The liquid that has flowed down on the rotor can be removed from the rotor. Accordingly, it is preferable to appropriately prevent a large amount of liquid from remaining on the rotor, and to dry the rotor at an early stage to make it excellent in hygiene.

  The mist generator provided by the second aspect of the present invention includes a rotor, control means for controlling the rotational operation of the rotor, and an upper wall portion that houses the rotor and is positioned above the rotor. And a mist ejection port formed in the housing, and the mist is generated by scattering the liquid supplied in the housing around the rotor by the rotation of the rotor. And a mist generating device capable of ejecting the mist from the mist outlet to the outside of the housing, wherein the control means performs the mist generating operation by rotating the rotor. In the case where the rotation of the rotor is stopped and the mist generation operation is terminated from the state where the rotor is rotating, as the operation control before stopping the rotation of the rotor After the rotational speed of the rotor is reduced to a speed lower than the rotational speed at the time of the mist generation operation and the low-speed rotation is continued for a first predetermined time, the rotational speed of the rotor is present on the rotor. It is characterized by accelerating at a speed at which at least a part of the liquid to be removed can be removed from the rotor, and performing control for rotating the rotor for a second predetermined time.

  According to such a configuration, the liquid adhering to the upper wall portion of the housing can flow down on the rotor during the low-speed rotation period of the rotor that is executed before stopping the rotation of the rotor. In addition, the liquid that has flowed down on the rotor in this way can be removed from the rotor when the rotor is rotated at an accelerated rotational speed. Therefore, when the rotation of the rotor is stopped and the operation of the mist generating device is stopped, not only a large amount of liquid exists on the rotor, but also a large amount of liquid flows down on the rotor after that from the upper wall portion of the housing. This is also prevented appropriately. As a result, it is avoided that much liquid remains on the rotor, which is preferable for drying the rotor at an early stage and improving hygiene.

  In a preferred embodiment of the present invention, a rotation speed when the rotor rotates for the second predetermined time is lower than a rotation speed of the rotor during the mist generation operation.

  According to such a configuration, when the rotor performs a revolving operation that is re-rotated or accelerated for the second predetermined time to eliminate the liquid on the rotor, a large amount of the liquid is contained in the housing due to the rotation of the rotor. Generation of mist is appropriately prevented. When a lot of mist is generated, this mist may come into contact with the upper wall portion of the housing, which may form water droplets and then fall on the rotor. It can be avoided.

  In a preferred embodiment of the present invention, the second predetermined time is shorter than the first predetermined time.

  According to such a configuration, it is possible to accurately obtain the operation intended by the present invention while eliminating the waste of rotating the rotor for an unnecessarily long time. That is, first, the first predetermined time should be a time required for a large amount of liquid on the upper wall portion of the housing to flow down on the rotor, and it is desirable that the first predetermined time be set to a certain extent. On the other hand, since the second predetermined time may be a time required to scatter liquid existing on the rotor around the rotor and exclude it, the time may be short. According to the above configuration, such a condition is met.

  In a preferred embodiment of the present invention, the whole or a part of the lower surface of the upper wall portion of the housing is inclined so that the height decreases as it proceeds from the outer peripheral edge region toward the central region of the lower surface. The inclined surface is configured such that the liquid adhering to the lower surface can flow down onto the rotor after proceeding to a region near the center of the lower surface.

  According to such a configuration, since the operation of the liquid flowing down from the lower surface of the upper wall portion onto the rotor is promoted, a large amount of liquid remains on the lower surface of the upper wall portion after the operation of the mist generating device is stopped. It can also be prevented appropriately. In addition, since the time required for the liquid on the lower surface of the upper wall portion to flow down on the rotor is shortened, the first predetermined time can be shortened.

  In a preferred embodiment of the present invention, the gap between the lowermost part of the lower surface of the upper wall part and the rotor is such that when the liquid droplets hang down from the lowermost part, the liquid droplets are separated between the lowermost part and the rotor. It is a dimension that can be bridged between. When the liquid to be misted is water, the size of the gap is, for example, 3 mm or less, and more preferably, 2-3 mm, for example.

