JP7175229B2 - ion generator - Google Patents

Description

The present invention relates to an ion generator.

The ion generator described in Patent Literature 1 includes an electrode, a blower, and an outer casing. The electrodes and the blower are arranged inside the outer housing. An air supply port is formed in the outer casing. The electrodes generate ions. A blower transports the ions generated by the electrodes with an air flow. Ions are discharged from the air supply port.

JP 2016-46046 A

However, when the wind flows spirally from the blower, the wind spirals around the electrodes without passing through the electrodes, which may reduce the amount of air passing through the electrodes. If the amount of air passing through the electrode decreases, the amount of ions discharged from the air supply port, that is, the amount of ions generated may decrease.

An object of the present invention is to provide an ion generator capable of suppressing a decrease in the amount of generated ions.

According to the first aspect of the present application, an ion generator includes an air blower, a discharge electrode, and a guide surface. The air blower sends a spiral wind that flows spirally. A discharge electrode is arranged downstream of the blower. The guide surface guides the spiral wind to the discharge electrode.

According to the ion generator of the present invention, it is possible to suppress a decrease in the amount of generated ions.

It is a side view of an ion generator concerning an embodiment of the present invention. It is a sectional view of an ion generator. It is a front view which shows an air blower and an ion supply part. It is a bottom view of an ion supply part. It is a figure which shows an example of the circuit structure of an ion generating element. It is a perspective view which shows the 1st example of operation|movement of an ion supply part. FIG. 11 is a perspective view showing a second example of the operation of the ion supply section; It is a front view of an ion supply part. It is a schematic diagram which shows the modification of an ion supply part.

An embodiment of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and description thereof will not be repeated.

An ion generator 100 according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is a side view of an ion generator 100 according to an embodiment of the invention. FIG. 2 is a cross-sectional view of the ion generator 100. FIG.

As shown in FIGS. 1 and 2, the ion generator 100 includes a housing 1. As shown in FIG. The housing 1 is a hollow member. The housing 1 is a hollow member made of resin, for example.

Housing 1 includes a first housing 10 and a second housing 20 . A second housing 20 is detachably attached to the first housing 10 . The second housing 20 is positioned outside the first housing 10 . A part of the first housing 10 is covered with the second housing 20 by attaching the second housing 20 to the first housing 10 . Note that the first housing 10 and the second housing 20 may be an integral member.

Housing 1 further includes a grip portion 3 . The grip portion 3 has a shape in which a portion of the outer surface of the housing 1 is recessed. A user holds the holding part 3 and carries the ion generator 100 .

An intake port A is formed in the housing 1 . The intake port A communicates the inside M of the housing 1 with the outside. An intake port A is formed in the lower portion 12 of the housing 1 .

An air outlet B is further formed in the housing 1 . The outlet B communicates the inside M and the outside of the housing 1 . The outlet B is formed in the upper portion 11 of the housing 1 .

As shown in FIG. 4 , the ion generator 100 further includes a light emitting section 4 , a purification section 5 and an air blowing section 6 .

The light emitting unit 4 , the purifying unit 5 , and the air blowing unit 6 are arranged inside M of the housing 1 .

The light emitting unit 4 emits light toward the purification unit 5 . The light emitting unit 4 includes, for example, a light source such as an LED.

The purifier 5 purifies air. The purification unit 5 is arranged above the light emitting unit 4 . Purification unit 5 includes, for example, a photocatalyst filter. The photocatalyst contained in the photocatalyst filter generates a catalytic action by being irradiated with light from the light emitting section 4 . As a result, when the air passes through the photocatalyst filter of the purifier 5, odorous components in the air are decomposed. Smell components are, for example, ammonia, methyl mercaptan, trimethylamine, and/or nonenal.

The purifier 5 may include a physical adsorption filter and/or a chemical adsorption filter, and may adsorb odorous components using the physical adsorption filter and/or the chemical adsorption filter. If the photocatalyst filter is not used, the ion generator 100 does not have to include the light emitting section 4 .

