JP2019072679A - Atomization blower - Google Patents

Abstract

To provide an atomization blower that can prevent the dissipation of cooling effect, obtain a high cooling effect in a pinpoint manner, and elongate the operating time.SOLUTION: An atomization blower comprises a first liquid storage part 11 that stores water, an atomization part 12 provided in the first liquid storage part 11 to discharge a misty body of water stored in the first liquid storage part 11 atomized by a mesh type ultrasonic transducer along a linear discharge orbit in a first direction to the outside of the first liquid storage part 11, a Sirocco fan 23 that feeds out linearly in a second direction so as to cross the discharge orbit, a second liquid storage part 41 that stores water, a pipe 31 that connects the interior of the first liquid storage part 11 with the interior of the second liquid storage part 41, and a pump unit 42 that supplies water stored in the second liquid storage part 41 to the first liquid storage part 11.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an atomizing and blowing device, and more particularly to an atomizing and blowing device including an atomizing unit for discharging a mist-like body obtained by atomizing a liquid and a blower for delivering wind to the mist-like body.

  In the past, there has been proposed a technique for lowering the temperature in the room by adding a device for spouting water to a fan.

  For example, in Patent Document 1, a device is proposed in which water and ice are stored in a lower portion of a fan main body and pumped up to eject misty water from the front center of the fan fan. Moreover, the apparatus of the substantially same structure is proposed also by patent document 2. FIG.

Utility model registration 3138210 gazette Unexamined-Japanese-Patent No. 2003-329273

  However, in Patent Documents 1 and 2, it is an axial fan that is adopted in the fan. The wind generated by the axial fan spreads widely. According to the technique of Patent Document 1, the misty water is diffused by the air flow of the axial fan immediately after evaporation after being released, and thus the cooling effect Tended to dissipate. In addition, it has also been desired to extend the operation time in a fan configured to obtain a cooling effect by such misty water.

  The present invention has been made to solve the above-mentioned problems, and provides an atomizing blower that prevents dissipation of the cooling effect, provides a high cooling effect at a pinpoint, and prolongs the operation time. The purpose is

  In order to achieve the above object, the invention according to claim 1 is characterized in that a first liquid storage unit for storing a liquid having vaporability and a first liquid storage unit are provided, and the mesh ultrasonic transducer is used to (1) An atomizing unit for discharging a misty body, which atomizes the liquid stored in the liquid storage unit, in a linear discharge path in a first direction with respect to the outside of the first liquid storage portion; A blower for delivering the air in a straight line in the second direction so as to cross each other, a second liquid storage for storing the liquid having volatility, an inside of the first liquid reservoir, and a second liquid reservoir And connection supply means for connecting the inside and supplying the liquid stored in the second liquid storage unit to the first liquid storage unit.

  According to this structure, the high density is achieved by crossing the straightly delivered winds in the second direction before the mists discharged linearly in the first direction by the emission trajectory are dispersed. The state mist can be concentrated in the second direction and liquid can be stored in the second liquid reservoir in addition to the first liquid reservoir.

  The invention according to claim 2 is the structure according to the invention according to claim 1, further comprising connection means for connecting the inside of the first liquid storage unit and the inside of the second liquid storage unit.

  According to this structure, the liquid in the first liquid storage unit can be moved to the second liquid storage unit through the connection unit.

  According to the third aspect of the present invention, in the configuration of the second aspect, the amount by which the connection supply means supplies the liquid to the first liquid storage portion is greater than the amount by which the atomization portion discharges the liquid as a mist. A control means is provided to control to increase the number.

  According to this structure, the liquid flows out from the first liquid storage portion to the second liquid storage portion through the connection means.

  The invention according to claim 4 is an atomizing blower including a plurality of atomizing blower units and a tank unit, wherein each of the plurality of atomizing blower units is a first liquid for storing a liquid having vaporization property. An atomizing body provided in the storage unit and the first liquid storage unit and atomizing the liquid stored in the first liquid storage unit by the mesh ultrasonic transducer is provided to the outside of the first liquid storage unit An atomizing unit that discharges in a linear discharge track in a first direction, and a blower that sends out a wind in a straight line in a second direction so as to intersect the discharge track, and the tank unit is volatile A second liquid storage unit for storing a liquid having a first liquid group, a first piping group connecting the inside of the first liquid storage unit of each of the plurality of atomizing and blowing units, and the inside of the second liquid storage unit; (2) The liquid stored in the liquid storage unit can be Those comprising a pump unit for supplying the first liquid storage unit of each of the number of atomizing air blowing unit.

  If comprised in this way, the cooled wind can be supplied from many directions.