  According to such a configuration, when the liquid droplet hangs from the lowermost portion of the lower surface of the upper wall portion and the liquid droplet bridges between the lowermost portion and the rotor, the rotor rotates when the rotor rotates. The lower end side of the liquid crystal is pulled, and an action of actively pulling off the droplet from the lowermost part is obtained. Therefore, the movement of the liquid from the lowermost part onto the rotor is promoted, and it is more preferable to reduce the liquid residual amount on the lower surface of the upper wall part.

  The bathroom air conditioner provided by the third aspect of the present invention is a bathroom air conditioner installed on or above a bathroom and used for air conditioning of the bathroom. The mist generator provided by the side surface is provided.

  According to such a configuration, the same effect as described for the mist generator provided by the first or second 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.

  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.

  FIGS. 1-7 has shown an example of the bathroom air conditioner provided with the mist generator to which this invention was applied, and the structure relevant to this. The bathroom air conditioner A shown in FIG. 1 is configured as a bathroom heater / dryer, and is attached to a ceiling 80 of a bathroom such as a unit bath. The main part of the mist generator MG is attached to the panel 41 provided in the lower part of the bathroom air conditioner A. The bathroom air conditioner A includes a control unit 7. The control unit 7 also performs operation control of the mist generating device MG, and corresponds to an example of a control unit in the present invention.

  As clearly shown in FIG. 2, the mist generator MG includes a housing H, a rotor 2, a motor M for driving and rotating the rotor 2, and hot water (hot water or non-heated water) for generating mist. A water supply pipe 92 for supplying the water into the inside and a drain pipe 99 connected to the bottom of the housing H are provided. The water supply pipe 92 and the drain pipe 99 are provided with on-off valves V1 and V2 for switching on / off of water supply and drainage (see also FIG. 1).

  The housing H includes an upper wall portion 60 and a bottom wall portion 11 that form a space for accommodating the rotor 2. In addition to the above, the housing H is also provided with a plurality of collision wall portions 12 and a plurality of mist jets 13 positioned around the rotor 2. The housing H is configured by assembling a cover body 6 on a housing body 1 whose overall schematic shape is a cup shape having an upper surface opening. Both the housing body 1 and the cover body 6 are made of synthetic resin. The housing H is disposed, for example, so that the upper portion thereof is in contact with the lower surface of the panel 41, and is fixed to the panel 41 using a screw member (not shown) or an appropriate bracket. The housing body 1 and the cover body 6 are assembled by superimposing the outer peripheral edge of the cover body 6 on the uppermost ring-shaped portion 18 of the housing body 1 and screwing (not shown) this portion. It is done.

  The upper wall portion 60 of the housing H is configured using the cover body 6 and plays a role of preventing mist from being ejected upward from the upper surface opening of the housing body 1. Further, the upper wall portion 60 has a plurality of upward convex portions 68 for screwing the motor M on its upper surface, and also serves as a motor support member. An air inlet 61 is provided at the center of the upper wall portion 60, and external air that has traveled through the gap between the motor M and the upper wall portion 60 can be advanced into the housing H. An electric heater 66 is provided on the upper surface of the upper wall portion 60. The heater 66 serves to heat the upper wall 60 and dry its lower surface 60a at an early stage. Of course, since the heat of the heater 66 is also transmitted to other parts of the housing H, it is useful for drying the entire housing H and the rotor 2 at an early stage.

