KR20120035949A - Discharge device with electromagnetic shield - Google Patents

Abstract

Discharge device 1: discharge electrode 2; An electrical insulator 15 including an atomization chamber accommodating a discharge electrode 2; A water supply unit 4 supplying water to the surface of the discharge electrode 2; A high voltage supply unit (5) for applying a high voltage to the discharge electrode (2) to atomize the supplied water from the tip of the discharge electrode (2) as charged particulate water; And an electromagnetic shield 7 provided at least around the atomization chamber and having an opening for discharging charged particulate water.

Description

Discharge device with electromagnetic shielding {DISCHARGE DEVICE WITH ELECTROMAGNETIC SHIELD}

The present invention relates to a discharge device. In particular, the present invention relates to a discharge device that generates a discharge by applying a high voltage to the discharge electrode, and prevents the discharge from adversely affecting the peripheral electronic device.

In recent years, a discharge apparatus for generating atomized water by atomizing water has attracted attention. Charged particulate water is often referred to as fine droplets or nano-sized mists, the typical size of which is from a few nanometers to several tens of nanometers. Patent document 1 discloses such a discharge device as a prior art.

The above-described discharge device has an electronic circuit for atomizing liquid (ie, water) from the tip of the needle-shaped electrode, which is the discharge portion. This circuit includes a high voltage generator, a control circuit and the like.

Japanese Patent Laid-Open No. 2006-122759

To date, there exists a technique of generating condensed water by cooling air to reduce the step of supplying condensed water and applying a high voltage to the condensed water for atomizing the condensed water. However, the discharge in the atomization emits noise to the outside, and this noise may cause malfunction of the peripheral device. This can be a problem.

The present invention has been devised in view of the above situation, and an object of the present invention is to prevent a discharge electrode to be applied at a high voltage from being a source of noise that will adversely affect a peripheral device, and more preferably, from static electricity from the outside. To provide a discharge device that can prevent malfunction due to ambient noise, such as electromagnetic waves.

Discharge device according to an aspect of the present invention comprises: a discharge electrode; An electrical insulator including an atomization room accommodating the discharge electrode; A water supply unit supplying water to a surface of the discharge electrode; A high voltage supply unit for applying a high voltage to the discharge electrode to atomize the supplied water from the tip portion of the discharge electrode as charged particulate water; And an electromagnetic shield provided at least around the atomization chamber and having an opening for discharging the charged particulate water.

The electromagnetic shield may be an electrically conductive case accommodating the atomization chamber, the water supply unit, and the high voltage supply unit.

The electrically insulated part may be an electrically insulated case that further accommodates the water supply part and the high voltage supply part. In this case, the electromagnetic shield may be formed as a conductive layer covering the outer surface of the electrical insulator.

According to the discharge device having the above-described structure, the electromagnetic shielding portion can prevent the discharge electrode from being an emission source of noise to the outside. The discharge device can also prevent the discharge device from being affected by noise from the outside.

1 is a schematic diagram showing the structure of a discharge device according to an embodiment of the present invention.
2 is a cross sectional view around the discharge electrode of the discharge device.

Embodiments according to the present invention are described below with reference to the drawings.

1 shows a discharge device 1 according to an embodiment of the invention. The discharge device 1 is configured to generate the charged fine particle number M. FIG. As mentioned above, the charged particulate water (M) is often referred to as fine droplets or nano-sized mists, and the general size of the charged particulate water (M) is from several nanometers to several tens of nanometers.

As shown in FIG. 2, the discharge device 1 has: a discharge unit 11 and an electromagnetic shield 7 provided around the discharge unit 11. The discharge unit 11 includes: a discharge electrode 2; A water condensing apparatus 4 including a cooling section 4b and a heat dissipating section 4c; And a high voltage supply section 5. The cooling unit 4b cools the discharge electrode 2 to condense moisture in the air on the surface of the discharge electrode 2. The heat dissipation portion 4c dissipates heat generated while cooling the discharge electrode 2. The high voltage supply unit 5 supplies a high voltage to the discharge electrode 2 to atomize condensed water on the tip portion 2a of the discharge electrode 2. In this embodiment, the high voltage supply unit 5 applies a negative high voltage to the discharge electrode 2.