  According to the fifth aspect of the present invention, in the configuration according to the fourth aspect, the inside of the first liquid storage section of each of the plurality of atomizing blower units is further connected to the inside of the second liquid storage section. It is provided with two piping groups.

  According to this structure, the liquid in the first liquid storage unit can be moved to the second liquid storage unit through the second pipe.

  The invention according to claim 6 relates to the configuration according to claim 5, wherein the pump unit supplies the liquid to the first liquid storage portion of each of the plurality of atomizing and blowing units in a plurality of atomizing and blowing units. Each atomization part is provided with a control means which controls so that it may become larger than the quantity which discharge | releases a liquid as a mist.

  According to this structure, the liquid flows out from the first liquid storage portion to the second liquid storage portion.

  The invention according to claim 7 is an atomization blower including a plurality of atomization blower units, a tank unit, and a connection unit for connecting the plurality of atomization blower units, the plurality of atomization blowers comprising: Each of the units is provided in a first liquid storage unit for storing a liquid having volatility and in the first liquid storage unit, and the mesh ultrasonic transducer is used to mist the liquid stored in the first liquid storage unit. The atomized portion that discharges the solidified mist in a linear discharge trajectory in a first direction with respect to the outside of the first liquid storage portion, and linearly in a second direction so as to intersect the discharge trajectory The tank unit includes a second liquid storage unit for storing a liquid having a vaporizing property, and a first liquid storage unit of one of the plurality of atomizing and blowing units among the atomizing and blowing units. Connect the inside of the second liquid storage A second pipe connecting the first pipe, the inside of the first liquid storage portion of another atomizing fan unit of the plurality of atomizing fan units, and the inside of the second liquid storage portion; And a pump unit for supplying the liquid stored in the liquid storage unit to the first liquid storage unit of one atomization blower unit via the first pipe, and the connection unit includes a plurality of atomization blower units. A connection pipe is provided to connect in series between the interiors of the first liquid storage portions.

  If comprised in this way, the cooled wind can be supplied from many directions.

  According to an eighth aspect of the present invention, in the configuration according to the seventh aspect, the amount by which the pump unit supplies the liquid to the first liquid storage portion of one atomizing fan unit is the mist of at least one atomizing fan unit The control unit is provided with control means for controlling so as to be larger than the amount of releasing the liquid as a mist.

  According to this structure, the liquid is transferred from the first liquid storage portion of the one atomizing fan unit to the first liquid storage portion of another atomizing fan unit connected in series with the one atomizing fan unit. It can be done.

  The invention according to claim 9 is a first liquid storage unit for storing a liquid having vaporability, and is provided in the first liquid storage unit, and is stored in the first liquid storage unit by a mesh ultrasonic transducer. Air is sent in a straight line so that the atomization unit that discharges a mist of liquid atomized to the outside of the first liquid storage unit, and the discharge trajectory of the atomization unit that discharges the mist And the second liquid storage unit for storing the liquid having volatility, the inside of the first liquid storage unit, and the inside of the second liquid storage unit, which are stored in the second liquid storage unit. And a connection supply means for supplying the liquid in the first liquid storage unit through the first pipe.

  According to this configuration, the linearly delivered wind can merge with the mist released by the release track and can store the liquid in the second liquid storage in addition to the first liquid storage.

  As described above, according to the first aspect of the present invention, before the mists discharged linearly in the first direction by the discharge trajectory disperse, the winds sent out linearly in the second direction are The crossing allows the dense state of the mist to be concentrated in the second direction, and since the liquid can be stored in the second liquid reservoir in addition to the first liquid reservoir, the vaporization can be performed. The cooling effect due to is obtained at pinpoint and the operating time of the device can be extended.

  According to the second aspect of the invention, in addition to the effects of the first aspect of the invention, the liquid in the first liquid storage portion can be moved to the second liquid storage portion through the connection means, so that the first liquid The surplus liquid of the reservoir can be circulated to the second liquid reservoir via the connection means.

  According to the third aspect of the present invention, in addition to the effects of the second aspect, the liquid flows out from the first liquid storage portion to the second liquid storage portion through the connection means. The liquid can be efficiently circulated to the second liquid storage unit via the connection means.

  According to the fourth aspect of the invention, since the cooled wind can be supplied from multiple directions, effective cooling can be performed.

  According to the fifth aspect of the invention, in addition to the effect of the invention of the fourth aspect, the liquid in the first liquid storage portion can be moved to the second liquid storage portion via the second pipe, so that The surplus liquid in the liquid storage portion can be circulated to the second liquid storage portion via the second pipe.

  According to the sixth aspect of the invention, in addition to the effect of the invention of the fifth aspect, since the liquid flows out from the first liquid storage portion to the second liquid storage portion, the liquid in the first liquid storage portion It can be efficiently circulated to the second liquid storage unit through the piping.

