JP2010046415A - Mist generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mist generator chargeable more ions to mist. <P>SOLUTION: A positive electrode plate 20 is arranged side by side at the lower part of a mist nozzle 9 so as to be positioned on the same straight line along the vertical direction with an ion nozzle 14 (ion discharge port 14a) and a mist nozzle 9 (mist discharge port 9b). Negative ions discharged from the ion discharge port 14a are moved toward the direction crossing the discharge direction m1 of the mist discharged from the mist discharge port 9b while being attracted to a positive electrode plate 20. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mist generator capable of discharging mist and ions from different discharge ports.

2. Description of the Related Art Conventionally, for the purpose of imparting firmness and moisture to a user's skin, a mist generating device that discharges toward a user while charging negative ions to the mist has been used. As such a mist generating device, a mist generating device capable of releasing toward the user mist (steam) generated by boiling water with a heater and negative ions generated by corona discharge has been proposed. (For example, patent document 1). In the mist generating apparatus of Patent Document 1, a mist nozzle that discharges mist and an ion nozzle that discharges negative ions are arranged in parallel, and the mist discharge port of the mist nozzle and the ion discharge port of the ion nozzle are close to each other. Are arranged as follows. And in patent document 1, a negative ion is discharged from the ion discharge port arrange | positioned in the vicinity of a mist nozzle, a negative ion and a mist are mixed, and a negative ion is charged to a mist.
JP 2003-159305 A

  By the way, generally, when a negative charge is charged on the surface of the stratum corneum in the skin, lipid components such as ceramide are released between the corneocytes from the epidermal granule layer. It is also known that ceramide released between the stratum corneum is dispersed on the stratum corneum surface and fills the stratum corneum, thereby preventing moisture transpiration from the skin surface and improving the skin barrier function. It has been.

  The more ceramide is released from the epidermal granule layer between the corneocytes, the more negative charge is charged on the stratum corneum surface in the skin. If the amount of ceramide released increases, ceramide is further dispersed on the surface of the stratum corneum and fills the stratum corneum, thereby further preventing the evaporation of moisture from the skin surface and improving the skin barrier function. It is possible. That is, it is conceivable to charge more negative ions with respect to the mist. In this respect, there is still room for improvement.

  An object of the present invention is to provide a mist generator that can charge more ions to a mist.

  In order to solve the above-mentioned problem, the invention described in claim 1 is characterized in that a mist generating means for generating mist, a mist discharge port for discharging the mist, an ion generating means for generating ions, and the ions. In a mist generating apparatus provided with an ion discharge port for discharging, the gist is provided with ion transfer means for transferring ions discharged from the ion discharge port toward the mist discharged from the mist discharge port. To do.

  According to the present invention, by providing the ion transfer means, the ions discharged from the ion discharge port can be transferred toward the mist discharged from the mist discharge port, and the mist generator without the ion transfer means As compared with, more ions can be charged to the mist.

The invention according to claim 2 is characterized in that, in the invention according to claim 1, the ion transfer means is a reverse polarity electrode portion having a polarity opposite to that of the ions.
According to the present invention, the ions move toward the direction intersecting the discharge direction of the mist discharged from the mist discharge port while being attracted to the reverse polarity electrode portion. Therefore, the ions discharged from the ion discharge port are attracted to the mist atmosphere of the mist discharged from the mist discharge port, and the ions are mixed with the mist in the mist atmosphere. Therefore, more ions can be charged with respect to the mist.

  The invention according to claim 3 is the invention according to claim 2, wherein the reverse polarity electrode portion is supported in a mist nozzle connected to the mist discharge port, and a tip side of the reverse polarity electrode portion is the mist. The gist is that the nozzle is exposed to the outside through the mist discharge port.

  According to the present invention, the ions move toward the vicinity of the mist discharge port while being attracted to the reverse polarity electrode portion. Therefore, ions discharged from the ion discharge port are attracted to the mist atmosphere of the mist discharged from the mist discharge port in the vicinity of the mist discharge port, and the ions are mixed with the mist in the mist atmosphere. Therefore, more ions can be charged with respect to the mist.

  According to a fourth aspect of the present invention, in the second or third aspect of the present invention, the charge amount detecting means for detecting the amount of charge flowing in the reverse polarity electrode portion, and the detection result of the charge amount detecting means. And an attractive force adjusting means for adjusting an attractive force for attracting ions ejected from the ion ejection port by adjusting the amount of charge flowing through the reverse polarity electrode portion.