  A substantially entire lower surface 60a of the upper wall portion 60 is formed as an inclined surface 60a ′ whose height decreases as it goes from the outer peripheral edge region toward the central region. Of the lower surface 60a, the vicinity of the peripheral edge of the air inlet 61 has the lowest height among the inclined surfaces 60a ′, and a plurality of convex portions 62 projecting downward are provided at this portion. The plurality of convex portions 62 correspond to an example of “the lowermost portion of the lower surface of the upper wall portion” in the present invention. If a liquid adheres to the lower surface 60a, this liquid will reach the formation part of the some convex part 62 along inclined surface 60a '. The plurality of convex portions 62 are positioned above a rotating plate 20 (described later) of the rotor 2. A dimension s1 of a gap between the rotating plate 20 and each convex portion 62 is, for example, 2 to 3 mm. With such dimensions, while the amount of air passing through the gap is increased to some extent, when a water drop hangs down from each convex part 62, the lower part of the water drop is brought into contact with the rotating plate 20, Water drops can be bridged between them. Producing such a bridge is preferable for pulling away hot water from each convex portion 62 using the rotation of the rotor 2 as will be described later.

  As shown in FIG. 7, the plurality of (for example, three) convex portions 62 are linear or belt-like in an arc shape when viewed from the bottom, and are provided in an arrangement surrounding the rotation center Oa of the rotor 2. However, among the convex portions 62, the distance r1 from one end 62a on the upstream side in the rotational direction N1 of the rotor 2 to the rotational center Oa and the rotational center Oa from the other end 62b located on the downstream side in the rotational direction N1. The distance r2 is in a relation of r1 <r2, and the distance from the rotation center Oa increases as it goes from the one end 62a to the other end 62b. The air inflow port 61 has a non-circular shape corresponding to the plurality of convex portions 62 (see also FIG. 6).

  The lower surface 60a of the upper wall portion 60 is a hydrophilic treatment surface including the surface of each convex portion 62, and has a specification that makes it difficult to generate water droplets. Preferably, in addition to the lower surface 60a, substantially the entire inner and outer surfaces of the housing H and the substantially entire surface of the rotor 2 are also hydrophilic treatment surfaces. Means for making the surface of each part of the housing H and the rotor 2 hydrophilic treatment surfaces include means for generating active species on the target surface, such as corona discharge treatment, plasma treatment, and ultraviolet irradiation treatment, primers and other hydrophilic properties. It is possible to employ a means for applying a material excellent in surface to the target surface or a means for roughening the target surface by etching or blasting the target surface. In addition to this, when each part is resin-molded, a means using a resin containing a hydrophilic material as the molding material can be employed.

  The bottom wall portion 11 of the housing H is recessed at the center, and forms a liquid storage portion 14 that can store an appropriate amount of hot water. The water supply pipe 92 is inserted into the housing H so that hot water can be supplied to the liquid storage section 14. Of the upper surface 11 a of the bottom wall portion 11, at least the region near the outer peripheral edge located around the liquid storage portion 14 is an inclined surface whose height decreases toward the center portion. This inclined surface is useful for allowing the hot water that has been misted and not ejected to the outside of the housing H to flow into the liquid storage portion 14 and be collected.

  The rotor 2 is rotatably supported by a drive shaft 30 of the motor M, and includes a disk-shaped rotating plate 20 and a shaft-shaped portion 21 for pumping hot water that protrudes downward from the central portion of the rotating plate 20. Have. The shaft-like portion 21 has a conical shape or a truncated cone shape having a larger diameter toward the upper part. When the shaft-shaped portion 21 has such a shape, when the shaft-shaped portion 21 is rotated at a high speed, the hot water stored in the liquid storage portion 14 is filmed along the outer peripheral surface of the shaft-shaped portion 21. It is possible to raise it in the shape. When the hot water rises along the shaft-like portion 21 and is pumped up to the lower surface of the rotating plate 20, the hot water is accelerated from the region near the center of the rotating plate 20 toward the outer periphery by centrifugal force, and the rotating plate 20 Spatter around. Such an action of the rotor 2 itself is the same as that of a conventionally known one (for example, a rotor described in JP-A-2001-289470).