The tip portion 2a of the discharge electrode 2 is shaped like a needle. In other words, the tip portion 2a is in the shape of a tapered wire, and serves as a discharge portion where discharge is likely to occur.

In the embodiment shown in FIG. 2, the water condensation device 4 has a Peltier device 4a. A cooling section 4b is provided for thermally connecting between the cold side of the Peltier device 4a and the discharge electrode 2. A heat radiating portion 4c is provided for thermally connecting between the hot side of the Peltier device 4a and the radiating fin 9.

The discharge device 1 has a motor fan (not shown) that generates wind to cool the heat dissipation fins 9. Wind from the motor fan is discharged from the outlet 6, which is the open end of the electromagnetic shield 7. In Fig. 2, reference numeral 20 denotes a frame having an opening and surrounds the discharge electrode 2. The frame 20 is made of an insulating material. Reference numeral 21 denotes a ring-shaped electrode disposed to face the discharge electrode 2. The ring-shaped electrode 21 is grounded. On the other hand, the frame 20 and the ring-shaped electrode 21 can be omitted.

The discharge unit 11 comprises: a cooling controller for transmitting a command for cooling or the like to the water condensation device 4; And a controller (control circuit) 10 (see FIG. 1) for controlling the high voltage supply unit 5. In the present embodiment, the cooling controller of the discharge unit 11 supplies power to the Peltier device 4a as a cooling command, thereby cooling the cooling section 4b. As a result, the discharge electrode 2 is cooled, and moisture of air condenses thereon as condensed water. Therefore, the cooling section 4b serves as a means for supplying water to the discharge electrode 2. The controller 10 of the discharge unit 11 controls the high voltage supply part 5 for applying a high voltage to the discharge electrode 2, and corresponds to the discharge electrode 2 while the condensation water adheres to the discharge electrode 2. A high electric field is created between the electrodes 21. During application of the high voltage, the condensation water adhering to the tip 2a is atomized. In particular, the condensation water is collected at the tip 2a of the discharge electrode 2, and the discharge between the discharge electrode 2 and the corresponding electrode 21 repeats Rayleigh fission of the condensation water, The condensed water becomes charged particulate water (M). After that, the charged particulate water M is blown off by the motor fan and discharged from the discharge opening 6. The controller 10 controls the amount of condensed water produced depending on the degree of cooling by the cooling section 4b. In particular, the controller 10 maintains an appropriate amount of condensed water to safely generate charged particulate water M without being affected by ambient temperature and humidity.

Charged particulate water (M) as described above includes radicals such as superoxide radicals, hydroxy radicals. Therefore, it has a deodorizing effect, a growth inhibitory effect on viruses, bacteria and fungi, an allergen inactivation effect, and the like. Therefore, when the charged particulate water M is dispersed in the room, they can deodorize the air, the wall, the sheet, and the like in the room. In addition, they can inhibit or inactivate allergens, such as mite carcasses that cling to fabric (eg, sheets, carpets, cushions, etc.), pollen entering the room from the outside, and the like.

As shown in FIG. 1, the electromagnetic shield 7 according to the embodiment has a tube case shape with an opening at its end. On the opening portion, an outlet 6 is mounted. The charged particulate water M is discharged from the outlet 6. The atomization chamber 3 containing the discharge electrode 2 is provided in the electromagnetic shield 7 on the side adjacent to the outlet 6, and the water condensing device 4 and the controller 10 are provided with the electromagnetic shield 7. It is provided behind the atomization chamber 3. The atomization chamber 3 is formed as all or part of the electrical insulation part mentioned later.

The electromagnetic shield 7 prevents the discharge electrode 2 from becoming a source of noise. In this embodiment, the electromagnetic shield 7 is an electrically conductive case, for example, made of metal. The electromagnetic shield 7 is grounded via a ground wire 8. The electrical insulator 15 is made of an insulating material such as resin. The electrical insulation 15 covers at least part of the inner surface of the electromagnetic shield 7, which surrounds the discharge electrode 2. In particular, the electrical insulation section 15 functions at least as an atomization chamber 3 surrounding the discharge electrode 2. On the other hand, the electrical insulation 15 can be formed entirely on the inner surface of the electromagnetic shield 7.