  When the amount of charge flowing to the reverse polarity electrode is small, the attractive force to attract ions discharged from the ion discharge port in the reverse polarity electrode is too small, and the ions discharged from the ion discharge port are discharged from the mist discharge port. Can't be attracted into the mist atmosphere of the mist to be done. On the other hand, when the amount of charge flowing through the reverse polarity electrode section is large, the attractive force for attracting ions discharged from the ion discharge port in the reverse polarity electrode section is too large, and the ions discharged from the ion discharge port are mist discharged. The mist discharged from the outlet is unnecessarily attracted in the direction intersecting with the discharge direction of the mist. Then, the ions pass through the mist atmosphere without being mixed with the mist in the mist atmosphere, and the ions cannot be charged to the mist. However, according to the present invention, the attracting force adjusting means attracts ions ejected from the ion ejection port by adjusting the amount of charge flowing through the reverse polarity electrode unit according to the detection result of the charge amount detecting means. Adjust. Therefore, it is possible to adjust the attracting force required to attract the ions ejected from the ion ejection port into the mist atmosphere. That is, more ions can be charged with respect to the mist.

  According to a fifth aspect of the present invention, in the first aspect of the present invention, the ion transfer means is a blower means for sending a wind for sending ions generated from the ion generation means toward the ion discharge port. In summary, the blowing means is provided upstream of the ion discharge portion constituting the ion generating means.

  According to the present invention, the ions discharged from the ion discharge portion move toward the ion discharge port by the wind generated from the air blowing means provided on the upstream side of the ion discharge portion, and from the ion discharge port to the mist. It discharges toward the discharge direction. Therefore, the ions discharged from the ion discharge port can be transferred toward the mist discharged from the mist discharge port, and more ions can be charged with respect to the mist.

  According to a sixth aspect of the present invention, in the first aspect of the present invention, the ion transfer means is the same polarity electrode section having the same polarity as the ions, and the same polarity electrode section is configured to generate the ions. The gist is that it is provided on the upstream side of the ion discharge portion constituting the means.

  According to the present invention, the ions discharged from the ion discharge portion and the same polarity electrode portion provided on the upstream side of the ion discharge portion have the same polarity, so the ions discharged from the ion discharge portion Repels each other with the same polarity electrode part, moves along with the repulsive force toward the ion discharge port, and is discharged from the ion discharge port toward the mist discharge direction. Therefore, the ions discharged from the ion discharge port can be transferred toward the mist discharged from the mist discharge port, and more ions can be charged with respect to the mist.

  According to the present invention, more ions can be charged with respect to the mist.

(First embodiment)
A first embodiment embodying the present invention will be described below with reference to FIG. In the following description, “front”, “rear”, “upper”, “lower”, “left”, and “right” indicate that the user of the mist generator 1 uses the mist generator 1 when the mist generator 1 is used. “Front”, “Rear”, “Up”, “Down”, “Left”, and “Right” are shown based on the facing state.

  As shown in FIG. 1 (a), a tank holder 3 is provided in the main body case 2 of the mist generating device 1. The tank holder 3 is provided with a detachable tank 4 for supplying a liquid such as water. The tank 4 is disposed so that the water supply opening is closed by a lid 4a provided with a water stop pin (not shown) and the lid 4a (opening) is on the lower side. The tank holder 3 is provided with a projecting pin (not shown) having a shape corresponding to the water stop pin. The tank 4 is arranged in the tank holder 3 in a state where liquid is injected, so that the water-stopping pin is pushed in by the protruding pin, the watertightness is released, and the liquid in the tank 4 flows out. The tank holder 3 stores the liquid that has flowed out of the tank 4.

  The tank holder 3 is connected to a liquid reservoir 6 formed at a lower portion in the main body case 2 via a liquid supply path 5. The liquid reservoir 6 is supplied with the liquid in the tank holder 3 via the liquid supply path 5 and stored therein. On the front and rear side surfaces of the liquid reservoir 6, a heater 7 for heating and boiling the liquid stored in the liquid reservoir 6 is provided. In the present embodiment, the liquid reservoir 6 and the heater 7 constitute mist generating means for generating mist. A mist flow path 8 extending along the vertical direction of the main body case 2 is formed in the upper part of the liquid reservoir 6.