Further, in the present embodiment, the purifier 5 reduces odorous components in the air as a first example of air purification. However, the invention is not so limited. As a second example of air purification, the purification unit 5 may reduce dust in the air. In this case, the purification unit 5 includes, for example, a HEPA filter.

An air passage N is formed in the interior M of the housing 1 . In this embodiment, the air passage N extends along the vertical direction. The air passage N communicates with the air inlet A and the air outlet B. As shown in FIG. A purifier 5 and a blower 6 are arranged on the air path N. As shown in FIG.

The blower 6 generates wind (air flow). The air blower 6 includes, for example, a fan 6a (see FIG. 3) and a drive source for rotating the fan 6a. The drive source includes, for example, a motor.

The ion generator 100 further includes an ion supply section 7 . The ion supply unit 7 is arranged inside M of the housing 1 . The ion supply unit 7 is arranged on the air path N. As shown in FIG. The ion supply unit 7 is arranged downstream of the blower unit 6 . The ion supply unit 7 supplies ions to the wind flowing through the air passage N. As shown in FIG. Ions include, for example, at least one of positive ions and negative ions.

The ion generator 100 further includes a straightening section 8 and a louver 9 . The rectifying section 8 and the louver 9 are arranged inside M of the housing 1 . The straightening section 8 and the louver 9 are arranged on the air passage N. As shown in FIG.

The straightening section 8 guides the air blown by the air blowing section 6 . The rectifying section 8 is arranged downstream of the ion supplying section 7 . The rectifying section 8 is fixed to the housing 1 .

The louver 9 guides the air flowing from the straightening section 8 . The louver 9 is arranged downstream of the straightening section 8 . The louver 9 is arranged just before the outlet B on the air path N.

Louver 9 is rotatably attached to housing 1 . By changing the rotation angle of the louver 9 with respect to the housing 1, the discharge direction H of the air discharged from the air outlet B is changed.

The ion generator 100 further includes a storage section S1 and a control section S2.

The storage unit S1 includes a main storage device (eg, semiconductor memory) such as ROM (Read Only Memory) and RAM (Random Access Memory), and may further include an auxiliary storage device (eg, hard disk drive). The main memory and/or auxiliary memory store various computer programs executed by the controller S2.

The control unit S2 includes processors such as a CPU (Central Processing Unit) and an MPU (Micro Processing Unit). The controller S<b>2 controls each element of the ion generator 100 .

The flow of air through the air passage N will be described with reference to FIG.

As shown in FIG. 2 , by operating the air blower 6 , air flows from the outside of the housing 1 into the interior M of the housing 1 through the intake port A. As shown in FIG. The wind that has flowed into the interior M of the housing 1 flows through the interior M of the housing 1 in the order of the purification unit 5 and the ion supply unit 7 . The wind flowing through the purifying section 5 and the ion supplying section 7 is purified when passing through the purifying section 5 and supplied with ions when passing through the ion supplying section 7 . After passing through the purifier 5 and the ion supply unit 7 , the wind passes through the straightening unit 8 and is discharged from the outlet B in the direction corresponding to the rotation angle of the louver 9 . As a result, the air that has been purified and supplied with ions is discharged from the outlet B. In this embodiment, the operation of the blower 6 means that the motor, which is the driving source of the blower 6, rotates the fan 6a (see FIG. 3).

Note that the ion generator 100 need not include both the purification unit 5 and the ion supply unit 7 , and may include at least the ion supply unit 7 out of the purification unit 5 and the ion supply unit 7 .

Next, the blower section 6 and the ion supply section 7 will be further described with reference to FIGS. 3 to 5. FIG. FIG. 3 is a front view showing the blower section 6 and the ion supply section 7. As shown in FIG. 4 is a bottom view of the ion supply unit 7. FIG.

As shown in FIGS. 3 and 4, the blower section 6 generates a spiral wind F1 by rotating the fan 6a. The spiral wind F<b>1 is wind that spirally flows from the air blower 6 toward the ion supply unit 7 . The spiral wind F<b>1 includes air after passing through the purifier 5 , that is, air purified by the purifier 5 .