  According to the seventh aspect of the present invention, since the cooled wind can be supplied from multiple directions, effective cooling can be performed.

  According to an eighth aspect of the present invention, in addition to the effect of the seventh aspect, the first liquid storage portion of the first atomizing fan unit is connected in series with the first atomizing fan unit. Since the liquid can be moved to the first liquid storage unit of the atomizing fan unit, the liquid can be efficiently moved from one atomizing fan unit to another atomizing fan unit.

  The invention according to claim 9 is that the linearly delivered wind merges with the mist released by the release track and stores the liquid in the second liquid storage in addition to the first liquid storage. As a result, the cooling effect by evaporation can be obtained and the operation time of the apparatus can be extended.

It is the perspective view which showed the external appearance shape of the atomization air blower by the 1st Embodiment of this invention. It is a front view of the atomization air blower unit of the atomization air blower shown in FIG. It is an end elevation of the III-III line in FIG. It is the block diagram shown about the functional composition of the control board of the atomization air blower shown in Drawing 1 grade. It is a figure which shows the relationship between the discharge | release track | orbit of the misty body of the atomization air blower shown in FIG. 1 etc., and the blowing direction of a wind. It is a schematic block diagram of the atomization air blower by the 2nd embodiment of this invention, (A) is a figure when an atomization air blower is seen from the front, (B) is an arrow in (A). It is a top view when it looks at D1 direction. It is a schematic block diagram of the atomization air blower by the 3rd Embodiment of this invention, (A) is a figure when the atomization air blower is seen from the side, and (B) is an arrow in (A). It is a front view when it sees in D 2 direction. It is the perspective view which showed the external appearance shape of the atomization air blower by 4th Embodiment of this invention, and respond | corresponds to FIG. It is the perspective view which showed the external appearance shape of the atomization air blower by 5th Embodiment of this invention, and respond | corresponds to FIG. It is the perspective view which showed the external appearance shape of the atomization air blower by 6th Embodiment of this invention, and respond | corresponds to FIG. It is the perspective view which showed the external appearance shape of the atomization air blower by 7th Embodiment of this invention, and respond | corresponds to FIG. It is a figure which shows the relationship between the discharge | release track | orbit of the mist shaped body of the atomization air blower by 8th Embodiment of this invention, and the ventilation direction of wind, Comprising: It respond | corresponds to FIG.

  FIG. 1 is a perspective view showing the external appearance of the atomizing blower according to the first embodiment of the present invention, and FIG. 2 is a front view of the atomizing blower unit of the atomizing blower shown in FIG. 3 is an end view of the III-III line in FIG.

  With reference to these figures, the atomizing blower 1 utilizes the cooling effect by the heat of vaporization of a liquid such as atomized water, and is composed of an atomizing blower unit 10 and a tank unit 40.

  The atomizing and blowing unit 10 is provided in the first liquid storage unit 11 for storing water, and the first liquid storage unit 11, and the water stored in the first liquid storage unit 11 is provided by the mesh ultrasonic transducer. The atomizing unit 12 discharges the atomized mist in a linear release trajectory in the first direction with respect to the outside of the first liquid storage unit 11, and the second direction so as to intersect this release trajectory And a blower 20 for creating a wind in a straight line. In addition, the detail of each part of these atomization ventilation units 10 is mentioned later.

  The tank unit 40 includes a second liquid storage unit 41 for storing water, a pipe 31 for connecting the inside of the first liquid storage unit 11 and the inside of the second liquid storage unit 41 in a watertight state, and a second liquid storage unit And 41 a pump unit for supplying the liquid stored in 41 to the first liquid storage unit. The pipe 31 and the pump unit 42 constitute a connection supply means in the atomizing air blower 1.

  Then, it is as follows when the detail of each part of the atomization ventilation unit 10 is demonstrated.

  The first liquid storage portion 11 is connected to the pipe 31 in a watertight manner at the upper portion thereof. As a result, the first liquid storage unit 11, the second liquid storage unit 41, and the pipe 31 are sealed. In the atomizing unit 12, the atomized body is released from the discharge port at the time of operation, so what is expressed as “closed state” is the atomizing unit in the first liquid storage unit 11. It means that the airtightness of parts other than 12 is maintained.

  The atomizing unit 12 is provided on the side wall of the first liquid storage unit 11. The mesh type ultrasonic transducer adopted in the atomizing unit 12 vibrates with the piezoelectric vibrator from the back (the first liquid storage section side) of a thin disk-like mesh member with a small hole open at the time of operation Thus, the liquid is ejected in the form of mist from the holes of the mesh member. The hole diameter of the mesh member is set to 10 μm or less. As a result, it is possible to suppress the formation of large droplets of the mist and to facilitate vaporization. At the same time, the air tightness of the interior of the first liquid reservoir is maintained when the atomizing unit is not in operation. Thereby, the water leak from the hole of a mesh type ultrasonic transducer can be suppressed.