  As shown in FIG. 1 (b), a mist nozzle 9 is disposed at the top of the mist flow path 8 via a bent portion K that bends forward, and at the tip of the mist nozzle 9, A mist discharge port 9b through which mist is discharged is formed. The bent portion K is configured to change the traveling direction of the mist passing through the mist flow path 8 from the lower side to the upper side toward the front. In addition, a mist discharge path 9a for discharging the mist passing through the mist flow path 8 from the mist discharge port 9b is formed inside the mist nozzle 9. The liquid in the liquid reservoir 6 is heated and boiled by the heater 7, so that mist is discharged from the mist discharge port 9 b of the mist nozzle 9. As shown in FIG. 1A, the heater 7 is electrically connected to the control unit 30, and the control unit 30 changes the voltage value applied to the heater 7 to change the amount of mist to be discharged. It is possible to control. Further, when the voltage is continuously applied to the heater 7, the liquid in the tank 4 runs out, and the liquid supply to the liquid reservoir 6 is interrupted. In this case, when the water level of the liquid reservoir 6 is lowered, a flow switch (not shown) provided in the liquid reservoir 6 is operated, and the control unit 30 receives a signal transmitted from the flow switch, and the heater 7 is controlled so as to stop the application of the voltage to 7.

  In the main body case 2 of the mist generating device 1, a corona discharge unit 10 as an ion generating means for generating negative ions is provided above the mist flow path 8 (mist nozzle 9).

  As shown in FIG. 1B, the corona discharge unit 10 includes a high-voltage power supply circuit 11, a needle-like discharge needle 12 as an ion discharge unit, and a semi-cylindrical ground electrode 13 connected to the ground. Yes. The discharge needle 12 and the ground electrode 13 constituting the corona discharge unit 10 are provided in an upper portion of the mist nozzle 9 and are disposed in an ion nozzle 14 having an ion discharge port 14a opened at the tip. More specifically, the ground electrode 13 is disposed on the ion discharge port 14a side in the ion nozzle 14, and the discharge needle 12 is disposed on the main body case 2 side from the ground electrode 13. The discharge needle 12 is supported by the support portion 12a so as to be positioned on the central axis of the ion nozzle 14. The tip of the discharge needle 12 faces the ion ejection port 14 a so as to face the ground electrode 13.

  In the corona discharge unit 10, a high voltage power supply circuit 11 applies a negative high voltage between the discharge needle 12 and the ground electrode 13 to generate corona discharge and generate negative ions. Negative ions generated by the corona discharge unit 10 are discharged from the ion discharge port 14a. The discharged negative ions are mixed with the mist discharged from the mist nozzle 9 so that the mist is negatively charged. As shown in FIG. 1A, the high-voltage power supply circuit 11 is electrically connected to the control unit 30, and the control unit 30 controls the amount of voltage applied between the discharge needle 12 and the ground electrode 13. It has come to be.

  As shown in FIG. 1B, the ion nozzle 14 (ion discharge port 14a) is a distance within a predetermined range (1.5 cm to 3 cm) from the mist nozzle 9 (mist discharge port 9b) (2 cm in this embodiment). It is located at a distance. That is, the ion discharge port 14a is disposed in the vicinity (near the vicinity) of the mist discharge port 9b. Further, the ion discharge port 14a and the mist discharge port 9b are arranged side by side along the vertical direction, the ion nozzle 14 (ion discharge port 14a) is upward, and the mist nozzle 9 (mist discharge port 9b) is downward. Has been placed. As shown in FIG. 1B, the mist discharge direction m1 of the mist nozzle 9 is horizontal, and the opening direction of the ion nozzle 14 (ion discharge port 14a) is also relative to the mist discharge direction m1. Facing in a parallel direction.

  A plus electrode plate 20 as a reverse polarity electrode portion having a plus polarity is provided below the mist nozzle 9. The plus electrode plate 20 is arranged in parallel with the ion nozzle 14 (ion discharge port 14a) and the mist nozzle 9 (mist discharge port 9b) so as to be positioned on the same straight line along the vertical direction. The positive electrode plate 20 is supported by a support portion 20a protruding in a direction orthogonal to the side surface 2a of the main body case 2, and in the present embodiment, the positive electrode plate 20 is linear in a direction parallel to the mist discharge direction m1. It is provided so as to protrude in a shape. As shown in FIG. 1A, the positive electrode plate 20 is electrically connected to a power source 21 for causing a positive charge to flow through the positive electrode plate 20, and the power source 21 is electrically connected to the control unit 30. It is connected. The controller 30 is electrically connected to a charge amount detector 22 as charge amount detection means for detecting the amount of charge flowing through the positive electrode plate 20.