The spiral wind F1 flows spirally around the central axis Z. A central axis Z is an axis extending from the air blowing section 6 toward the ion supplying section 7 . In the present embodiment, the central axis Z extends along the vertical direction while passing through the blower section 6 and the ion supply section 7 .

In this embodiment, the air blower 6 sends the spiral air F1 upward. An ion supply unit 7 is arranged above the blower unit 6 .

The ion supply unit 7 includes a housing 71 , a first discharge electrode 72 , a second discharge electrode 73 , a first guide plate 74 and a second guide plate 75 .

The housing 71 is made of, for example, insulating resin. Each of the first discharge electrode 72 and the second discharge electrode 73 is attached to the housing 71 .

Each of the first discharge electrode 72 and the second discharge electrode 73 is a needle-like electrode. Each of the first discharge electrode 72 and the second discharge electrode 73 is made of, for example, a conductive metal. The first discharge electrode 72 emits positive ions by discharging. The second discharge electrode 73 emits negative ions by discharging.

Each of the first discharge electrode 72 and the second discharge electrode 73 protrudes from the front surface 71 a of the housing 71 . The first discharge electrode 72 and the second discharge electrode 73 are separated from each other along the horizontal direction. A central axis Z is positioned between the first discharge electrode 72 and the second discharge electrode 73 .

Each of the first guide plate 74 and the second guide plate 75 is a plate-like member. Each of the first guide plate 74 and the second guide plate 75 is made of resin, for example. Each of the first guide plate 74 and the second guide plate 75 is provided on the housing 71 . Each of the first guide plate 74 and the second guide plate 75 may be a member integrated with the housing 71 or a separate member from the housing 71 .

The first guide plate 74 includes a first guide surface 74a. The first guide surface 74a is a plane parallel to the vertical direction. The first guide surface 74 a is arranged below the first discharge electrode 72 . The first guide surface 74a is arranged at a location spaced apart from the first discharge electrode 72 toward the air blower 6 side. The first guide surface 74a is positioned on the air path of the spiral wind F1. The first guide surface 74a faces forward.

The second guide plate 75 includes a second guide surface 75a. The second guide surface 75a is a plane parallel to the vertical direction. The second guide surface 75 a is arranged below the second discharge electrode 73 . The second guide surface 75a is arranged at a location spaced apart from the second discharge electrode 73 toward the air blower 6 side. The second guide surface 75a is positioned on the air path of the spiral wind F1. The second guide surface 75a faces rearward. The second guide surface 75a faces the opposite side to the first guide surface 74a.

The first guide surface 74a and the second guide surface 75a are separated from each other along the left-right direction. A central axis Z is positioned between the first guide surface 74a and the second guide surface 75a.

As shown in FIG. 4, the first discharge electrode 72 and the first guide surface 74a are arranged in the same direction (forward). Regarding the position in the front-rear direction, the first guide surface 74a is arranged at substantially the same position as the base portion 72a of the first discharge electrode 72, or slightly behind the base portion 72a.

The second discharge electrode 73 and the second guide surface 75a are arranged opposite to each other. The second discharge electrode 73 is arranged forward, and the second guide surface 75a is arranged rearward. Regarding the position in the front-rear direction, the second guide surface 75a is arranged at substantially the same position as the tip portion 73b of the second discharge electrode 73 or slightly ahead of the tip portion 73b. The second guide surface 75a is arranged to face the tip portion 73b of the second discharge electrode 73 when the ion supply portion 7 is viewed in the vertical direction.

As shown in FIGS. 3 and 4 , the ion supply section 7 further includes a first side wall portion 76 , a second side wall portion 77 and a third side wall portion 79 .

The first side wall portion 76 is provided on the housing 1 . The first side wall portion 76 is a wall-shaped member that covers the first discharge electrode 72 from the side. The first side wall portion 76 has a shape that protrudes forward from the housing 1 while extending along the vertical direction. The first side wall portion 76 faces the first discharge electrode 72 from the side. The first side wall portion 76 is further away from the central axis Z than the first discharge electrode 72 is.