  The lower portion of the shaft-like portion 21 is inserted into a liquid discharge hole 16 provided at the bottom of the housing H. A gap of, for example, about 1 to 3 mm is formed between the hole portion 16 and the outer peripheral surface of the shaft-like portion 21. As described above, the hot water existing in the gap is always pumped upward by the action of the shaft-like portion 21 raising the hot water along the outer peripheral surface when the rotor 2 rotates. As a result, the hot water in the liquid storage unit 14 is appropriately prevented from leaking downward from the hole 16. Of course, when the rotation of the rotor 2 is stopped, the hot water in the liquid reservoir 14 flows out from the hole 16 downward. A drainage pipe 99 having an opening / closing valve V2 is connected to the hole 16, and hot water flowing out from the hole 16 is led to an appropriate location outside or inside the bathroom via the drainage pipe 99. Of course, the hot water may flow down directly below the hole 16 without providing such a drain pipe 99. For example, when the shower water used in the bathroom enters the housing H when the operation of the mist generator MG is stopped, the hole 16 is also useful for discharging the water to the outside of the housing H.

  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 rotating plate 20 to the periphery thereof, and a mist having a minute particle size is generated by the collision. It is possible. The upper end and the lower end of each collision wall portion 12 are connected to the ring-shaped portion 18 and the bottom wall portion 11 (see also FIG. 4). As shown in FIG. 3, the plurality of collision wall portions 12 are in the form of ribs arranged radially around the central axis of the housing H at substantially equal intervals. The gap between the collision wall portions 12 adjacent to each other is opened substantially in the horizontal direction and downward, and this opening portion is the mist ejection port 13. Mist generated when water collides with the plurality of collision wall portions 12 passes through the plurality of mist outlets 13 as it is from the gaps between the plurality of collision wall portions 12 and is ejected around the housing H.

  The bottom wall portion 11 is provided with one or a plurality of cylindrical portions 15a erected upward. A hole portion of the cylindrical portion 15a is an air inlet for allowing external air to flow into the housing H. 15 (see also FIG. 5). When external air flows into the housing H from the air inlet 15, the ambient air around the rotor 2 is prevented from becoming a turbulent state, and the hot water in the liquid storage unit 14 is pumped up along the shaft 21. This helps to stabilize the movement that proceeds toward the periphery of the rotating plate 20. The air inlet 61 provided in the upper wall portion 60 also serves to suppress the occurrence of turbulent flow in the housing H.

  As shown in FIG. 1, the bathroom air conditioner A includes a case 4, a fan 50, and a heat exchanger 51 as a heating unit in addition to the control unit 7. The case 4 has a lower opening shape that houses the fan 50 and the heat exchanger 51 and is installed on the upper surface side of the ceiling plate 80 of the bathroom. The lower opening of the case 4 is blocked by the panel 41. ing. The panel 41 is provided with an air supply port 41a and a louver 42 having a blower port 41b.

  In the bathroom air conditioner A, when the fan 50 is driven, air is sucked into the case 4 from the air supply port 41 a and the air is heated by the heat exchanger 51. The heat exchanger 51 is configured by using a plurality of finned tubes to which hot water is supplied from a heat source device (not shown) such as a hot water supply device installed outside the bathroom, and the intake air by the fan 50 is used as the intake air. Heated when passing between the plurality of finned tubes. The heated air is guided to the louver 42 and blown out from the air blowing port 41b. The flow of air blown from the blower port 41b can be used to efficiently supply the mist blown from the mist generator MG to a desired region. The louver 42 can swing and adjust the angle, but can preferably be set to an angle at which warm air can be blown toward the housing H of the mist generator MG. According to such a configuration, when the operation of the mist generator MG is stopped, the housing H1, the rotor 2, and the like can be quickly dried using the warm air. Therefore, it is particularly preferable when the mist generator MG is not provided with the heater 66.

  The control unit 7 is configured using, for example, a microcomputer, and executes operation control of each unit of the bathroom air conditioner A in response to an operation command from an operation remote controller (not shown). Further, as described above, the control unit 7 also performs operation control of the mist generating device MG. However, the specific contents of this control will be described later.

  Next, the basic operation of the bathroom air conditioner A provided with the mist generator MG will be described.