  The blower 20 takes in air from the air inlet 21, the air outlet 22 and the air inlet 21, and controls the sirocco fan 23, the atomizing part 12, the sirocco fan 23 and the pump unit 42 from the air outlet 22. And a substrate 24.

  The air blowing port 22 is provided below the atomizing unit 12. Therefore, the sirocco fan 23 is configured to be provided below the atomizing unit 12. Further, the second direction is set to be directed upward. The effects of this configuration will be described later.

  The sirocco fan 23 can send a wind having high static pressure and high straightness as compared to an axial fan or the like.

  The control board 24 is connected by wiring to the atomizing unit 12, the sirocco fan 23, and the pump unit 42 (the connection between the atomizing unit 12 and the pump unit 42 is not shown for convenience of drawing) .

  In addition, the air blowing port 22 of the air blowing unit 20 and the discharge source of the misty body of the atomizing unit 12 are separated by about 3 cm.

  Then, control in this atomization air blower is explained.

  FIG. 4 is a block diagram showing a functional configuration of a control substrate of the atomizing air blower shown in FIG. 1 and the like.

  Referring to the figure, the control board 24 includes a control unit (control means) 50 that controls various kinds of signals by supplying various signals to the atomizing unit 12, the sirocco fan 23, and the pump unit 42. There is.

  The control unit 50 controls the atomization unit control unit 51 that supplies a control signal to the atomization unit 12 and a control signal to a blower unit control unit 52 and a pump unit 42 that supplies a control signal to the sirocco fan 23. And a supply control unit 53 for supplying

  The atomization unit control unit 51, the blower unit control unit 52 and the supply control unit (control means) 53 control the atomization unit 12, the sirocco fan 23 and the pump unit 42 according to the on / off of the power switch 25, respectively. Do.

  Here, the supply control unit 53 controls the amount of water supplied to the first liquid storage unit 11 by the pump unit 42 so that the water supplied from the pump unit 42 does not exceed the capacity of the first liquid storage unit 11. It controls so that the amount which the chemical conversion part 12 discharges as a mist does not exceed.

  Next, the operation of the atomizing blower will be described.

  FIG. 5: is a figure which shows the relationship between the discharge | release track | orbit of the mist-like body of the atomization air blower shown in FIG. 1 etc., and the blowing direction of wind.

  Referring to the figure, the linear distance between the position P1 where the wind sent from the blower 20 crosses the mist in the emission trajectory R and the position of the emission source of the mist in the emission trajectory R is , 5 mm to 30 cm.

  While the atomization unit 12 discharges the mist in a linear emission track R in the first direction A1 in the horizontal direction, the blower unit 20 is directed in the upward direction below the atomization unit 12. The wind is sent out linearly in the direction B1 of 2.

  Then, the wind sent from the blower 20 eventually crosses the emission trajectory R at the position P1. As a result, the mists linearly emitted in the emission trajectory in the first direction A1 intersect the winds linearly transmitted in the second direction B1 before being dispersed.

  At position P1 where the mist intersects with the wind, the mist travels in a second direction B1 in which the wind is delivered. Thus, at a position ahead of the position P1 in the horizontal direction A1, the mist advances in the same direction A2 as the direction of the wind while vaporizing.

  Therefore, the wind cooled by the vaporization of the mist advances at a position ahead of the position P1 in the horizontal direction A1.

  Therefore, since it is possible to concentrate the high-density mists in the second direction, a cooling effect by evaporation can be obtained at a pinpoint.

  In particular, by setting the above-mentioned linear distance to 5 mm to 30 cm, it is preferable for the mist to merge the wind and the mist before it is dispersed in the air, and the cooling effect can be more reliably achieved. It can be enhanced.

  In addition, since the blower unit 20 is provided below the atomizing unit 12, the blower 20 has a positional relationship in which the wind is applied from below the mist. For this reason, even when the apparatus is placed on the floor, the cooling effect is likely to be diffused. Further, since the second direction B1 is set to be directed upward, the air cooled above the atomizing portion 12 can be delivered, so that the effect of cooling upward can be expected.

  Moreover, according to such an atomization air blower 1, since water can be stored in the second liquid storage unit in addition to the first liquid storage unit, the operation time of the apparatus can be extended. In addition, since water can be supplied from the second liquid storage unit, the capacity of the first liquid storage unit can be suppressed, whereby weight reduction and downsizing of the atomizing blower unit can be achieved.

  FIG. 6 is a schematic block diagram of the atomizing blower according to the second embodiment of the present invention, where (A) is a front view of the atomizing blower, (B) It is a top view when it looks in arrow D 1 direction in A).