The second side wall portion 77 is provided on the housing 1 . The second side wall portion 77 is a wall-shaped member that covers the second discharge electrode 73 from the side. The second side wall portion 77 has a shape that protrudes forward from the housing 1 while extending along the vertical direction. The second side wall portion 77 faces the second discharge electrode 73 from the side. The second side wall portion 77 is further away from the central axis Z than the second discharge electrode 73 is. Also, the second side wall portion 77 continues to the second guide plate 75 .

The third side wall portion 79 is provided on the housing 1 . The third side wall portion 79 continues to the second guide plate 75 . A second guide plate 75 is positioned between the third side wall portion 79 and the second side wall portion 77 .

The ion supply section 7 further includes an ion generation element 78 .

The ion generating element 78 emits ions from each of the first discharge electrode 72 and the second discharge electrode 73 . The ion generating element 78 is housed in the housing 71 . Each of the first discharge electrode 72 and the second discharge electrode 73 is connected to the ion generating element 78 .

The ion generating element 78 will be described with reference to FIG. FIG. 5 is a diagram showing an example of the circuit configuration of the ion generating element 78. As shown in FIG.

As shown in FIG. 5, the ion generating element 78 includes a first land 78a, a capacitor 78b, a step-up transformer 78c, a transistor 78d, a first diode 78e, a second diode 78f, and a first induction electrode 78g. , and a second induction electrode 78h. The ion generating element 78 is provided on the circuit board.

Capacitor 78b is temporarily charged based on the drive voltage supplied via first land 78a. The capacitor 78b supplies the drive voltage to the step-up transformer 78c.

Step-up transformer 78 c includes primary winding 781 and secondary winding 782 . The step-up transformer 78c steps up the driving voltage supplied from the capacitor 78b. The step-up transformer 78 c applies the drive voltage to the first discharge electrode 72 and the second discharge electrode 73 .

Transistor 78d controls step-up transformer 78c. Transistor 78d includes, for example, a packaged MOS transistor.

A first diode 78e rectifies the current. The anode of the first diode 78e is connected to the secondary winding 782 of the step-up transformer 78c. A cathode of the first diode 78 e is connected to the first discharge electrode 72 .

A second diode 78f rectifies the current. An anode of the second diode 78 f is connected to the second discharge electrode 73 . A cathode of the second diode 78f is connected to the secondary winding 782 of the step-up transformer 78c.

A first induction electrode 78 g is arranged near the first discharge electrode 72 . The first induction electrode 78g induces the first discharge electrode 72 to generate a discharge. A second induction electrode 78 h is arranged near the second discharge electrode 73 . The second induction electrode 78 h induces discharge in the second discharge electrode 73 .

The capacitor 78b is repeatedly charged and discharged, and the ON/OFF operation of the transistor 78d is switched in synchronization with the charging and discharging of the capacitor 78b, thereby generating an impulse voltage in the primary winding 781 of the step-up transformer 78c. As a result, a positive high voltage pulse and a negative high voltage pulse are alternately generated in the secondary winding 782 of the step-up transformer 78c.

A positive high voltage pulse generated by the secondary winding 782 is applied to the first discharge electrode 72 via the first diode 78e. A negative high voltage pulse generated by the secondary winding 782 is applied to the second discharge electrode 73 via the second diode 78f. Accordingly, corona discharge is generated at the first discharge electrode 72 . As a result, positive ions are emitted from the first discharge electrode 72 . Also, a corona discharge is generated at the second discharge electrode 73 . As a result, negative ions are emitted from the second discharge electrode 73 .

Positive ions produced by the corona discharge combine with moisture in the air. The positive ions combined with water contain H ⁺ (H ₂ O) and form positively charged cluster ions. In addition, negative ions generated by corona discharge combine with moisture in the air. The negative ions include O ₂ ⁻ (H ₂ O) and form negatively charged cluster ions. By changing the voltage and pulse period applied to each of the first discharge electrode 72 and the second discharge electrode 73, the amount of ions generated from each of the first discharge electrode 72 and the second discharge electrode 73 is reduced to adjusted. The amount of ions, in other words, indicates the concentration of ions.

