JP2009079865A - Humidifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidifier capable of improving humidifying efficiency, by enhancing gas-liquid contact efficiency of a droplet and object air fined in a mist shape. <P>SOLUTION: Liquid diffused from a rotary plate 8 is fined in a mist shape by colliding the liquid diffused from the rotary plate 8 with a plurality of annular collision walls 13, by arranging the plurality of annular collision walls 13 in a concentrically circular shape on the outer peripheral side of the rotary plate 8 diffusing the liquid by centrifugal force, and is contacted with fined mist by ventilating the object air between the plurality of annular collision walls 13. Such a constitution can efficiently contact the fined mist with the object air in respective clearance parts of the plurality of annular collision walls 13, that is, can improve the humidifying efficiency by enhancing the gas-liquid contact efficiency of the mist and the object air. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a humidifier that refines a liquid into a mist to humidify target air.

  Mist for various purposes such as moisturizing skin, relaxation effect due to negative ions, or using a bathroom as a sauna room in recent years (Mist as used in this application includes vapor, fine droplets, mixed state of vapor and fine droplets) A humidifier using the concept has been devised.

As such a conventional humidifier, for example, the liquid is dissipated in the radial direction from the rotating plate by centrifugal force, and is collided with a colliding portion disposed on the outer periphery of the rotating plate, thereby making the mist form fine. There are some which humidify by supplying the target air near the part. (For example, see Patent Document 1)
JP 2006-057977 A

  In such a humidifier, since the mist-shaped droplet and the target air contact only at the periphery of the collision part, that is, the outer peripheral side of the rotating plate, there is a problem that the gas-liquid contact is not sufficiently performed and the humidification efficiency is low. there were.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a humidifier capable of improving the humidification efficiency by increasing the gas-liquid contact efficiency between the mist-shaped droplets and the target air. .

  In order to achieve the above object, the humidifying device of the present invention has a plurality of annular collision walls arranged concentrically on the outer peripheral side of a rotating plate that dissipates liquid by centrifugal force, and the plurality of liquids diffused from the rotating plate are transferred to the plurality of rotating plates. The target air is humidified by causing the target air to flow between the plurality of annular collision walls and contacting with the refined mist. .

  Further, the second problem solving means is characterized in that the annular collision wall rotates together with the rotating plate.

  Further, the third problem solving means is characterized in that a plurality of connecting ribs for connecting each of the plurality of annular collision walls are provided radially.

  Further, the fourth problem solving means is characterized in that a plurality of connecting ribs for connecting each of the plurality of annular collision walls and the rotating plate are provided in a radial manner.

  Further, the fifth problem solving means is characterized in that the number of the connecting ribs is increased in the radially outward direction.

  The sixth problem solving means is characterized in that the connecting ribs are arranged so as not to be in a straight line in the radial direction.

  The seventh problem-solving means is characterized in that the connecting rib is formed in an uneven shape when viewed from the rotational direction.

  The eighth problem-solving means is characterized in that the connecting rib is formed in a sawtooth shape when viewed from the rotational direction.

  The ninth problem solving means is characterized in that the connecting rib is formed in a comb shape when viewed from the rotation direction.

  Further, the tenth problem solving means is characterized in that the connecting rib is formed in a lightning bolt shape when viewed from the rotation direction.

  The eleventh problem solving means is characterized in that the connecting rib is formed in a wave shape when viewed from the rotational direction.

  The twelfth problem solving means is characterized by comprising a plurality of annular collision walls and rotating plates in the axial direction.

  The thirteenth problem solving means is characterized in that the annular collision wall is formed in an uneven shape when viewed from the radial direction.

  The fourteenth problem solving means is characterized in that the annular collision wall is formed in a sawtooth shape when viewed from the radial direction.

  Further, the fifteenth problem solving means is characterized in that the annular collision wall is formed in a comb shape when viewed from the radial direction.

  The sixteenth problem solving means is characterized in that the annular collision wall is formed in a lightning bolt shape when viewed from the radial direction.

  The seventeenth problem solving means is characterized in that the annular collision wall is formed in a wave shape when viewed from the radial direction.

  The eighteenth problem solving means is characterized in that the rotation axis of the rotating plate is set to the vertical direction, and the ventilation direction of the target air is set to be vertically downward.

  The nineteenth problem solving means is characterized in that the rotation axis of the rotating plate is set in the vertical direction, and the ventilation direction of the target air is set in the vertically upward direction.

  The twentieth problem solving means is characterized in that the air blowing means for passing air between the plurality of annular collision walls is arranged on the windward side of the rotating plate.

  The twenty-first problem solving means is characterized in that the air blowing means for passing air between the plurality of annular collision walls is arranged on the leeward side of the rotating plate.

  The twenty-second problem solving means is characterized by comprising driving means for rotating the rotating plate on the windward side of the rotating plate.

  In the twenty-third problem solving means, the air blowing means for ventilating between the plurality of annular collision walls is driven by the driving means for rotating the rotating plate.

  In the twenty-fourth problem solving means, a vaporization filter is disposed on the outer peripheral side of the annular collision wall.

  According to the present invention, a plurality of annular collision walls are arranged concentrically on the outer peripheral side of the rotating plate that dissipates the liquid by centrifugal force, and the liquid diffused from the rotating plate is By colliding with a plurality of annular collision walls to be refined into a mist shape, by passing the target air between the plurality of annular collision walls, that is, the gap portions of the plurality of annular collision walls, and bringing them into contact with the refined mist In addition, it is possible to provide a humidifier having an effect of improving the humidification efficiency by bringing the mist and the target air into contact with each other in the gap portions of the plurality of annular collision walls to increase the gas-liquid contact efficiency.

  According to the invention described in claim 2, the contact time with the mist refined by turning the target air ventilated through the gaps between the plurality of annular collision walls by rotating the annular collision wall together with the rotating plate. It is possible to provide a humidifier having an effect of increasing the gas-liquid contact efficiency.