Instead of the previous configuration, the electromagnetic shield may be formed as a conductive layer (conductive film) covering the outer surface of the electrical insulator 15. In this case, the electrical insulator 15 is formed in the form of a case serving as the atomization chamber 3 and accommodating the discharge unit 11, and the conductive layer of the atomization chamber 3 is part of the electrical insulator 15. It is formed by plating a metal on the outer surface of the insulation 15 so as to surround (cover) at least the perimeter. The conductive layer is grounded through the ground wiring 8. On the other hand, the conductive layer may be formed entirely on the outer surface of the electrical insulator 15.

The discharge port 6 which communicates with the opening side of the atomization chamber 3 is comprised by the resin mold 16 which has a tube shape. The resin mold 16 prevents the charged particulate water M from sticking on the inner surface of the outlet 6. In the present embodiment, the resin mold 16 is manufactured separately from the electromagnetic shielding portion 7 and the electrical insulation portion 15 and mounted on them. The resin mold 16 may be integrally formed with the electromagnetic shield and the electrical insulator 15. When the electromagnetic shield 7 is formed of a metal case, electrical insulation is continuously processed from the inner surface of the electromagnetic shield 7 to the inner surface of the outlet 6 of the resin mold 16.

The electromagnetic shielding part 7 is grounded by the ground wiring 8, and therefore, the discharge electrode 2 can be prevented from being a source of noise emission. Even when a high voltage is applied to the discharge electrode 2 and noise is emitted therefrom, the noise is transmitted through the ground wiring 8 and grounded. Therefore, peripheral devices, computers, and the like can be prevented from malfunctioning due to noise.

In addition, an electrical insulator 15 which functions as the atomization chamber 3 is formed on the inner surface of the electromagnetic shield 7. Therefore, no discharge occurs between the discharge electrode 2 and the electromagnetic shielding portion 7, and thus it is possible to increase the generation efficiency of the charged fine particle number M. FIG.

In addition, ambient noise from the outside due to ambient static electricity and electromagnetic waves is shielded by the electromagnetic shield 7. Therefore, the discharge unit 11 accommodated in the electromagnetic shield 7 can be prevented from malfunctioning due to ambient noise.

Since the electromagnetic shielding portion 7 is configured as a case accommodating the discharge unit 11 or as a conductive layer on the case, the structure of the discharge device 1 having a function of reducing emission noise is simplified.

In this embodiment, the outlet 6 through which the charged fine particle water M is discharged is resin molded. Therefore, the inner surface of the outlet 6 serves as an electrical insulator, thus preventing the charged particulate water M from sticking to it, and increasing the discharge efficiency of the charged particulate water M. Can be.

In this embodiment, the water condensation apparatus 4 is shown as a means for supplying water to the discharge electrode 2. However, this means can be constituted by a bar-shaped transfer section which supplies water to its tip and also functions as the discharge electrode described above. In this case, the bar-shaped conveying part may have a capillary, a groove or the like which draws water from the water tank and supplies water to the tip of the bar-shaped conveying part.

Claims (3)

As a discharge device,
Discharge electrodes;
An electrical insulator including an atomization room accommodating the discharge electrode;
A water supply unit supplying water to a surface of the discharge electrode;
A high voltage supply unit for applying a high voltage to the discharge electrode in order to atomize the supplied water from the tip of the discharge electrode as charged particulate water: and
An electromagnetic shield having an opening for discharging said charged particulate water and surrounding said electrical insulator, said water supply and said high voltage supply;
Wherein said electromagnetic insulation is provided on an inner surface of said electromagnetic shield. The discharge device according to claim 1, wherein the electromagnetic shield is an electrically conductive case. The discharge device according to claim 1, wherein the electrical insulation portion is an electrically insulating case further containing the water supply portion and the high voltage supply portion, and the electromagnetic shield portion is formed as a conductive layer covering an outer surface of the electrical insulation portion.

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