  In addition, since it is fundamentally the same as that of 1st Embodiment in description, it demonstrates focusing on the difference.

  With reference to the figure, in the first embodiment described above, the blower 20 is disposed below the atomizing unit, but in the second embodiment, the positional relationship is changed. doing. Moreover, in the atomization air blower 1 by this embodiment, the discharge | release direction of the mist body by the atomization part 12 is also changed from what was based on 1st Embodiment.

  Specifically, the installation level of the blower 20 is shifted upward from that of the first embodiment and set to the same level as the atomization unit 12, and the position thereof is the discharge position of the atomization unit 12. The position has been changed so that the wind strikes at a right angle to.

  According to this configuration, the air discharged from the air blowing unit 20 immediately strikes the mist discharged from the atomizing unit 12 and the vaporization progresses.

  FIG. 7 is a schematic configuration view of an atomizing blower according to a third embodiment of the present invention, in which (A) is a side view of the atomizing blower, (B) It is a front view when it looks in the arrow D 2 direction in A).

  In addition, since it is fundamentally the same as that of 1st Embodiment in description, it demonstrates focusing on the difference.

  With reference to the figure, in the atomizing blower 1 according to this embodiment, the discharge direction of the mist by the atomizing unit 12 is changed from that according to the first embodiment.

  Specifically, the atomizing unit 12 is provided on the bottom surface, and thereby the discharge direction of the mist is changed to be vertically downward. Further, the position of the blower 20 is shifted from the one in the first embodiment in the horizontal direction so that the air blows on the discharge position of the atomizing unit 12. In this way, the wind is applied to the mist discharged from the atomizing unit 12 at a right angle.

  With this configuration, as in the case of the second embodiment, the air discharged from the air blowing unit 20 immediately strikes the mist discharged from the atomizing unit 12, and the vaporization progresses.

  FIG. 8 is a perspective view showing the external appearance of the atomizing blower according to the fourth embodiment of the present invention, which corresponds to FIG.

  In addition, since it is fundamentally the same as that of 1st Embodiment in description, it demonstrates focusing on the difference.

  With reference to the figure, in the atomizing blower 1 according to this embodiment, in the first embodiment, the inside of the first liquid storage portion 11 and the second liquid storage portion 41 are further provided. The pipe 32 is provided as a connecting means for connecting the inside of the pipe in a watertight state. A filter 14 for filtering water supplied from the second liquid storage unit 41 is inserted between the pipe 31 and the first liquid storage unit 11. Not only the filtering effect of water but also silver and the like may be added to the filter 14 to provide a disinfecting effect.

  Then, the supply control unit (see FIG. 4 etc.) is such that the amount by which the pump unit 42 supplies water to the first liquid storage unit 11 is larger than the amount by which the atomization unit 12 discharges water as a mist. Control.

  With such a configuration, the amount of water supplied to the first liquid storage unit 11 is larger than the amount released from the atomization unit 12, so a part of the water supplied to the first liquid storage unit 11 Flows out from the first liquid storage unit 11 to the second liquid storage unit 41 via the pipe 32. Thus, the water which became surplus in the 1st liquid storage part 11 can be circulated to the 2nd liquid storage part 41 via piping.

  Further, since the filter 14 is provided at the connection portion between the first liquid storage portion 11 and the pipe 31, clean water filtered from the first liquid storage portion 11 to the outside by the atomization portion 12 is It can be released. On the other hand, since the filter is not provided at the connection portion between the first liquid storage portion 11 and the pipe 32, when the water flows out from the first liquid storage portion 1 to the second liquid storage portion 41, the resistance by the filter Can be prevented.

  In this manner, the liquid in the first liquid storage unit can be efficiently circulated to the second liquid storage unit through the pipe 32.

  FIG. 9 is a perspective view showing the outer appearance of an atomizing blower according to a fifth embodiment of the present invention, which corresponds to FIG.

  In addition, since it is fundamentally the same as that of 1st Embodiment in description, it demonstrates focusing on the difference.

  Referring to the figure, in the atomizing blower 1 according to this embodiment, a plurality of atomizing blower units 10a, 10b,..., 10n are connected to one tank unit 40. . The plurality of atomizing / blowing units 10a, 10b,..., 10n each have the same configuration as that according to the first embodiment, and therefore the description thereof will not be repeated here.

  The atomizing blower 1 connects the insides of the plurality of atomizing / blowing units 10a, 10b, ..., 10n to the inside of the first liquid storages 11a, 11b, ..., 11n and the inside of the second liquid storage 41, respectively. , And 31n, and the water stored in the second liquid storage unit 41 via the first piping groups 31a, 31b,. The pump units 42a, 42b,..., 42n are provided to supply the first liquid storage portions 11a, 11b,.