  According to a third aspect of the present invention, by providing a plurality of connecting ribs that connect each of the plurality of annular collision walls in a radial manner, the liquid that collides with the annular collision wall and splashes further collides with the connection ribs. Therefore, it is possible to provide a humidifying device having an effect of facilitating miniaturization and improving the contact efficiency with the target air.

  According to a fourth aspect of the present invention, a plurality of connecting ribs that connect each of the plurality of annular collision walls and the rotating plate are provided in a radial manner, so that the liquid that collides with the annular collision wall and scatters together with the rotating plate. It is possible to provide a humidifying device having an effect that the rotating connecting rib can be collided to promote miniaturization and the contact efficiency with the target air can be increased.

  Further, according to the invention described in claim 5, since the number of the connecting ribs increases as it goes in the radially outward direction, it is possible to suppress a decrease in the collision probability of the connecting rib in the radially outward direction where the liquid scattering area is large. Thus, it is possible to provide a humidifier that is effective in suppressing a decrease in mist efficiency and suppressing a decrease in contact efficiency with the target air.

  According to the sixth aspect of the present invention, since the connecting ribs are arranged so as not to be in a straight line in the radial direction, the liquid moves in the radially outward direction along the connecting ribs to inhibit mist formation. It is possible to provide a humidifying device having an effect of suppressing a phenomenon to suppress a decrease in mist efficiency and suppressing a decrease in contact efficiency with target air.

  According to the seventh aspect of the present invention, since the connecting rib is formed in an uneven shape when viewed from the rotation direction, the corner portion having a large contribution of liquid crushing at the time of the collision of the connecting rib is increased and the miniaturization is promoted. And the humidification apparatus with the effect that contact efficiency with object air can be improved can be provided.

  According to the invention described in claim 8, since the connecting rib is formed in a sawtooth shape when viewed from the rotation direction, the corner portion where the contribution of liquid crushing at the time of the collision of the connecting rib increases is increased and the miniaturization is promoted. And the humidification apparatus with the effect that contact efficiency with object air can be improved can be provided.

  Further, according to the ninth aspect of the present invention, since the connecting rib is formed in a comb-like shape when viewed from the rotation direction, the corner portion having a large contribution of liquid crushing at the time of collision of the connecting rib is increased, thereby miniaturizing. It is possible to provide a humidifying device that is effective to promote and improve the contact efficiency with the target air.

  According to the invention described in claim 10, since the connecting rib is formed in a lightning bolt shape when viewed from the rotation direction, the corner portion having a large contribution of liquid crushing at the time of the collision of the connecting rib is increased and the miniaturization is promoted. And the humidification apparatus with the effect that contact efficiency with object air can be improved can be provided.

  According to the invention described in claim 11, since the connecting rib is formed in a wave shape when viewed from the rotation direction, the corner portion having a large contribution of liquid crushing at the time of the collision of the connecting rib is increased and the miniaturization is promoted. And the humidification apparatus with the effect that contact efficiency with object air can be improved can be provided.

  According to the twelfth aspect of the present invention, by providing a plurality of annular collision walls and rotating plates in the axial direction, the contact efficiency between the target air and the mist generated by increasing the number of mist generation locations and gas-liquid contact areas is increased. It is possible to provide a humidifier having an effect that it can be increased.

  In addition, according to the invention of claim 13, by forming the annular collision wall in a concave-convex shape when viewed from the radial direction, the corner portion where the contribution of the liquid crushing at the time of the collision of the annular collision wall is increased increases in size. It is possible to provide a humidifying device having an effect that the contact efficiency with the target air can be enhanced.

  Further, according to the invention described in claim 14, by forming the annular collision wall in a sawtooth shape when viewed from the radial direction, the corner portion where the contribution of the liquid crushing at the time of the collision of the annular collision wall is increased increases in size. It is possible to provide a humidifying device having an effect that the contact efficiency with the target air can be enhanced.

  According to the invention described in claim 15, by forming the annular collision wall in a comb-like shape when viewed from the radial direction, the corner portion having a large contribution of liquid crushing at the time of collision of the annular collision wall increases and becomes finer. It is possible to provide a humidifying device having an effect of facilitating the conversion and improving the contact efficiency with the target air.

  According to the invention described in claim 16, by forming the annular collision wall in a lightning bolt shape when viewed from the radial direction, the corner portion where the contribution of the liquid crushing at the time of the collision of the annular collision wall is increased increases in size. It is possible to provide a humidifying device having an effect that the contact efficiency with the target air can be enhanced.

  According to the invention described in claim 17, by forming the annular collision wall into a wave shape when viewed from the radial direction, the corner portion where the contribution of the liquid crushing at the time of the collision of the annular collision wall is increased increases in size. It is possible to provide a humidifying device having an effect that the contact efficiency with the target air can be enhanced.

  According to the invention described in claim 18, the rotation axis of the rotating plate is set to the vertical direction, and the air flow direction of the target air is set to the vertically downward direction, thereby suppressing the scattering of relatively large droplets that cannot be miniaturized. Therefore, it is possible to provide a humidifying device that is effective.

  According to the nineteenth aspect of the present invention, the rotation axis of the rotating plate is set to the vertical direction, and the ventilation direction of the target air is set to the vertically upward direction, so that the liquid mist formed by the annular collision wall does not collide with the obstacle. Thus, it is possible to provide a humidifying device having an effect that it can be smoothly supplied together with the target air.

  According to the twentieth aspect of the present invention, the air blowing means for passing air between the plurality of annular collision walls is arranged on the windward side of the rotating plate, so that the liquid scattered when the annular collision wall collides is supplied to the air blowing means. It is possible to provide a humidifier that is effective in suppressing adhesion.

  According to the invention as set forth in claim 21, the air blowing means that ventilates between the plurality of annular collision walls is disposed on the leeward side of the rotating plate, so that the object to be ventilated through the gap portions of the plurality of annular collision walls. It is possible to provide a humidifier having an effect of making the air velocity distribution uniform and improving the gas-liquid contact efficiency.