Next, operation | movement of the mist generator 1 mentioned above is demonstrated.
In a state where the liquid is stored in the liquid reservoir 6, first, the heater 7 is operated to heat and boil the liquid in the liquid reservoir 6. The water vapor generated thereby becomes mist when passing through the mist flow path 8. And the mist which passes the mist flow path 8 toward the upper direction from the downward | lower direction changes in the advancing direction in the bending part K, and flows in into the mist discharge path 9a. The mist that has flowed into the mist discharge path 9a travels through the mist discharge path 9a, and is discharged out of the main body case 2 from the mist discharge port 9b.

  On the other hand, the negative ions generated by the corona discharge unit 10 are discharged from the tip of the discharge needle 12 and attracted to the ground electrode 13 as shown in the movement path R1 of the negative ions indicated by the alternate long and short dash line in FIG. 14 is moved to the ion discharge port 14a side and discharged from the ion discharge port 14a. The negative ions discharged from the ion discharge port 14a move so as to be attracted in the direction intersecting the discharge direction m1 of the mist discharged from the mist nozzle 9 due to the presence of the positive electrode plate 20. Then, the negative ions discharged from the ion discharge port 14a are attracted to the mist atmosphere of the mist discharged from the mist discharge port 9b, and the negative ions are mixed with the mist in the mist atmosphere. In this way, the mist is negatively charged. That is, the positive electrode plate 20 functions as an ion transfer means for transferring negative ions discharged from the ion discharge port 14a toward the mist discharged from the mist discharge port 9b.

  Further, when the amount of charge flowing through the positive electrode plate 20 detected by the charge amount detector 22 is less than a predetermined amount, the attractive force for attracting negative ions discharged from the ion discharge port 14a in the positive electrode plate 20 is small. Too much. Therefore, negative ions discharged from the ion discharge port 14a cannot be attracted into the mist atmosphere of the mist discharged from the mist discharge port 9b. Then, the negative ions discharged from the ion discharge port 14a float above the mist atmosphere, and the negative ions are not mixed with the mist in the mist atmosphere. That is, the mist charged with negative ions cannot be released toward the user's skin, and the barrier function of the skin is not improved. Here, the predetermined amount refers to a charge amount for creating an attractive force necessary for attracting negative ions discharged from the ion discharge port 14a into the mist atmosphere in the positive electrode plate 20. In this case, the control unit 30 adjusts the amount of charge flowing from the power source 21 to the plus electrode plate 20 so that a predetermined amount of charge flows through the plus electrode plate 20. Therefore, the control unit 30 can adjust the attractive force in the positive electrode plate 20 to the attractive force necessary for attracting negative ions discharged from the ion discharge port 14a into the mist atmosphere. The negative ions discharged from 14a can be mixed with the mist in the mist atmosphere. That is, mist charged with negative ions can be released to the user's skin, and the skin barrier function is improved.

  On the other hand, when the amount of charge flowing through the positive electrode plate 20 detected by the charge amount detector 22 is larger than a predetermined amount, the attractive force for attracting negative ions discharged from the ion discharge port 14a in the positive electrode plate 20 is large. Too much. Therefore, negative ions discharged from the ion discharge port 14a are unnecessarily attracted toward the direction intersecting the discharge direction m1 of the mist discharged from the mist discharge port 9b. Then, the negative ions are not mixed with the mist in the mist atmosphere and pass through the mist atmosphere, so that the negative ions cannot be charged to the mist. That is, the mist charged with negative ions cannot be released toward the user's skin, and the barrier function of the skin is not improved. In this case, the control unit 30 adjusts the amount of charge flowing from the power source 21 to the plus electrode plate 20 so that a predetermined amount of charge flows through the plus electrode plate 20. Therefore, the control unit 30 can adjust the attractive force in the positive electrode plate 20 to the attractive force necessary for attracting negative ions discharged from the ion discharge port 14a into the mist atmosphere. The negative ions discharged from 14a can be mixed with the mist in the mist atmosphere. That is, mist charged with negative ions can be released to the user's skin, and the skin barrier function is improved.