A first example of the operation of the ion supply unit 7 will be described with reference to FIGS. 2 and 6. FIG. FIG. 6 is a perspective view showing a first example of the operation of the ion supply section 7. FIG.

FIG. 6 shows the spiral wind F11. The helical wind F11 is part of the helical wind F1 (see FIG. 3) sent from the air blower 6. As shown in FIG.

As shown in FIGS. 2 and 6, the spiral wind F11, when sent from the blower section 6, spirally flows toward the ion supply section 7 around the central axis Z. As shown in FIGS. The spiral wind F11 hits the first guide surface 74a from the front. The helical wind F11 hits the first guide surface 74a and changes its flow direction to become a reflected wind F21. The spiral wind F11 flows toward the first discharge electrode 72 along the first guide surface 74a. That is, the first guide surface 74a changes the spiral wind F11 that flows spirally into the reflected wind F21 that flows substantially straight. When the reflected wind F21 passes through the first discharge electrode 72, positive ions are emitted from the first discharge electrode 72 in the airflow of the reflected wind F21. As a result, the reflected wind F21 containing positive ions is discharged to the outside of the housing 1 from the air outlet B after passing through the rectifying section 8 and the louver 9 .

As described above with reference to FIGS. 2 and 6 , the flat first guide surface 74 a guides the spiral wind F<b>11 to the first discharge electrode 72 . Therefore, the spiral wind F11 (reflected wind F21) that hits the first guide surface 74a can be moved toward the first discharge electrode 72 along the first guide surface 74a. can effectively flow the reflected wind F21. As a result, it is possible to suppress the decrease in the amount of positive ions generated (the amount of positive ions discharged from the outlet B).

Next, a second example of the operation of the ion supply unit 7 will be described with reference to FIGS. 2 and 7. FIG. FIG. 7 is a perspective view showing a second example of the operation of the ion supply section 7. FIG.

FIG. 7 shows the spiral wind F12. The helical wind F12 is another part of the helical wind F1 (see FIG. 3) sent from the air blower 6. As shown in FIG.

As shown in FIGS. 2 and 7, when the spiral wind F12 is sent from the blower section 6, it spirally flows toward the ion supply section 7 around the central axis Z. As shown in FIGS. The spiral wind F12 hits the second guide surface 75a from behind. The helical wind F12 hits the second guide surface 75a and changes its flow direction to become a reflected wind F22. The reflected wind F22 flows toward the second discharge electrode 73 along the second guide surface 75a. That is, the second guide surface 75a changes the spiral wind F12 flowing in a spiral shape into the reflected wind F22 flowing substantially straight. The reflected wind F22 emits negative ions from the second discharge electrode 73 when passing through the second discharge electrode 73 . As a result, the reflected wind F<b>22 containing negative ions is discharged to the outside of the housing 1 from the outlet B after passing through the rectifier 8 and the louver 9 .

As described above with reference to FIGS. 2 and 7 , the flat second guide surface 75 a guides the spiral wind F<b>12 to the second discharge electrode 73 . Therefore, the spiral wind F12 (reflected wind F22) hitting the second guide surface 75a can be moved toward the second discharge electrode 73 along the second guide surface 75a. can effectively flow the reflected wind F22. As a result, it is possible to suppress a decrease in the amount of negative ions generated (the amount of negative ions discharged from the outlet B). Further, since the sides of the second guide surface 75a are surrounded by the second side wall portion 77 and the third side wall portion 79, the spiral wind F12 can be effectively guided to the second guide surface 75a, and the reflected wind F22 can be effectively guided to the second discharge electrode 73 .

Next, the ion supply section 7 will be further described with reference to FIGS. 3 and 6 to 8. FIG. FIG. 8 is a front view of the ion supply unit 7. FIG.

As shown in FIGS. 3 and 6 to 8, the area V1 of the first guide surface 74a has a size corresponding to the air volume of the reflected air F21 supplied to the first discharge electrode 72. As shown in FIG. As the area V1 of the first guide surface 74a increases, the amount of the reflected air F21 supplied to the first discharge electrode 72 by the first guide surface 74a increases.