  According to the invention of claim 22, by providing the driving means for rotating the rotating plate on the windward side of the rotating plate, it is possible to suppress the adhesion of the liquid scattered at the time of the collision with the annular collision wall to the driving means. It is possible to provide a humidifying device having an effect of being able to.

  According to the twenty-third aspect of the present invention, the driving means for rotating the rotating plate drives the blowing means for ventilating between the plurality of annular collision walls. Therefore, it is possible to provide a humidifier having an effect that the apparatus can be downsized.

  According to the invention of claim 24, by providing the vaporization filter on the outer peripheral side of the annular collision wall, the liquid diffused from the annular collision wall in the radially outward direction is captured by the vaporization filter and vaporized in the target air. Thus, it is possible to provide a humidifying device having an effect of increasing the humidifying efficiency.

  According to the first aspect of the present invention, a plurality of annular collision walls are concentrically arranged on the outer peripheral side of the rotating plate that dissipates the liquid by centrifugal force, and diffused from the rotating plate. The liquid is made to collide with the plurality of annular collision walls to be refined into a mist shape, and the target air is blown between the plurality of annular collision walls to be brought into contact with the refined mist. The mist that has been refined in the gap portions of each of these contacts with the target air and has an effect of improving the gas-liquid contact efficiency.

  Further, the invention according to claim 2 is to rotate the annular collision wall together with the rotating plate, and the contact time with the mist that is refined by swirling the target air ventilated through the gaps between the plurality of annular collision walls is increased. The gas-liquid contact efficiency is increased.

  According to a third aspect of the present invention, a plurality of connecting ribs for connecting each of the plurality of annular collision walls are provided radially, and the liquid that collides with the annular collision wall and further scatters also collides with the connecting ribs. Thus, miniaturization is promoted and the contact efficiency with the target air is increased.

  According to a fourth aspect of the present invention, a plurality of connecting ribs for connecting each of the plurality of annular collision walls and the rotating plate are provided radially, and the liquid that collides with the annular collision wall and scatters is rotated together with the rotating plate. The connecting ribs collide with each other to promote the miniaturization and increase the contact efficiency with the target air.

  Further, the invention according to claim 5 is configured such that the number of the connecting ribs increases as it goes in the radially outward direction, and a decrease in the collision probability of the connecting rib in the radially outward direction where the liquid scattering area is large is suppressed. A reduction in mist efficiency is suppressed, and a reduction in contact efficiency with the target air is suppressed.

  The invention according to claim 6 is a phenomenon in which the connecting ribs are arranged so as not to be in a straight line in the radial direction, and the liquid is moved radially outward along the connecting ribs to prevent mist formation. Is suppressed, a decrease in mist efficiency is suppressed, and a decrease in contact efficiency with the target air is suppressed.

  The invention according to claim 7 is such that the connecting rib is formed in an uneven shape when viewed from the rotation direction, and the miniaturization is promoted by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting rib increases. Thus, the contact efficiency with the target air is increased.

  In the invention according to claim 8, the connecting rib is formed in a sawtooth shape when viewed from the rotation direction, and the miniaturization is promoted by increasing the corner portion where the contribution of liquid crushing at the time of the collision of the connecting rib increases. Thus, the contact efficiency with the target air is increased.

  Further, the invention according to claim 9 is such that the connecting rib is formed in a comb-like shape when viewed from the rotation direction, and miniaturization is achieved by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting rib increases. It has the effect | action that it is accelerated | stimulated and the contact efficiency with object air is improved.

  In the invention of claim 10, the connecting rib is formed in a lightning bolt shape when viewed from the direction of rotation, and the miniaturization is promoted by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting rib increases. Thus, the contact efficiency with the target air is increased.

  Further, the invention according to claim 11 is such that the connecting rib is formed in a wave shape when viewed from the rotation direction, and the miniaturization is promoted by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting rib increases. Thus, the contact efficiency with the target air is increased.

  The invention according to claim 12 is provided with a plurality of annular collision walls and rotating plates in the axial direction, and the contact efficiency between the target air and the mist refined by increasing the number of mist generation locations and gas-liquid contact areas. Has the effect of increasing.

  Further, the invention according to claim 13 is such that the annular collision wall is formed in an uneven shape when viewed from the radial direction, and miniaturization is achieved by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting rib increases. It has the effect | action that it is accelerated | stimulated and the contact efficiency with object air is improved.

  The invention according to claim 14 is such that the annular collision wall is formed in a sawtooth shape when viewed from the radial direction, and miniaturization is achieved by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting rib increases. It has the effect | action that it is accelerated | stimulated and the contact efficiency with object air is improved.

  Further, the invention according to claim 15 is such that the annular collision wall is formed in a comb-like shape when viewed from the radial direction, and is refined by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting ribs increases. Is promoted to increase the contact efficiency with the target air.

  The invention according to claim 16 is the one in which the annular collision wall is formed in a lightning bolt shape when viewed from the radial direction, and the miniaturization is increased by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting ribs is increased. It has the effect | action that it is accelerated | stimulated and the contact efficiency with object air is improved.

  The invention according to claim 17 is the one in which the annular collision wall is formed in a wave shape when viewed from the radial direction, and miniaturization is achieved by increasing the corner portion where the contribution of liquid crushing at the time of collision of the connecting ribs is increased. It has the effect | action that it is accelerated | stimulated and the contact efficiency with object air is improved.

  The invention according to claim 18 is such that the rotation axis of the rotating plate is the vertical direction and the air flow direction of the target air is the vertically downward direction, and scattering of relatively large droplets that could not be miniaturized is suppressed. Has the effect of

  According to the nineteenth aspect of the present invention, the rotation axis of the rotating plate is set to the vertical direction, and the air flow direction of the target air is set to the vertically upward direction, so that the liquid misted by the annular collision wall does not collide with the obstacle. It has the effect of being able to easily supply smoothly with the target air.