  In this way, the control unit 30 can adjust the attractive force in the positive electrode plate 20 to an attractive force necessary for attracting negative ions discharged from the ion discharge port 14a into the mist atmosphere. That is, the controller 30 adjusts the amount of charge flowing through the positive electrode plate 20 in accordance with the detection result of the charge amount detector 22, thereby adjusting the attractive force for attracting negative ions discharged from the ion discharge port 14a. It functions as a force adjustment means.

  According to the mist generator 1 having the above-described configuration, the negative ions move toward the direction intersecting the discharge direction m1 of the mist discharged from the mist discharge port 9b while being attracted to the positive electrode plate 20. Therefore, the negative ions discharged from the ion discharge port 14a are attracted to the mist atmosphere of the mist discharged from the mist discharge port 9b, and the negative ions are mixed with the mist in the mist atmosphere. Therefore, more negative ions can be charged with respect to the mist.

Next, the effect on the user's skin (skin) by the mist charged with negative ions will be described.
Generally, the human epidermis is composed of a basal layer, a spiny layer, a granular layer, and a stratum corneum, and the stratum corneum constitutes the outermost layer side of the skin. The stratum corneum is composed of corneocytes and intercellular lipids composed mainly of ceramide that fills the space between the corneocytes. When the stratum corneum is filled with a sufficient amount of ceramide (intercellular lipid), the stratum corneum can exhibit a barrier property and suppress the transpiration of moisture from the skin, and can retain moisture. On the other hand, when the amount of ceramide is insufficient, the barrier property is lowered and moisture is easily evaporated from the skin, and the amount of moisture retained is reduced.

  When the mist charged with negative ions contacts the user's skin, the surface of the user's skin is negatively charged and water is replenished by the mist. When the skin surface is negatively charged, a weak negative potential on the skin surface is sensed, and the ceramide precursor is released from the granule layer toward the stratum corneum, and finally becomes ceramide between the corneocytes. Fill. Thereby, in the stratum corneum, the amount of intercellular lipid can be increased, the barrier function of the skin can be improved (improved), and the moisture retention amount of the skin can be increased (the moisturizing power can be improved). And the texture (texture) of a user's skin can be improved.

  From the above, in order to improve the skin barrier function and improve the moisturizing power, it is desirable to charge more negative ions to the mist and adhere to the user's skin. For this reason, it is preferable to dispose the mist discharge port 9b and the ion discharge port 14a as close to each other as possible so that negative ions can be easily charged in the mist. On the other hand, by bringing the mist discharge port 9b and the ion discharge port 14a close to each other, the mist flows from the ion discharge port 14a and the humidity in the vicinity of the corona discharge unit 10 is increased, and negative ions are generated in the corona discharge unit 10. The problem that the amount is reduced can arise. However, according to the mist generating apparatus 1 of the present embodiment, the mist discharge port 9b and the ion discharge port 14a are arranged at positions separated by a distance within a predetermined range, and the mist discharged from the mist discharge port 9b is ionized. Inflow to the discharge port 14a is avoided. Further, the negative ions discharged from the ion discharge port 14a by the positive electrode plate 20 are attracted to the mist atmosphere of the mist discharged from the mist discharge port 9b, thereby charging the mist with the negative ions. Yes. That is, the humidity near the corona discharge part 10 is suppressed from rising due to mist, and stable corona discharge is performed so that the amount of negative ions generated is not reduced, and negative ions are generated and generated stably. The negative ions can be charged to the mist. And by attaching the mist charged with negative ions to the skin of the user, the barrier function of the skin can be improved and the moisturizing power can be improved.

In the above embodiment, the following effects can be obtained.
(1) The positive electrode plate 20 is arranged in parallel at the lower part of the mist nozzle 9 so as to be positioned on the same straight line as the ion nozzle 14 (ion discharge port 14a) and the mist nozzle 9 (mist discharge port 9b) in the vertical direction. Has been. Therefore, the negative ions discharged from the ion discharge port 14a move toward the direction intersecting the discharge direction m1 of the mist discharged from the mist discharge port 9b while being attracted to the positive electrode plate 20. Therefore, the negative ions discharged from the ion discharge port 14a are attracted to the mist atmosphere of the mist discharged from the mist discharge port 9b, and the negative ions are mixed with the mist in the mist atmosphere. Therefore, more negative ions can be charged with respect to the mist.