The area V2 of the second guide surface 75a has a size corresponding to the air volume of the reflected air F22 supplied to the second discharge electrode 73. As shown in FIG. As the area V2 of the second guide surface 75a increases, the amount of the reflected air F22 supplied to the second discharge electrode 73 by the second guide surface 75a increases.

In this embodiment, the area V1 of the first guide surface 74a is larger than the area V2 of the second guide surface 75a (S1>S2).

Further, in this embodiment, the distance D1 from the first discharge electrode 72 to the central axis Z is longer than the distance D2 from the second discharge electrode 73 to the central axis Z (D1>D2). In other words, the first discharge electrode 72 is more distant from the air blower 6 than the second discharge electrode 73 is.

When the distance D1 is longer than the distance D2, the air volume of the reflected air F21 supplied to the first discharge electrode 72 is generally smaller than the air volume of the reflected air F22 supplied to the second discharge electrode 73. Become. However, by making the area V1 of the first guide surface 74a larger than the area V2 of the second guide surface 75a, the air volume of the reflected air F21 supplied to the first discharge electrode 72 and the amount of air supplied to the second discharge electrode 73 It is possible to prevent a difference from occurring between the reflected wind F22 and the air volume of the reflected wind F22. As a result, it is possible to suppress the difference between the amount of positive ions supplied to the reflected wind F21 from the first discharge electrode 72 and the amount of negative ions supplied to the reflected wind F22 from the second discharge electrode 73. Therefore, positive ions and negative ions can be generated in good balance.

In addition, without changing the configuration of each of the first discharge electrode 72 and the second discharge electrode 73, only by changing the ratio between the area V1 of the first guide surface 74a and the area V2 of the second guide surface 75a, , the positive ions and negative ions generated from the ion generator 100 can be balanced. As a result, the balance between positive ions and negative ions generated from the ion generator 100 can be easily adjusted.

In addition, each of the first guide plate 74 and the second guide plate 75 has a deformable structure (for example, an expandable structure), and each of the first guide plate 74 and the second guide plate 75 is deformable. By doing so, each of the area V1 of the first guide surface 74a and the area V2 of the second guide surface 75a may be changed. As a result, the balance between positive ions and negative ions can be adjusted more easily.

The embodiments of the present invention have been described above with reference to the drawings (FIGS. 1 to 8). However, the present invention is not limited to the above embodiments, and can be implemented in various aspects without departing from the scope of the invention (eg, (1) to (2)). Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above embodiments. For example, some components may be omitted from all components shown in the embodiments. In order to facilitate understanding, the drawings mainly show each component schematically, and the number of each component shown in the figure may differ from the actual number for convenience of drawing preparation. Also, each component shown in the above embodiment is an example and is not particularly limited, and various modifications are possible within a range that does not substantially deviate from the effects of the present invention.

(1) In this embodiment, the ion generator 100 includes the first discharge electrode 72 and the second discharge electrode 73 to generate positive ions and negative ions. However, the invention is not so limited. The ion generator 100 includes either one of the first discharge electrode 72 and the second discharge electrode 73, and may generate either positive ions or negative ions. . That is, the ion generator 100 may include either one of the first guide surface 74a and the second guide surface 75a.

Moreover, the ion generator 100 may include three or more discharge electrodes and three or more guide surfaces.

Moreover, the kind of ion which the ion generator 100 generate|occur|produces is not specifically limited. The ion generator 100 may generate nanoe (registered trademark), for example.

(2) A modification of the ion supply unit 7 will be described with reference to FIG. FIG. 9 is a schematic diagram showing a modification of the ion supply unit 7. As shown in FIG. In FIG. 9, the illustration of the second discharge electrode 73 and the second guide surface 75a is omitted.

As shown in FIG. 9, in the modified example of the ion supply unit 7, the inclination angle θ of the first guide surface 74a with respect to the front-rear direction (the direction perpendicular to the central axis Z) is an acute angle. In this case, the lower end of the first guide surface 74a is located on the front side (upstream side) of the upper end. In this case, the first guide surface 74a causes the spiral wind F11 that hits the first guide surface 74a to flow along the first guide surface 74a, which is a flat surface (inclined surface), thereby causing the reflected wind F21 that flows substantially straight. can be changed to As a result, the reflected wind F<b>21 can effectively flow to the first discharge electrode 72 . In addition, since the first guide surface 74a is inclined at an acute angle, the first guide surface 74a can guide the reflected wind F21 to the first discharge electrode 72 while suppressing the pressure loss of the reflected wind F21.