  Further, in the invention described in claim 20, the air blowing means for passing air between the plurality of annular collision walls is disposed on the windward side of the rotating plate, and the liquid scattered during the collision with the annular collision wall adheres to the air blowing means. Has the effect of being suppressed.

  Further, in the invention described in claim 21, the air blower that ventilates between the plurality of annular collision walls is arranged on the leeward side of the rotating plate, and the target air to be ventilated through the gap portions of the plurality of annular collision walls. Has the effect that the air-velocity distribution is made uniform and the gas-liquid contact efficiency is increased.

  The invention according to claim 22 is provided with a driving means for rotating the rotating plate on the windward side of the rotating plate, and the adhesion of the liquid scattered at the time of the collision with the annular collision wall to the driving means is suppressed. Has an effect.

  Further, the invention described in claim 23 is such that the air blowing means for passing air between the plurality of annular collision walls is driven by the driving means for rotating the rotating plate, and the driving source of the rotating plate and the air blowing means is individually set. There is no need to provide the device, and the device can be reduced in size.

  The invention according to claim 24 is the one in which the vaporization filter is disposed on the outer peripheral side of the annular collision wall, and the liquid diffused radially outward from the annular collision wall is supplemented by the vaporization filter and vaporized in the target air. This has the effect of increasing the humidification efficiency.

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

(Embodiment 1)
A humidifier according to Embodiment 1 of the present invention will be described. FIG. 1 is a schematic cross-sectional view of a humidifier equipped with a mist generator. As shown in the figure, a mist transport duct 2 having a hollow cylindrical shape and an inverted conical bottom formed inside a main body 1 of the humidifier is arranged. A drain port 3 is opened at the center of the inverted conical bottom surface of the mist transport duct 2. A hollow cylindrical mist generating cylinder 4 is disposed substantially concentrically with the mist transport duct 2 inside the mist transport duct 2. The lower end of the mist generating cylinder 4 is provided with a space so that air can communicate with the mist conveying duct 2, and the other end of the mist generating cylinder 4 communicates with a suction port 5 opened in the outer shell of the main body 1. Yes.

  Further, a fan 6 is disposed inside the main body 1 so that the suction side communicates with the upper opening end of the mist transport duct 2, and the blowout side of the fan 6 communicates with the air outlet 7 opened on the top surface of the main body 1. is doing. Therefore, when the fan 6 is operated, the target air is sucked from the suction port 5, flows through the mist generating cylinder 4, flows through the space between the mist transport duct 2 and the mist generating cylinder 4, and is discharged from the outlet 7 to the outside of the main body 1. The air blowing operation is performed.

  In addition, a disk-shaped rotating plate 8 is disposed inside the mist generating cylinder 4, and a drive motor 9 is disposed above the rotating plate 8. The drive shaft of the drive motor 9 is connected to the central portion of the rotary plate 8, and the rotary plate 8 is configured to rotate by driving the drive motor 9. Further, the rotating plate 8 and the drive motor 9 are set in a positional relationship in which the rotating surface when the rotating plate 8 is rotated is parallel to the radial direction of the mist generating cylinder 4. Further, a plurality of annular collision walls 13, which will be described in detail later, are disposed inside the mist generating cylinder 4 and in the radially outward direction of the rotating plate 8.

  Further, a water supply pipe 10 for supplying water to the rotating surface of the rotary plate 8 is provided in the main body 1, and this water supply pipe 10 has one end opened above the rotary plate 8 and the other end is provided with the other end. It is connected to the discharge side of the water supply pump 11. The suction side of the water supply pump 11 opens into a water supply tank 12 disposed at the bottom of the main body 1, and the drain port 3 of the mist transport duct 2 opens above the water supply tank 12. Therefore, when the water supply pump 11 is operated with water stored in the water supply tank 12, the water in the water supply tank 12 is pumped up by the water supply pump 11 and supplied to the rotating plate 8 through the water supply pipe 10. When the rotating plate 8 is rotated by the drive motor 9 in this state, the water supplied on the rotating surface is discharged radially outward by centrifugal force and collides with the plurality of annular collision walls 13. Then, the water droplets further released from the annular collision wall 13 in the radially outward direction adhere to the inner wall surface of the mist generating cylinder 4 and drop downward through the wall surface and are collected from the drain port 3 to the water supply tank 12. Become.

  Next, details of the annular collision wall 13 will be described. 2A is a schematic enlarged view of the annular collision wall 13, and FIGS. 2B, 2C, 2D, 2E, and 2F are illustrated in FIG. It is a schematic sectional drawing which shows the cross-sectional shape pattern of AA 'cross section of). As shown in FIG. 2 (a), the annular collision wall 13 is arranged in multiple layers concentrically with the rotation plate 8 on the radially outer peripheral side of the rotation plate 8. The cross-section viewed from the direction, that is, the AA ′ cross-sectional shape is an uneven shape as shown in FIG. 2 (b), a comb-like shape as shown in FIG. 2 (c), and a sawtooth as shown in FIG. 2 (d). The lightning shape as shown in FIG. 2 (e) and the wave shape as shown in FIG. 2 (f). By setting it as such a shape, the corner | angular part with respect to the radial direction of the rotating plate 8 will increase. In this corner portion, the contact portion with respect to the liquid radiated outward from the rotating plate 8 is small, and the liquid colliding with the corner is likely to scatter while maintaining the speed. Will be promoted by mist.

  In addition, at least some of the plurality of annular collision walls 13 from the inside are connected by connecting ribs 14 that are formed radially with the rotation axis of the rotating plate 8 as the center. As shown in FIG. 2A, the connecting ribs 14 that connect each of the plurality of adjacent annular collision walls 13 are not formed on the same straight line in the radial direction, and further go outward from the rotating plate 8 in the radial direction. Accordingly, the number of the connecting ribs 14 is increased to form a mesh shape. By adopting such a configuration, it is possible to suppress the water that has been diffused from the rotating plate 8 and has contacted the annular collision wall 13 from moving radially outward along the connecting ribs 14 and inhibiting mist formation.