  (2) The control unit 30 adjusts the attractive force in the positive electrode plate 20 to the attractive force necessary to attract the negative ions discharged from the ion discharge port 14a into the mist atmosphere, so that the ion discharge port The negative ions discharged from 14a can be attracted into the mist atmosphere of the mist discharged from the mist discharge port 9b. Therefore, the negative ions are mixed with the mist in the mist atmosphere, and the mist charged with the negative ions can be released to the user's skin, thereby improving the skin barrier function.

  (3) If the mist generator 1 having the above configuration is used, it is possible to release a mist having a lot of negative ions toward the user's skin. By releasing a mist with a lot of negative ions to the user's skin, a lot of negative charges are charged on the surface of the stratum corneum, and a large amount of lipid components such as ceramide are released between the corneocytes from the epidermal granule layer. By increasing the amount of ceramide released, ceramide is further dispersed on the surface of the stratum corneum and the space between the stratum corneum is filled to further prevent moisture from evaporating from the skin surface. Will improve.

  (4) By providing the positive electrode plate 20, even if the mist discharge port 9b and the ion discharge port 14a are arranged at positions separated by a distance within a predetermined range, negative ions discharged from the ion discharge port 14a While being attracted into the mist atmosphere of the mist discharged from the mist discharge port 9b, negative ions are mixed with the mist in the mist atmosphere. Therefore, it is possible to charge negative ions to the mist while avoiding the mist discharged from the mist discharge port 9b from flowing into the ion discharge port 14a. That is, the humidity near the corona discharge part 10 is suppressed from rising due to mist, and stable corona discharge is performed so that the amount of negative ions generated is not reduced, and negative ions are generated and generated stably. The negative ions can be charged to the mist. And by attaching the mist charged with negative ions to the skin of the user, the barrier function of the skin can be improved and the moisturizing power can be improved.

(Second Embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to FIG. Note that, in the embodiments described below, the same reference numerals are given to the same configurations as those of the embodiments already described, and redundant descriptions thereof are omitted or simplified.

  As shown in FIG. 2, the plus electrode plate 20 is supported in the mist discharge path 9a of the mist nozzle 9, and the tip side of the plus electrode plate 20 is moved from the inside of the mist nozzle 9 to the outside through the mist discharge port 9b. Exposed. The positive electrode plate 20 is supported by the support portion 20 a so as to be positioned on the central axis of the mist nozzle 9.

  According to the mist generating apparatus 1 having the above-described configuration, negative ions are attracted toward the mist discharge port 9b while being attracted to the positive electrode plate 20 as in the negative ion movement path R2 indicated by a one-dot chain line in FIG. To move. Therefore, the negative ions discharged from the ion discharge port 14a are attracted to the mist atmosphere of the mist discharged from the mist discharge port 9b in the vicinity of the mist discharge port 9b, and the negative ions are mist in the mist atmosphere. Mixed with. Therefore, more negative ions can be charged with respect to the mist.

Therefore, according to the present embodiment, in addition to the effects (2) to (4) of the first embodiment, the following effects can be obtained.
(5) The positive electrode plate 20 is supported in the mist discharge path 9a of the mist nozzle 9, and the front end side of the positive electrode plate 20 is exposed to the outside from the mist nozzle 9 through the mist discharge port 9b. . Therefore, the negative ions discharged from the ion discharge port 14a are attracted to the mist atmosphere of the mist discharged from the mist discharge port 9b in the vicinity of the mist discharge port 9b, and the negative ions are mist in the mist atmosphere. Mixed with. Therefore, more negative ions can be charged with respect to the mist.

(Third embodiment)
Hereinafter, a third embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 3, an intake hole 41 for inhaling air is formed in the wall surface of the main body case 2 (in this embodiment, the upper wall 2 b of the main body case 2). The intake hole 41 and the ion nozzle 14 communicate with each other via a communication pipe 42. In the communication tube 42, a fan 40 is provided on the upstream side of the discharge needle 12 to send a wind that sends negative ions discharged from the discharge needle 12 toward the ion discharge port 14 a.