  First, when the mist generator MG is operated, hot water is supplied from the water supply pipe 92 to the liquid storage unit 14 and the motor M is driven to rotate the rotor 2. As described above, a part of the hot water stored in the liquid storage part 14 rises 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. After that, it scatters around it and collides with a plurality of collision walls 12. Due to this collision, a lot of fine mist is generated in the gaps between the plurality of collision wall portions 12, and the mist passes through the mist outlet 13 as it is and is ejected around the housing H. Accordingly, it is possible to appropriately suppress water droplets in the housing H without much of the mist generated in the housing H being ejected to the outside, and to increase the amount of mist ejected. The mist ejected around the housing H can then be gradually lowered from the upper part of the bathroom using gravity, but the mist generating device MG is utilized by utilizing the air flow blown from the air blowing port 41a. It can also be actively supplied to areas other than directly below. For this reason, for example, the amount of mist when the bather takes a mist shower can be increased to make the bather comfortable.

  When the mist is generated, a part of the mist touches the lower surface 60a of the upper wall portion 60, and hot water adheres to this portion. Such hot water smoothly flows toward the plurality of convex portions 62 along the inclined surface 60a ′ of the lower surface 60a, and flows from the plurality of convex portions 62 onto the rotating plate 20 of the rotor 2. As described with reference to FIG. 7, the plurality of convex portions 62 have a substantially arc shape that surrounds substantially the entire circumference around the rotation center Oa of the rotor 2, and therefore, the lower surface 60 a is formed along the inclined surface 60 a ′. The hot water flowing toward the center almost certainly reaches any one of the plurality of convex portions 62. Therefore, hot water is effectively collected on the plurality of convex portions 62, and the ratio of hot water flowing from the convex portions 62 onto the rotating plate 20 increases. When the mist is generated, the rotor 2 is rotating at a high speed, so that the hot water flowing on the rotating plate 20 is scattered toward the plurality of collision wall portions 12 by the centrifugal force, and is reused for the generation of mist.

  Further, when the mist is generated, a swirling air flow in the same direction as the rotation direction of the rotor 2 is generated in the gap between each convex portion 62 and the rotating plate 20 of the rotor 2. Accordingly, the hot water that has reached each convex portion 62 is pushed by the swirling air flow and moves from one end portion 62a of the convex portion 62 toward the other end portion 62b, as indicated by an arrow n1 in FIG. Furthermore, since the above-described swirling air flow tends to spread from the rotation center Oa side of the rotor 2 toward the periphery of the rotating plate 20, the hot water that has reached the convex portion 62 is gradually rotated by the swirling air flow. Pushed away from Oa. On the other hand, since each convex part 62 is formed so that the distance from the rotation center Oa becomes longer as it moves from the one end part 62a side to the other end part 62b side, the hot water that has reached each convex part 62 is reduced. The movement to the other end portion 62b using the swirling air flow is further ensured. Thus, if hot water is collected in the other end part 62b, it will become easy to flow hot water on the rotor 2 from this part. Since the gap between each convex portion 62 and the rotating plate 20 is dimensioned so that hot and cold water can be bridged, when a water droplet hangs down to some extent from each convex portion 62, the water droplet contacts the rotating plate 20, There is also an effect that the rotary plate 20 is easily pulled away from each convex portion 62 by being dragged by the rotation.

  As described above, the mist generating device MG of the present embodiment actively and efficiently causes the hot water adhering to the lower surface 60a of the upper wall portion 60 to flow on the rotor 2 when the mist is generated. 60a has a good water drainability. Therefore, it is possible to prevent a large amount of hot water from remaining on the lower surface 60a immediately after the rotation of the rotor 2 is stopped. Also, hot water remaining on the lower surface 60a immediately after the rotation of the rotor 2 is stopped can be quickly guided onto the rotor 2 using the inclined surface 60a ′ and the convex portion 62 thereafter. As a result, the lower surface 60a can be dried early.