  Next, details of the connecting rib 14 will be described. FIG. 3A, FIG. 3B, FIG. 3C, FIG. 3D, and FIG. 3E are schematic cross-sectional views showing a cross-sectional shape pattern of the axial cross section of the connecting rib. Similarly to the annular collision wall 13, the connecting rib 14 is preferably configured to have a shape with many corners for refining the collided liquid. 3 (a), comb teeth shown in FIG. 3 (b), sawtooth shapes shown in FIG. 3 (c), lightning shapes shown in FIG. 3 (d), and shown in FIG. 3 (e). By setting it as a wave shape, the corner | angular part with respect to the rotation direction of the rotating plate 8 will increase. In this corner portion, the contact portion with respect to the liquid diffused between the rotating plate 8 and the annular collision wall 13 and between the plurality of annular collision walls 13 is small, and the liquid colliding with the corner easily scatters while maintaining the speed. Then, the liquid is effectively miniaturized at the corners to promote mist formation.

  Next, the principle of mist generation will be described in detail. FIG. 4 is a schematic diagram showing an outline of the action in the mist generating cylinder 4. When the water supply pump 11 is operated as described with reference to FIG. 1, water is pumped from the water supply tank 12 by the water supply pump 11 and supplied to the water supply pipe 11. The outlet of the water supply pipe 10 is disposed above and near the center of the rotating plate 8 and is configured to supply water pumped up from the water supply tank 12 to the vicinity of the rotating shaft of the rotating plate 8. Here, when the drive motor 9 is driven to rotate the rotating plate 8, the supplied water is dissipated in a tangential direction from the outer peripheral edge of the rotating plate 8 by centrifugal force, and collides with the annular collision wall 13 in a stepwise manner. . That is, the water diffused from the point 15 shown in FIG. 4 scatters in the direction indicated by the arrow 16. The water droplets scattered in the direction of the arrow 16 collide with the innermost annular collision wall 13 that rotates together with the rotating plate 8. Due to this collision, the water droplets are crushed and fine mist is generated.

  Since the annular collision wall 13 is rotated together with the rotating plate 8 by the connecting rib 14, further centrifugal force is applied to the water droplet colliding with the innermost annular collision wall 13. The centrifugal force further increases the speed of the water droplet in the radially outward direction and is dissipated from the innermost annular collision wall 13 as indicated by an arrow 17, and then collides with the next outer diameter annular collision wall 13 to be fine. Turn into. That is, by rotating both the rotating plate 8 and the annular collision wall 13, centrifugal force is applied to water droplets radiating from the annular collision wall 13, and the collision energy at the time of collision with the next annular collision wall 13 is increased to refine the structure. Can be promoted.

  Further, residual water remaining on the annular collision wall 13 that is not diffused into the air as a fine mist by the collision is subjected to centrifugal force due to the rotation of the annular collision wall 13, and as shown by an arrow 18, It is diffused from the outer periphery again in the radially outward direction. In this way, new water droplets diffused again from the annular collision wall 13, a part of the water droplets diffused from the rotating plate 8 and not collided with the annular collision wall 13, and the innermost annular collision wall 13 A part of the water droplets crushed by collision collides with the next annular collision wall 13 on the outer peripheral side, and is crushed and refined to generate mist.

  In addition, the rotating connecting rib 14 collides with water droplets that collide with the annular collision wall 13 and scatter, and the water droplets scattered between the plurality of annular collision walls 13 are also refined.

  Such an action is repeated in each of the plurality of annular collision walls 13 in the radially outward direction, and is repeated up to the outermost annular collision wall 13 among the rotating annular collision walls 13. . The water droplets diffused from the outermost annular collision wall 13 collide with the inner wall of the mist generating cylinder 4 as shown by an arrow 19 and become mist, and the residual water that has not been mist still forms along the inner wall of the mist generating cylinder 4. It is dripped and collected in the water supply tank 12 from the drain port 3.

  By the operations and actions described above, the water droplets diffused from the rotating plate 8 repeatedly collide and mist, and are accelerated by receiving the centrifugal force due to the rotation of the annular collision wall 13 every time the collision occurs. The mist can be generated by causing the water droplets scattered from the rotating plate 8 to collide with the annular collision wall 13 in a stepwise manner.

  When the fan 6 is operated in a state where mist is generated by the collision at the plurality of annular collision walls 13 as described above, the air outside the main body 1 is sucked from the suction port 5 as shown by the solid line in FIG. 4 is introduced. The air that has flowed into the mist generating cylinder 4 passes through the gaps between the plurality of annular collision walls 13 downward in the vertical direction and mixes in contact with the mist. The mixed air moves downward on the annular collision wall 13 on the leeward side, and further contact between the mist and air is achieved in this process. In this way, the mist and air contact each other at the gaps between the plurality of annular collision walls in the mist generating cylinder 4 and the leeward side thereof, and the mist is vaporized and the target air is humidified in this gas-liquid contact process. In addition, since the annular collision wall 13 rotates together with the rotating plate 8, the target air passing through the gaps between the plurality of annular collision walls 13 is subjected to a swirling action. This swirling action increases the contact time between the mist and the target air and increases the gas-liquid contact efficiency, so that the humidification efficiency is improved. At this time, since the drive motor 9 is located above the rotating plate 8 and the target air passes vertically downward, the generated mist is difficult to adhere to the drive motor 9. Further, since the fan 6 is located on the leeward side with respect to the rotating plate 8, the air velocity distribution of the target air ventilated through the gap portions of the plurality of annular collision walls is made uniform, and the gas-liquid contact efficiency is increased. Also have.