  Air is sent from the intake hole 41 toward the fan 40, and air is sent to the discharge needle 12 side by wind generated by driving the fan 40. Then, the negative ions discharged from the discharge needle 12 are moved toward the ion discharge port 14a by the air sent from the fan 40 as shown in the movement path R3 of the negative ions indicated by the one-dot chain line in FIG. It discharges from the outlet 14a in the horizontal direction.

  On the other hand, the mist nozzle 90 is inclined obliquely upward with respect to the mist flow path 8. The mist nozzle 90 is slanted so that the crossing angle α between the negative ion discharge direction and the mist discharge direction m1 is an angle (30 ° in this embodiment) within a predetermined range (15 ° to 120 °). It is set to discharge mist upward.

  According to the mist generating apparatus 1 having the above-described configuration, the negative ions sent out from the ion discharge port 14a in the horizontal direction by the fan 40 move toward the mist discharge direction m1. Therefore, the negative ions discharged from the ion discharge port 14a are transferred into the mist atmosphere of the mist discharged from the mist discharge port 9b, and the negative ions are mixed with the mist in the mist atmosphere. Therefore, negative ions can be transferred toward the mist discharged from the mist discharge port 9b, and more negative ions can be charged with respect to the mist. That is, the fan 40 is a blowing unit that sends a wind that sends negative ions generated from the corona discharge unit 10 toward the ion discharge port 14a, and functions as an ion transfer unit.

Therefore, according to this embodiment, in addition to the effects (3) and (4) of the first embodiment, the following effects can be obtained.
(6) A fan 40 is provided on the upstream side of the discharge needle 12 to send a wind that sends negative ions discharged from the discharge needle 12 toward the ion discharge port 14a. Therefore, the negative ions discharged from the ion discharge port 14a are transferred into the mist atmosphere of the mist discharged from the mist discharge port 9b, and the negative ions are mixed with the mist in the mist atmosphere. Therefore, negative ions can be transferred toward the mist discharged from the mist discharge port 9b, and more negative ions can be charged with respect to the mist.

(Fourth embodiment)
Hereinafter, a fourth embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 4, on the upstream side of the discharge needle 12, a negative electrode plate 50 is provided as the same polarity electrode portion having the same polarity as the negative ions discharged from the discharge needle 12. The negative electrode plate 50 is electrically connected to the high voltage power supply circuit 11, and a negative voltage is applied from the high voltage power supply circuit 11 so that a negative electrode is generated.

  Since the negative ions and the negative electrode plate 50 have the same polarity, the negative ions discharged from the discharge needle 12 repel each other and the negative force shown by the one-dot chain line in FIG. Like the ion movement path R4, it moves toward the ion discharge port 14a and is discharged from the ion discharge port 14a in the horizontal direction.

  On the other hand, the mist nozzle 90 is inclined obliquely upward with respect to the mist flow path 8. The mist nozzle 90 is slanted so that the crossing angle α between the negative ion discharge direction and the mist discharge direction m1 is an angle (30 ° in this embodiment) within a predetermined range (15 ° to 120 °). It is set to discharge mist upward.

  According to the mist generating apparatus 1 having the above-described configuration, the negative ions discharged from the discharge needle 12 repel each other with the negative electrode plate 50, and are sent out from the ion discharge port 14a in the horizontal direction along with this repulsive force. Move towards m1. Therefore, the negative ions discharged from the ion discharge port 14a are transferred into the mist atmosphere of the mist discharged from the mist discharge port 9b, and the negative ions are mixed with the mist in the mist atmosphere. Therefore, negative ions can be transferred toward the mist discharged from the mist discharge port 9b, and more negative ions can be charged with respect to the mist. That is, the negative electrode plate 50 functions as an ion transfer means for transferring negative ions discharged from the ion discharge port 14a toward the mist discharged from the mist discharge port 9b.

Therefore, according to this embodiment, in addition to the effects (3) and (4) of the first embodiment, the following effects can be obtained.
(7) On the upstream side of the discharge needle 12, a negative electrode plate 50 having the same polarity as the negative ions discharged from the discharge needle 12 is provided. Therefore, the negative ions discharged from the discharge needle 12 and the negative ions discharged from the ion discharge port 14a by the repulsive force of the negative electrode plate 50 are transferred into the mist atmosphere of the mist discharged from the mist discharge port 9b. In the mist atmosphere, negative ions are mixed with the mist. Therefore, negative ions can be transferred toward the mist discharged from the mist discharge port 9b, and more negative ions can be charged with respect to the mist.