  Next, a specific example of the operation processing procedure of the control unit 7 when the mist generating operation is terminated will be described with reference to the flowchart of FIG. The operation at that time will be described with reference to FIG.

  First, in a state where the rotor 2 is rotated and a mist generation operation is performed, when the operation remote controller is used and a switch operation for ending the mist operation is performed, the control unit 7 turns on the heater 66. Then, heating of the upper wall portion 60 is started, and the open / close valve V1 is closed to stop water supply into the housing H (S1: YES, S2, S3). Moreover, the on-off valve V2 for drainage is opened (S4). Thereafter, the controller 7 stops the rotation of the rotor 2 (S5). When the rotation of the rotor 2 is stopped, the generation of mist is also stopped. At this time, as shown in FIG. 8A, the hot water W adhering to the lower surface 60a of the upper wall portion 60 is inclined. It flows along 60a ′ and proceeds toward the convex portion 62. The hot water W that has reached the convex portion 62 then hangs down and is guided onto the rotating plate 20, and a part of the hot water W is formed between the convex portion 62 and the rotating plate 20 as shown in FIG. It will be in the state bridged to.

  The controller 7 then re-rotates the rotor 2 when the first predetermined time has elapsed thereafter (S6: YES, S7). The first predetermined time is preferably a time necessary and sufficient for causing the phenomenon shown in FIGS. 8A and 8B. Although depending on the size of the lower surface 60a, the inclination angle of the inclined surface 60a ′, etc., the first predetermined time can be, for example, in the range of about 2 to 3 seconds to about 10 seconds. When the rotor 2 is rotated again as described above, the hot water W bridged between the convex portion 62 and the rotating plate 20 is separated from the convex portion 62 as shown in FIG. It can be made to advance toward the outer periphery. Accordingly, it is possible to reduce the amount of hot water remaining on the lower surface 60a.

  Preferably, the rotation speed when the rotor 2 re-rotates is a speed at which the hot and cold water W can be scattered around the rotary plate 20 by centrifugal force, and is lower than that during the mist generation operation. More preferably, when the hot water W scatters around the rotary plate 20 and collides with the collision wall portion 12, the hot water W hardly mists. When the rotor 2 rotates at such a speed, as shown in FIG. 8D, most of the hot water W collides with the collision wall portion 12 and then almost flows down onto the bottom wall portion 11 along the collision wall portion 12. . The hot water W can then reach the liquid discharge hole 16 and be discharged to the outside of the housing H.

  The control unit 7 stops the rotation of the rotor 2 when the second predetermined time has elapsed from the start of the re-rotation of the rotor 2, and then turns off the heater 66 (S8: YES, S9, S10). As described above, the re-rotation of the rotor 2 is an operation for discharging the hot water W already accumulated on the rotating plate 20 to the periphery of the rotor 2. . Therefore, it is preferable that the second predetermined time is shorter than the first predetermined time.

  According to the above-described series of operation control, the hot water adhering to the lower surface 60a of the upper wall portion 60 is caused to flow on the rotor 2 after the rotation operation of the rotor 2 is finished, and then the rotor 2 is rotated again. As a result, the hot water is separated from the lower surface 60a, and the remaining hot water on the rotor 2 is also eliminated. Therefore, not only the lower surface 60a but also a large amount of hot water remains on the upper surface of the rotor 2 is preferably avoided, which is preferable for early drying of these portions. Of course, in this mist generating device MG, since hot water existing on the bottom wall portion 11 can also be discharged to the outside from the hole portion 16, it becomes easy to dry almost the entire area in the housing H at an early stage. In addition, it is possible to suppress the growth of mold and various germs and to improve hygiene.

  FIG. 10 shows another example of the operation processing procedure of the control unit 7. The mist generating device MG may be configured to execute an operation process as shown in FIG. 10 instead of the operation process shown in FIG. 9 when the mist generation operation is terminated. In the flowchart of FIG. 10, the same steps as those shown in FIG. 9 are denoted by the same reference numerals as those in FIG.