  The air that has passed through the mist generating cylinder 4 changes its flow direction rapidly from below to above as shown by the arrows in FIG. The air passes through the space and is sucked into the fan 6 and discharged from the air outlet 7 to the outside of the main body 1. As described above, the humidifying device performs the humidifying operation by generating mist in the mist generating cylinder 4, vaporizing the mist into the air introduced from the suction port 5, and discharging the mist from the outlet 7.

  FIG. 5 is a schematic cross-sectional view in the case where a plurality of, for example, three stages, the rotating plate 8 and the annular collision wall 13 are provided in the axial direction. As shown in the figure, through holes 20 for allowing the supply water to flow downward are opened in the uppermost and middle rotary plates 8. When water is supplied to the uppermost rotating plate 8 through the water supply pipe 10, a part of the water supply is diffused radially outward by the rotation of the rotating plate 8, and the remaining is passed through the through hole 20 and the middle rotating plate located below. Drip into 8. Similarly, a part of the dropped water is dissipated in the radially outward direction by the rotation of the rotating plate 8, and the rest passes through the through hole 20 and drops onto the lowermost rotating plate 8. All of the water dripped onto the lowermost rotating plate 8 is diffused outwardly by rotation. Water droplets diffused from each of the upper, middle, and lower rotating plates 8 collide with the annular collision wall 13 connected to each rotating plate 8 to be misted by the above-described action. As described above, a plurality of the rotating plates 8 and the annular collision wall 13 are provided in the axial direction, and the mist generation amount is increased because each of them performs mist formation of the water supply.

  Furthermore, since the air supplied into the mist generating cylinder 4 passes through the gap portion of the annular collision wall 13 formed in multiple stages in the axial direction in a stepwise manner in the axial direction, the gas-liquid contact portion and the gas-liquid contact time As a result, the humidification performance is improved.

  Due to the configuration, operation and action as described above, the mist generator in the present embodiment dissipates the liquid from the rotating plate 8 in the radially outward direction by centrifugal force, and is disposed concentrically on the outer peripheral side of the rotating plate 8. By causing the plurality of annular collision walls 13 to collide in stages, the liquid can be efficiently misted.

  The above description is merely an example for carrying out the present invention, and the present invention is not limited to the above embodiment.

  For example, although the shape of the annular collision wall 13 is concave and convex when viewed from the radial direction, water droplets diffused by rotation collide stepwise, and the corner portion having a large contribution to crushing at the time of collision increases. Any other shape may be used as long as it has a shape.

  Similarly, the shape of the connecting rib 14 may be any other shape as long as it has a function of causing water droplets diffused by rotation to collide stepwise and increasing a corner portion having a large contribution to crushing at the time of the collision.

  In addition, the above-described concave-convex, comb-tooth, saw-tooth, lightning, and wave-shaped formation intervals of the annular collision wall 13 and the connecting rib 14 are formed narrower toward the outer radial direction, that is, the innermost It is desirable to form the widest interval on the circumferential side and the narrowest interval on the outermost side. With such a shape, there is an effect that a decrease in the probability of collision of water droplets on the annular collision wall 13 and the connecting rib 14 in the radially outward direction with a large liquid diffusing area is suppressed, mist efficiency is improved, and humidification is performed. The effect of improving ability is obtained.

  Moreover, although the case where all the some annular collision walls 13 rotated was shown in the said embodiment, it is not necessary to rotate the annular collision wall 13 necessarily. For example, among the plurality of annular collision walls 13, at least one or more annular collision walls 13 are integrated and fixed with the inner wall of the mist generating cylinder 4 from the outside, and the remainder on the inner peripheral side is rotated integrally with the rotating plate 8. Alternatively, the entire annular collision wall 13 may be isolated from the rotating plate 8 and fixed.

  In the above configuration, the position where the rotary plate 8 and the annular collision wall 13 are arranged in the mist generating cylinder 4 is not mentioned, but as long as it is allowed for the restrictions such as the size of the main body 1, It is preferable to dispose the mist generating cylinder 4 on the leeward side of the annular collision wall 13, that is, to provide a larger space on the leeward side than the rotating plate 8 for vaporizing the mist and air in vapor-liquid contact with each other. Is desirable.

  Further, in the vicinity of the bottom surface of the mist transport duct 2, the air flow is abruptly changed, so that an action of separating the large water droplets remaining in the air without being miniaturized due to the downward inertia force occurs. For example, when the flow rate of humidified air is high, it is formed by the outer wall surface of the mist generating cylinder 4 and the inner wall surface of the mist transport duct 2 in order to prevent large water droplets from scattering outside the main body 1. It is further desirable to provide separation means 21 for separating air from large water droplets of 10 microns or more scattered by the speed of the flow velocity in a space where air flows upward. The separating means 21 is preferably made of a rough mesh-like material such as resin, fiber, metal, etc., and has little pressure loss.

  Further, a ceramic heater 22 as a heating means for heating the target air is provided inside the mist generating cylinder 4 and on the windward side of the rotating plate 8 so that at least a part of the target air passes through the ceramic heater 22. It has become. Therefore, since the target air can be heated by energizing the ceramic heater 22 and the amount of saturated water that can be contained in the target air can be increased, the humidifying ability can be improved.

  Further, the outermost peripheral portion of the annular collision wall 13 and the inner wall of the mist generating cylinder 4 are sufficiently narrow so that the air passing through the mist generating cylinder 4 passes through the gap portions of the plurality of annular collision walls 13 almost without leakage. It is desirable that For example, when all of the plurality of annular collision walls 13 rotate, the distance between the outer peripheral edge of the outermost annular collision wall 13 and the inner wall of the mist generating cylinder 4 is such that the annular collision wall 13 does not contact the inner wall during rotation. For example, it is desirable to set a gap of about 5 mm. Further, among the plurality of annular collision walls 13, when at least one annular collision wall 13 is fixed from the outside, or from the outside, one or more annular collision walls 13 are integrated with the inner wall of the mist generating cylinder 4. In the case of rotating, the gap between the outermost annular collision wall 13 among the rotating annular collision walls 13 and the innermost annular collision wall 13 among the non-rotating annular collision walls 13 is rotated during the rotation. It is desirable to set an interval of, for example, about 5 mm so that the 13 do not contact each other.