As with the inclination angle θ of the first guide surface 74a with respect to the front-rear direction, the inclination angle of the second guide surface 75a (see FIG. 7) with respect to the front-rear direction may be an acute angle. In this case, the lower end of the second guide surface 75a is located on the rear side (upstream side) of the upper end. In this case, the second guide surface 75a causes the spiral wind F12 that hits the second guide surface 75a to flow along the second guide surface 75a, which is a plane (inclined surface), thereby causing the reflected wind F22 that flows substantially straight. can be changed to As a result, the reflected wind F<b>22 can effectively flow to the second discharge electrode 73 . In addition, since the second guide surface 75a is inclined at an acute angle, the second guide surface 75a can guide the reflected wind F22 to the second discharge electrode 73 while suppressing the pressure loss of the reflected wind F22.

INDUSTRIAL APPLICABILITY The present invention can be used in the field of ion generators.

6 air blower 72 first discharge electrode 73 second discharge electrode 74a first guide surface 75a second guide surface 100 ion generators F1, F11, F12 spiral wind

Claims (7)

a blowing unit that sends a spiral wind that flows spirally;
a discharge electrode arranged downstream of the blower;
a guide surface that guides the spiral wind to the discharge electrode ,
The guide surface generates a reflected wind from the spiral wind that hits the guide surface,
the reflected wind flows along the guide surface toward the discharge electrode;
The ion generating device , wherein the area of the guide surface has a size corresponding to the air volume of the reflected air supplied to the discharge electrode . 2. The ion generator according to claim 1, wherein said guide surface is arranged at a location spaced apart from said discharge electrode toward said air blower, and is a surface parallel to the central axis of said spiral wind. 2. The ion generator according to claim 1, wherein said guide surface is arranged at a location spaced from said discharge electrode toward said air blower, and is a surface inclined at an acute angle with respect to a direction perpendicular to the central axis of said spiral wind. Device. The discharge electrode includes a first discharge electrode and a second discharge electrode,
The first discharge electrode and the second discharge electrode are separated from each other via the central axis,
The guide surface is
a first guide surface arranged at a location spaced apart from the first discharge electrode toward the air blower;
a second guide surface arranged at a location spaced from the second discharge electrode toward the air blower,
The ion generator according to claim 2 or 3 , wherein said first guide surface and said second guide surface face opposite sides to each other. The distance between the first discharge electrode and the central axis is longer than the distance between the second discharge electrode and the central axis,
The ion generator according to claim 4 , wherein the area of said first guide surface is larger than the area of said second guide surface. a blowing unit that sends a spiral wind that flows spirally;
a discharge electrode arranged downstream of the blower;
a guide surface that guides the spiral wind to the discharge electrode;
with
The guide surface is arranged at a location spaced from the discharge electrode toward the air blower, and is a surface parallel to the central axis of the spiral wind,
The guide surface generates a reflected wind from the spiral wind that hits the guide surface,
the reflected wind flows along the guide surface toward the discharge electrode;
The ion generating device, wherein the area of the guide surface has a size corresponding to the air volume of the reflected air supplied to the discharge electrode . a blowing unit that sends a spiral wind that flows spirally;
a discharge electrode arranged downstream of the blower;
a guide surface that guides the spiral wind to the discharge electrode;
with
The guide surface is a surface that is disposed at a location spaced from the discharge electrode toward the air blower and that is inclined at an acute angle with respect to a direction perpendicular to the central axis of the spiral wind.
The guide surface generates a reflected wind from the spiral wind that hits the guide surface,
the reflected wind flows along the guide surface toward the discharge electrode;
The ion generating device, wherein the area of the guide surface has a size corresponding to the air volume of the reflected air supplied to the discharge electrode .

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