  In the operation process shown in FIG. 10, when a switch operation for stopping the mist operation is performed during the mist generation operation (S1: YES), steps S2 to S4 are executed as in the case of FIG. However, the control unit 7 thereafter reduces the rotational speed of the rotor 2 to the first predetermined speed without immediately stopping the rotor 2 (S5 '). The first predetermined speed is a low speed at which the amount of mist generated is zero or almost zero without causing hot water to splash from the rotor 2 toward the collision wall portion 12. When the rotational speed of the rotor 2 is set to such a low speed, as in the case where the rotor 2 is stopped, the hot water is prevented from newly adhering to the lower surface 60a of the upper wall portion 60, and already on the lower surface 60a. The hot and cold water that has adhered can be made to flow on the rotor 2.

  Next, after continuing the low-speed rotation of the rotor 2 described above for a first predetermined time, the control unit 7 accelerates the rotational speed of the rotor 2 and performs a second predetermined speed higher than the first predetermined speed. The speed is set (S6: YES, S7 ′). Thus, if the rotational speed of the rotor 2 is accelerated, the hot water existing on the rotating plate 20 can be reliably scattered around the rotating plate 20. The second predetermined speed is preferably set so that the hot water on the rotating plate 20 does not collide with force toward the collision wall portion 12 as in the case where the rotor 2 is rotated again in step S7 of FIG. It is set as the speed which can be scattered around. The operation of rotating the rotor 2 at the second predetermined speed is executed for a second predetermined time, as in the case of FIG. 9, and then the rotor 2 is stopped and the heater 66 is also turned off (S8: YES). , S9, S10).

  In the operation process described above, unlike the operation process of FIG. 9, the rotation speed of the rotor 2 is temporarily reduced and then accelerated without temporarily stopping the rotation of the rotor 2. The same effect as that of the operation process shown in FIG. 9 can be obtained.

  The present invention is not limited to the contents of the above-described embodiment. The specific configuration of each part of the mist generator according to the present invention and the bathroom air conditioner provided with the mist generator can be varied in design in various ways.

  For example, when the rotor is re-rotated after the rotation of the rotor is stopped, this re-rotation operation may be repeatedly performed several times (that is, after the re-rotation is finished and the rotor is stopped, the rotor is further stopped). The rotor may be stopped after rotating. Similarly, also in the case of performing rotation accelerated after decelerating the rotation speed of the rotor, the decelerated rotation and the acceleration rotation may be repeatedly executed a plurality of times. The specific values of the first and second predetermined times are matters that can be appropriately determined by the designer of the mist generating apparatus in consideration of the purpose intended by the present invention, and are not particularly limited.

  In the case of forming an inclined surface on the lower surface of the upper wall portion of the housing, it is preferable to form it on substantially the entire lower surface from the viewpoint of improving drainage, but instead, it is partially formed on the lower surface of the upper wall portion. It can also be set as the structure which carried out. When providing a convex part on the lower surface of the upper wall part, it is preferable to provide a plurality of convex parts separated from each other, but instead of this, for example, only one convex part in the shape of a ring in a bottom view may be provided. it can.

  As the rotor, for example, as shown in Patent Document 1, water is directly supplied on its upper surface using a water supply pipe or the like, and this water is directly scattered around the rotor by centrifugal force. It can also be adopted. Moreover, if hot water splashed from the rotor is collided with the collision wall, it is possible to suitably generate mist having a small particle size, but the hot water is simply scattered around the rotor using the rotor. Even so, it is possible to generate mist (the mist generated in this case has a large particle size and becomes quite coarse). Therefore, the mist generator of the present invention can be configured such that the collision wall portion is not provided. In addition, when providing a collision wall part, this collision wall part does not necessarily need to be rib shape with constant thickness. For example, the thickness may be non-uniform or bent in plan view. From the viewpoint of increasing the amount of mist ejection, it is preferable to eject mist over substantially the entire outer periphery of the housing, but the present invention is not limited to this. For example, a means for blocking the mist traveling from the mist outlet or a means for closing the mist outlet is provided in a part of the periphery of the plurality of collision walls, and the mist is provided in a part of the outer periphery of the housing. Can be prevented from being ejected.