In addition, you may change the said embodiment as follows.
In the first and second embodiments, the control unit 30 attracts negative ions discharged from the ion discharge port 14a by adjusting the amount of charge flowing through the positive electrode plate 20 according to the detection result of the charge amount detector 22. It is not necessary to function as an attractive force adjusting means for adjusting the attractive force. In this case, a constant charge amount is always applied to the positive electrode plate 20 so that the attractive force in the positive electrode plate 20 becomes an attractive force necessary for attracting negative ions discharged from the ion discharge port 14a into the mist atmosphere. 20 to flow.

  In the third and fourth embodiments, the mist ejection direction m1 is the horizontal direction, and the intersection angle α between the minus ion ejection direction and the mist ejection direction m1 is within a predetermined range (15 ° to 120 °). The ion nozzle 14 may be set so that negative ions are discharged obliquely downward so that the inner angle (30 ° in the present embodiment) is obtained.

  In each embodiment, the method of heating and boiling the liquid in the liquid reservoir 6 by the heater 7 is adopted as the mist generating means, but mist may be generated by other methods. For example, the mist may be generated by a method of atomizing a liquid with ultrasonic waves, a method using a venturi effect known from a principle such as spraying, or the like.

  In each embodiment, the ions generated from the ion generating means are not limited to negative ions, and for example, positive ions may be generated. In this case, in the first and second embodiments, a negative electrode plate having a polarity opposite to that of positive ions is used as the reverse polarity electrode portion.

The following technical idea (invention) can be understood from the embodiment.
(1) The mist generator according to any one of claims 1 to 6, wherein the ions are negative ions.

(A) is the longitudinal cross-sectional view of the mist generator in 1st Embodiment, (b) is the expanded sectional view to which the vicinity of the mist nozzle and the ion nozzle was expanded. The expanded sectional view which expanded the vicinity of the mist nozzle and ion nozzle in 2nd Embodiment. The expanded sectional view which expanded the vicinity of the mist nozzle and ion nozzle in 3rd Embodiment. The expanded sectional view which expanded the vicinity of the mist nozzle and ion nozzle in 4th Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Mist generator, 6 ... Liquid reservoir which comprises mist generating means, 7 ... Heater which comprises mist generating means, 9, 90 ... Mist nozzle, 9b ... Mist discharge port, 10 ... Corona discharge as ion generating means , 12 ... discharge needle as an ion discharge part, 14a ... ion ejection port, 20 ... positive electrode plate as a reverse polarity electrode part functioning as ion transfer means, 22 ... charge quantity detector as charge quantity detection means, 30 A control unit that functions as an attraction force adjusting unit, 40 a fan as a blowing unit, 50 a negative electrode plate as an identical polarity electrode unit that functions as an ion transfer unit.

Claims (6)

In a mist generating apparatus comprising: a mist generating means for generating mist; a mist outlet for discharging the mist; an ion generator for generating ions; and an ion outlet for discharging the ions;
An mist generating apparatus, comprising: ion transfer means for transferring ions discharged from the ion discharge port toward the mist discharged from the mist discharge port.   The mist generator according to claim 1, wherein the ion transfer means is a reverse polarity electrode unit having a polarity opposite to that of the ions.   The reverse polarity electrode portion is supported in a mist nozzle connected to the mist discharge port, and a tip side of the reverse polarity electrode portion is exposed to the outside from the mist nozzle through the mist discharge port. Item 3. The mist generator according to Item 2. Charge amount detection means for detecting the amount of charge flowing in the reverse polarity electrode portion;
And an attractive force adjusting means for adjusting an attractive force for attracting ions ejected from the ion ejection port by adjusting an amount of charge flowing through the reverse polarity electrode unit according to a detection result of the charge amount detecting means. The mist generator according to claim 2 or claim 3, wherein The ion transfer means is a blower means for sending a wind for sending ions generated from the ion generation means toward the ion discharge port side,
The mist generating apparatus according to claim 1, wherein the air blowing unit is provided on an upstream side of an ion discharge portion constituting the ion generating unit. The ion transfer means is the same polarity electrode part having the same polarity as the ions,
The mist generating apparatus according to claim 1, wherein the same polarity electrode portion is provided upstream of an ion discharge portion constituting the ion generating means.

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