(Embodiment 2)
Next, a humidifier according to Embodiment 2 of the present invention will be described. In addition, description is abbreviate | omitted about the same part as above-mentioned Embodiment 1, and the part which has the same effect, and uses the same code | symbol.

  FIG. 6 is a schematic sectional view of the main body 1 according to the second embodiment of the present invention. In the present embodiment, as shown in FIG. 6, the bottom surface of the mist generating cylinder 4 is formed in an inverted conical shape, and has the same shape and effect as the bottom surface portion of the mist transport duct 2 in the first embodiment described above. Yes. The blowing portion of the fan 6 is opened and communicated with the lower side surface of the mist generating cylinder 4 so that air can be sent toward the rotating plate 8 and the annular collision wall 13 inside the mist generating cylinder 4. Yes. Further, the suction portion of the fan 6 communicates with the suction port of the fan 6 opened in the main body 1, and the mist generating cylinder 4 communicates with the air outlet 7 opened in the main body 1 on the leeward side of the rotating plate 8. In addition, a separating means 21 for separating large water droplets is disposed on the leeward side of the rotary plate 8 and on the windward side of the air outlet 7. In addition, a ceramic heater 22 is provided in the blowing portion of the fan 6 as a heating means for heating the air, and the amount of saturated moisture to be included can be increased by increasing the temperature of the blown air.

  Air in the target space is sucked from the suction port 5 opened in the main body 1 and blown to the mist generating cylinder 4 by the fan 6. The air sent into the mist generating cylinder 4 rises vertically upward while generating swirling or turbulent flow in the mist generating cylinder 4 and reaches the rotating plate 8 and the annular collision wall 13. Here, each gap portion between the plurality of annular collision walls 13 is ventilated vertically upward, and is humidified by the same action as described in the first embodiment by the rotation of the rotating plate 8. The air humidified here is blown out from the air outlet 7 to the outside of the main body 1. Here, since the drive motor 9 as the drive means for driving the rotating plate 8 is located on the leeward side of the rotating plate 8 as in the first embodiment, the air cooled by the vaporization of the mist is generated. The heat generated by the drive motor 9 is removed and the drive motor 9 is cooled. The target air can be humidified by the operation as described above.

  Further, the flow direction of air in the mist generating cylinder 4 is determined by the connection position of the blowing portion of the fan 6, and as shown in FIG. 7, it is clockwise, counterclockwise, divided flow, etc. as viewed from above. If the connection position is determined so as to flow in the direction opposite to the rotation direction of the rotating plate 8, air and mist to be diffused are mixed efficiently, which is more desirable.

(Embodiment 3)
Next, a third embodiment of the present invention will be described. In addition, description is abbreviate | omitted about the same part as above-mentioned Embodiment 1, and the part which has the same effect, and uses the same code | symbol.

  FIG. 8 is a schematic cross-sectional view of the main body 1 in the third embodiment of the present invention. As shown in FIG. 8, the bottom surface of the mist generating cylinder 4 is formed in an inverted conical shape, and has the same shape and effect as the bottom surface portion of the mist transport duct 2 in the first embodiment described above. On the lower side surface of the mist generating cylinder 4, an opening communicating with the suction port 5 opened in the main body 1 is provided. The drive shaft of the drive motor 9 disposed above the rotary plate 8 extends through the drive motor 9 to the opposite side of the rotary plate 8. A sirocco fan is pivotally supported on the drive shaft as the fan 6, and the sirocco fan can rotate and blow air simultaneously with the rotation of the rotating plate 8. The blowing portion of the fan 6 and the air outlet 7 opened in the main body 1 communicate with each other, and the air sucked into the fan 6 can be blown out of the main body 1. Next, operation | movement is demonstrated along the flow of object air.

  The target air is sucked into the main body 1 from the suction port 5 opened in the main body 1 by the action of the fan 6 driven by the rotation of the drive motor 9. The target air sucked into the main body 1 is guided to the lower part of the mist generating cylinder 4, flows vertically upward depending on the shape of the mist generating cylinder 4, and is guided to the gap portions of the plurality of annular collision walls 13. Here, mist is generated by the action described in the first embodiment, and is mixed with the target air. The mist mixed with the target air is vaporized by the gas-liquid contact here, and humidifies the target air. The humidified air is sucked into the fan 6 located above the drive motor 9 and blown out from the air outlet 7 opened in the main body 1 to the outside of the main body 1. The target air can be humidified by the action described above.

  In any of the first to third embodiments described above, as shown in FIG. 9, a vaporization filter 23 for vaporizing water is formed outside the annular collision wall 13 located on the outermost side among the annular collision walls 13. The case where it is provided will be described.

  The vaporization filter 23 is formed of a material such as resin, fiber, or metal, such as foamed urethane having a three-dimensional skeleton, or a three-dimensional woven fabric in which front and back openings are connected by fibers. If so, the surface area is increased and the contact efficiency between the retained water and air is improved, so that the humidifying ability can be further improved.

  By adopting such a configuration, the outermost annular collision wall 13 not only generates mist but also has an action of supplying moisture to the vaporization filter 23. That is, water droplets diffused from the outermost annular collision wall 13 adhere to the vaporization filter 23 and are retained here. Therefore, when air passes through the rotating plate 8 and the annular collision wall 13 portion, in addition to humidification by the mist generated by the action described in the first embodiment, humidification by water vaporization on the vaporization filter 23 surface. Since the action is added, the humidification ability can be further improved, and the humidification efficiency with respect to the amount of water to be supplied can be further improved, so humidification with less waste can be performed.

  In the first to third embodiments, the heating means is the ceramic heater 22. However, as long as the heating amount, power consumption, safety, and the like are satisfied, there is no difference in the effect of other heaters such as a nichrome heater. .