  The mist generating apparatus according to the present invention may be configured to be provided in a wall-mounted bathroom air conditioner that is attached to, for example, a location near the ceiling of the bathroom side wall, instead of the ceiling-mounted bathroom air conditioner. it can. Also, unlike this, the mist generating device is installed above or above the bathroom using devices / equipment other than the bathroom air conditioner, or brackets, etc., independently of the presence or absence of the bathroom air conditioner. It can also be used. The mist generator according to the present invention is suitable for mist generation in hot water or non-heated water in a bathroom (including a shower room), but is installed in a place other than the bathroom to atomize or spray liquid other than hot water or hot water. It can also be used for applications (for example, humidification applications, application of liquids such as chemicals, applications aimed at the negative ion effect associated with mist generation).

It is a schematic sectional drawing which shows an example of the bathroom air conditioner provided with the mist generating apparatus which concerns on this invention. It is principal part sectional drawing of the mist generator shown by FIG. FIG. 3 is a plan cross-sectional view of the principal part of III-III in FIG. 2. It is IV-IV sectional drawing of FIG. It is a top view which shows the housing main body of the mist generator shown by FIG. It is a top view which shows the cover body of the housing of the mist generating apparatus shown by FIG. It is a bottom view of the cover body shown in FIG. (A)-(d) is principal part cross-section explanatory drawing which shows an example of an effect | action in the case of complete | finishing mist generation | occurrence | production operation | movement. It is a flowchart which shows an example of the operation | movement process procedure of the control part of the mist generating apparatus shown by FIG. It is a flowchart which shows the other example of the operation | movement process procedure of the control part of the mist generating apparatus shown by FIG.

Explanation of symbols

A Bathroom air conditioner MG Mist generator H Housing (of mist generator)
W Hot water (liquid)
2 Rotor 7 control unit (control means)
13 Mist outlet 60 Upper wall (housing)
60a bottom surface (on top wall)
60a 'inclined surface (underside)
62 Convex (bottom of the bottom surface)

Claims (6)

A rotor, a control means for controlling the rotational operation of the rotor, a housing which houses the rotor and has an upper wall portion located above the rotor, and a mist jet formed in the housing And an exit,
It is possible to generate mist by scattering the liquid supplied into the housing around the rotor by the rotating operation of the rotor, and to eject the mist from the mist outlet to the outside of the housing. A mist generator,
The control means stops the rotation of the rotor from the state in which the rotor is rotated and the mist generating operation is being executed, and ends the mist generating operation for the first predetermined time thereafter . When the rotation stop state is maintained and the first predetermined time has elapsed, the second rotor is moved at a speed at which at least a part of the liquid existing on the rotor can be removed from the rotor. The mist generator is configured to execute a re-rotation control over a predetermined time. The mist generating apparatus according to claim 1, wherein a rotational speed when the rotor rotates for the second predetermined time is lower than a rotational speed of the rotor during the mist generating operation . The mist generating apparatus according to claim 1 or 2, wherein the second predetermined time is shorter than the first predetermined time . The whole or part of the lower surface of the upper wall portion of the housing is an inclined surface that is inclined so as to decrease in height as it proceeds from the outer peripheral edge region toward the central region of the lower surface, and is attached to the lower surface. The mist generating device according to any one of claims 1 to 3, wherein the mist generating device is configured such that the liquid can be allowed to flow onto the rotor after proceeding to a central region of the lower surface . The gap between the lowermost part of the lower surface of the upper wall part and the rotor has a dimension capable of bridging the liquid droplet between the lowermost part and the rotor when the liquid droplet hangs down from the lowermost part. The mist generator according to claim 4 , wherein Bathroom air conditioner installed above or above the bathroom and used for air conditioning the bathroom
Where
A bathroom air conditioner comprising the mist generator according to any one of claims 1 to 5.

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