  According to this configuration, the cooled air is discharged from the plurality of atomizing units 12a, 12b,..., 12n of the plurality of atomizing / blowing units 10a, 10b,. Therefore, since the cooled wind can be supplied from many directions, effective cooling can be performed.

  FIG. 10 is a perspective view showing the external appearance of the atomizing blower according to the sixth embodiment of the present invention, which corresponds to FIG.

  In addition, since it is fundamentally the same as that of 4th Embodiment in description, it demonstrates focusing on the difference.

  Referring to the figure, in the atomizing blower 1 according to this embodiment, a plurality of atomizing blower units 10a, 10b,..., 10n are connected to one tank unit 40. . The plurality of atomizing / blowing units 10a, 10b,..., 10n each have the same configuration as that according to the first embodiment, and therefore the description thereof will not be repeated here.

  The atomizing blower 1 connects the insides of the plurality of atomizing / blowing units 10a, 10b, ..., 10n to the inside of the first liquid storages 11a, 11b, ..., 11n and the inside of the second liquid storage 41, respectively. , And 31n, and the water stored in the second liquid storage unit 41 via the first piping groups 31a, 31b,. 10n, pump units 42a, 42b,..., 42n supplying the respective first liquid reservoirs 11a, 11b,..., 11n of 10n, and a plurality of atomizing blower units 10a, 10b,. A second pipe group 32a, 32b,..., 32n is provided that connects the inside of each of the first liquid storages 11a, 11b,.

  Also, the supply control unit supplies water to the first liquid storage units 11a, 11b,..., 11n of the plurality of atomizing and blowing units 10a, 10b,. The amount is controlled so that the amount of each of the atomizing units 12a, 12b,..., 12n of the plurality of atomizing and blowing units 10a, 10b,.

  According to this structure, since the liquid in the first liquid storage unit can be moved to the second liquid storage unit through the second pipe, the excess liquid in the first liquid storage unit can be transferred to the second pipe. Can be efficiently circulated to the second liquid storage unit.

  FIG. 11 is a perspective view showing the external shape of the atomizing blower according to the seventh embodiment of the present invention, which corresponds to FIG.

  In addition, since it is fundamentally the same as that of 6th Embodiment in description, it demonstrates focusing on the difference.

  Referring to the figure, in the atomizing blower 1 according to this embodiment, the circulation structure of water is converted in the sixth embodiment.

That is, the atomizing blower 1 connects in series the plurality of atomizing blower units 10a, 10b,..., 10n, the tank unit 40, and the plurality of atomizing blower units 10a, 10b,. Connection piping 37a, 37b, ..., 37 _n-1 is provided.
The tank unit 40 includes a first pipe 35 connecting the inside of the first liquid storage portion 11 a of the atomizing air blowing unit 10 a and the inside of the second liquid storage portion 41, and the first liquid storage of the atomizing air blowing unit 10 n. The second pipe 36 connecting the inside of the portion 11 n and the inside of the second liquid storage portion 41 and the water stored in the second liquid storage portion 41 are atomized and blown through the first pipe 35 And a pump unit 42 for supplying the first liquid storage 11a of the unit 10a.

The connection pipes 37a, 37b, ..., 37 _n-1 connect in series the respective first liquid storage portions 11a, 11b, ..., 11n of the plurality of atomizing / blowing units 10a, 10b, ..., 10n. Do.

  In the supply control unit, the amount by which the pump unit 42 supplies water to the first liquid storage unit 11a of the atomizing blower unit 10a releases the water as at least the atomizing unit 12a of the atomizing blower unit 10a as a mist. Control to be more than the amount of The supply control unit is configured to supply the water to the first liquid storage unit 11a of the atomizing blower unit 10a by the pump unit 42 in the atomizing units 12a of the atomizing blower units 10a, 10b, ..., 10n. It is more preferable to control 12b, ..., 12n to be more than the total amount of water released.

According to this configuration, the water supplied from the second liquid storage unit 41 to the atomizing fan unit 10a is atomized in order from the atomizing fan unit 10a through the connection pipes 37a, 37b, ..., 37 _n-1. The air is circulated to the air blowing unit 10 n and is further returned from the atomizing air blowing unit 10 n to the second liquid storage unit 41.

  Therefore, water can be efficiently moved to the atomization ventilation unit 10 n sequentially from the atomization ventilation unit 10 a by a simple configuration.

  FIG. 12 is a diagram showing the relationship between the emission trajectory of the mist and the blowing direction of the air according to the eighth embodiment of the present invention, corresponding to FIG.

  In addition, since it is fundamentally the same as that of 1st Embodiment in description, it demonstrates focusing on the difference.