  In the first to third embodiments, the liquid to be mist is water. However, various liquids such as hot water, oil, solvent, detergent, and fragrance may be used, and the present invention is not limited to this.

  The above description is merely an example for carrying out the present invention, and the present invention is not limited to the above embodiment.

  As described above, the humidifier according to the present invention can improve the humidification efficiency by increasing the gas-liquid contact efficiency between the mist-shaped droplets and the target air, and the portable humidifier shown in the embodiment. Not only can it be applied to humidified air purifiers, bathroom sauna devices, relaxation equipment using negative ions, facial instruments, sprayers, and washers. In addition to hot water, the liquid to be mist can be applied to various liquids such as oil, solvent, and detergent.

Schematic sectional view of a humidifying device body according to Embodiment 1 of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS Schematic of the annular collision wall of Embodiment 1 of the present invention ((a) Schematic enlarged view of the annular collision wall, (b) Cross section when the AA 'portion in FIG. 2 (a) is uneven. (C) Enlarged view when the AA ′ portion is comb-tooth shaped, (d) Enlarged view when the AA ′ portion is serrated, (e) AA ′ Enlarged view when the part is lightning-shaped, (f) Enlarged view when the AA ′ part is wave-shaped) Schematic diagram of connection ribs according to Embodiment 1 of the present invention ((a) Schematic diagram when the connection ribs are uneven, (b) Schematic diagram when the connection ribs are serrated, (c) Schematic when the connecting rib is comb-shaped, (d) Schematic when the connecting rib is lightning-shaped, (e) Schematic when the connecting rib is wave-shaped) Schematic diagram of the outline of the action in the mist generating cylinder Schematic cross-sectional view when the same rotating plate and multiple annular collision walls are provided in the axial direction Schematic sectional view of a humidifying device body according to Embodiment 2 of the present invention. Schematic diagram of the flow of the target air in the mist generating cylinder 4 ((a) a diagram showing the flow of the target air in a clockwise direction when viewed from above, (b) a diagram showing a flow of the target air in a counterclockwise direction (C) The figure which shows the flow of the object air in the divided flow) Schematic sectional view of a humidifying device body according to a third embodiment of the present invention. In any of Embodiment 1-3 of this invention, the schematic of the rotary plate vicinity when providing a vaporization filter

Explanation of symbols

6 Fan 8 Rotating plate 9 Drive motor 13 Annular collision wall 14 Connecting rib 23 Evaporation filter

Claims (24)

A plurality of annular collision walls are arranged concentrically on the outer peripheral side of the rotating plate that dissipates liquid by centrifugal force, the liquid diffused from the rotating plate collides with the plurality of annular collision walls, and is refined into a mist shape, A humidifying device characterized in that the target air is humidified by passing the target air between the plurality of annular collision walls and bringing it into contact with the mist that has been refined. The humidifying device according to claim 1, wherein the annular collision wall rotates together with the rotating plate. The humidifying device according to claim 1, wherein a plurality of connecting ribs for connecting each of the plurality of annular collision walls are provided in a radial pattern. The humidifying device according to claim 2, wherein a plurality of connecting ribs for connecting each of the plurality of annular collision walls and the rotating plate are provided radially. The humidifying device according to claim 3 or 4, wherein the number of the connecting ribs is increased as it goes in the radially outward direction. The humidifying device according to any one of claims 3 to 5, wherein the connecting ribs are arranged so as not to be in a straight line in the radial direction. The humidifying device according to any one of claims 3 to 6, wherein the connecting rib is formed in an uneven shape when viewed from the rotation direction. The humidifying device according to any one of claims 3 to 6, wherein the connecting rib is formed in a sawtooth shape when viewed from the rotation direction. The humidifying device according to any one of claims 3 to 6, wherein the connecting rib is formed in a comb shape when viewed from the rotation direction. The humidifying device according to any one of claims 3 to 6, wherein the connecting rib is formed in a lightning bolt shape when viewed from the rotation direction. The humidifying device according to any one of claims 3 to 6, wherein the connecting rib is formed in a wave shape when viewed from the rotation direction. The humidifier according to any one of claims 1 to 11, wherein a plurality of annular collision walls and rotating plates are provided in the axial direction. The humidifying device according to any one of claims 1 to 12, wherein the annular collision wall is formed in an uneven shape when viewed from the radial direction. The humidifying device according to any one of claims 1 to 12, wherein the annular collision wall is formed in a sawtooth shape when viewed from the radial direction. The humidifying device according to any one of claims 1 to 12, wherein the annular collision wall is formed in a comb shape when viewed from the radial direction. The humidifying device according to any one of claims 1 to 12, wherein the annular collision wall is formed in a lightning bolt shape when viewed from the radial direction. The humidifying device according to any one of claims 1 to 12, wherein the annular collision wall is formed in a wave shape when viewed from the radial direction. The humidifying device according to any one of claims 1 to 17, wherein a rotation axis of the rotating plate is a vertical direction, and a ventilation direction of the target air is a vertically downward direction. The humidifying device according to any one of claims 1 to 17, wherein a rotation axis of the rotating plate is a vertical direction, and a ventilation direction of the target air is vertically upward. The humidifying device according to any one of claims 1 to 19, wherein the air blowing means for passing air between the plurality of annular collision walls is disposed on the windward side of the rotating plate. The humidifying device according to any one of claims 1 to 19, wherein the air blowing means for passing air between the plurality of annular collision walls is disposed on the leeward side of the rotating plate. The humidifying device according to any one of claims 1 to 21, further comprising driving means for rotating the rotating plate on the windward side of the rotating plate. The humidifying device according to any one of claims 1 to 22, wherein a driving unit that rotates the rotating plate drives a blowing unit that ventilates between the plurality of annular collision walls. The humidifying device according to any one of claims 1 to 23, wherein a vaporizing filter is disposed on an outer peripheral side of the annular collision wall.

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