  With reference to the figure, in the atomizing blower 1 according to this embodiment, the delivery direction of the mist in the atomizing unit 12 is different.

  Specifically, the discharge direction of the mists of the atomization unit 12 and the wind discharge direction of the sirocco fan 23 are set in parallel. That is, while the atomization unit 12 discharges the mist in the horizontal direction A41, the sirocco fan 23 also sends out the wind in the horizontal direction B41.

  Then, the atomized body discharged by the atomizing unit 12 draws a discharge trajectory R which descends by gravity and advances to the front of the atomizing blower 1.

  On the other hand, since the sirocco fan 23 sends the wind linearly in the horizontal direction B41, it crosses the emission path R at the position P1. That is, the mist and the wind merge at the position P1.

  Therefore, vaporization is promoted at the position P1 where the mist intersects the wind. At a position ahead of the position P1 in the horizontal direction B41, the mist-like material travels in the same direction A42 as the wind traveling direction while being vaporized.

  Therefore, the wind cooled by the vaporization of the mist advances at a position ahead of the position P1 in the horizontal direction B41.

  According to such a configuration, since the released mist forms a trajectory that descends by gravity, it is easy for the air sent out linearly from the air blowing portion below the atomizing portion and the mist to merge And the cooling effect by vaporization is obtained.

  In the above configuration, from the viewpoint of the cooling effect, it is preferable to set the distance between the air outlet 22 of the sirocco fan 23 and the discharge source of the mist-like body of the atomizing unit 12 to about 3 cm or less.

  In each of the above-described embodiments, although the atomizing blower having a specific shape and dimensional relationship has been described, the present invention is not limited to this. For example, although the hole diameter of the mesh member is set to 10 μm or less, a hole diameter larger than 10 μm may be adopted. In addition, the linear distance between the position at which the wind delivered by the blower crosses the mist in the discharge trajectory and the position of the discharge source of the mist in the discharge trajectory can be arbitrarily set.

  Moreover, although it did not demonstrate in particular in said each embodiment, you may provide the cover which covers the discharge port of an atomization part at the time of non-use of an atomization air blower.

  Furthermore, although the first liquid storage unit and the second liquid storage unit are connected by piping in the first to fourth embodiments described above, the present invention is not limited to this, and the first liquid storage unit and the second liquid storage unit are directly connected. I don't care.

  Furthermore, in the fourth embodiment described above, the filter is provided between one of the pipes and the first liquid storage unit, but this filter may be omitted.

  Furthermore, in each of the above-described embodiments, the supply control unit controls the amount of liquid supplied to the first liquid storage unit to be larger than the amount of the atomizing unit discharging the liquid as a mist. Although it was, it is not restricted to this. In addition, the control between the release amount and the supply amount as described above may be performed in the atomization control unit.

  Furthermore, in each of the above-described embodiments, the first liquid storage unit and the second liquid storage unit have been described as storing water. However, the present invention is not limited thereto. Any liquid may be stored as long as it can be used.

  Furthermore, in each of the above-described embodiments, the first liquid storage unit or the second liquid storage unit is configured to be sealable, but is not limited thereto, and may be opened in any part, The second liquid storage unit may be configured to be removable.

  Furthermore, although not particularly described in each of the above-described embodiments, a liquid supply port may be provided to put the liquid into the second liquid storage section.

  Furthermore, in each of the above-described embodiments, the blower unit includes the sirocco fan, but the present invention is not limited to this. Any impeller can be used as long as it can deliver the wind in a straight line.

  Furthermore, although not particularly described in each of the above embodiments, the tank unit may be configured to have a standby power supply, and when the tank unit is attached, electric power is supplied to the atomizing unit, the blower unit and the pump unit. It may be configured to be able to be supplied.

  Furthermore, although not particularly described in the fifth embodiment, the sixth embodiment, and the seventh embodiment described above, the control unit is provided in each of the plurality of atomizing blower units. Alternatively, a control substrate may be separately provided to generally control the plurality of atomizing and blowing units and the tank unit.

  Furthermore, in each of the above-described embodiments, in the atomizing and blowing unit, one mesh ultrasonic transducer is provided in the atomizing unit, while one sirocco fan is provided in the blowing unit. Although it was, it is not restricted to this. For example, mists may be released from a plurality of mesh ultrasonic transducers for one sirocco fan. Further, in this case, the mist-like body may be selectively released from the plurality of mesh ultrasonic transducers.

DESCRIPTION OF SYMBOLS 1 ... Atomization air blower 10 ... Atomization air blower unit 11 ... 1st liquid storage part 12 ... Atomization part 20 ... Air flow part 24 ... Control board 31, 32 ... Piping 33 ... Connection unit 35 ... 1st piping 36 ... No. 1 2 piping 37 ... connection piping 40 ... tank unit 41 ... second liquid storage unit 42 ... pump unit 50 ... control unit 53 ... supply control unit

Claims (9)

A first liquid storage unit for storing a liquid having vaporability;
An atomizing body provided in the first liquid storage section and atomizing the liquid stored in the first liquid storage section by a mesh ultrasonic transducer is applied to the outside of the first liquid storage section. An atomization unit which emits in a linear emission trajectory in a first direction;
A blower configured to deliver a wind linearly in a second direction so as to intersect the release track;
A second liquid storage unit for storing a liquid having vaporability;
A connection supply unit that connects the inside of the first liquid storage unit and the inside of the second liquid storage unit and supplies the liquid stored in the second liquid storage unit to the first liquid storage unit; Equipped with an atomizing blower.   The atomization air blower of Claim 1 provided with the connection means which connects the inside of a said 1st liquid storage part, and the inside of a said 2nd liquid storage part.   The control means is controlled such that the amount by which the connection supply means supplies the liquid to the first liquid storage part is greater than the amount by which the atomization part discharges the liquid as the mist form. The atomization air blower according to Item 2. An atomizing blower comprising a plurality of atomizing and blowing units and a tank unit,
Each of the plurality of atomizing and blowing units is
A first liquid storage unit for storing a liquid having vaporability;
An atomizing body provided in the first liquid storage section and atomizing the liquid stored in the first liquid storage section by a mesh ultrasonic transducer is applied to the outside of the first liquid storage section. An atomization unit which emits in a linear emission trajectory in a first direction;
And a blower configured to deliver the wind linearly in a second direction so as to intersect the discharge track,
The tank unit is
A second liquid storage unit for storing a liquid having vaporability;
A first piping group connecting the inside of the first liquid storage section of each of the plurality of atomizing and blowing units and the inside of the second liquid storage section;
Atomization comprising a pump unit for supplying the liquid stored in the second liquid storage unit to the first liquid storage unit of each of the plurality of atomizing and blowing units via the first piping group Blower.   The atomizing blast according to claim 4, further comprising a second piping group connecting the inside of the first liquid storage portion of each of the plurality of atomizing and blowing units with the inside of the second liquid reservoir. apparatus.   The amount by which the pump unit supplies the liquid to the first liquid storage portion of each of the plurality of atomizing and blowing units, the atomizing portion of each of the plurality of atomizing and blowing units functions as the atomized body The atomization air blower according to claim 5, further comprising control means for controlling so as to be larger than the amount of liquid discharge. An atomizing blower comprising: a plurality of atomizing and blowing units; a tank unit; and a connection unit for connecting the plurality of atomizing and blowing units,
Each of the plurality of atomizing and blowing units is
A first liquid storage unit for storing a liquid having vaporability;
An atomizing body provided in the first liquid storage section and atomizing the liquid stored in the first liquid storage section by a mesh ultrasonic transducer is applied to the outside of the first liquid storage section. An atomization unit which emits in a linear emission trajectory in a first direction;
And a blower configured to deliver the wind linearly in a second direction so as to intersect the discharge track,
The tank unit is
A second liquid storage unit for storing a liquid having vaporability;
A first pipe that connects the inside of the first liquid storage unit of one of the plurality of atomizing and blowing units and the inside of the second liquid storage unit;
A second pipe that connects the inside of the first liquid storage portion of the other atomization fan unit of the plurality of atomizing fan units and the inside of the second liquid storage portion;
A pump unit for supplying the liquid stored in the second liquid storage unit to the first liquid storage unit of the one atomizing blower unit via the first pipe;
The connection unit is
An atomizing blower, comprising: a connection pipe that serially connects the insides of the first liquid storage portions of the plurality of atomizing blower units.   The amount by which the pump unit supplies the liquid to the first liquid storage unit of the one atomizing blower unit discharges the liquid as the atomized body of the atomizing unit of the at least one atomizing blower unit The atomization air blower of Claim 7 provided with the control means controlled to become more than the amount to do. A first liquid storage unit for storing a liquid having vaporability;
An atomizing body provided in the first liquid storage section and atomizing the liquid stored in the first liquid storage section by a mesh ultrasonic transducer is applied to the outside of the first liquid storage section. An atomizing unit that releases
A blower configured to send out a wind in a straight line so that the atomizing unit intersects with a release trajectory that releases the mists;
A second liquid storage unit for storing a liquid having vaporability;
The inside of the first liquid storage unit is connected to the inside of the second liquid storage unit, and the liquid stored in the second liquid storage unit is connected to the first liquid storage unit through the first pipe. An atomizing blower comprising a connection supply means for

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