KR101101814B1 - Ion generating apparatus - Google Patents

Abstract

The present invention relates to an ion generating device having a substrate and a casing for receiving the substrate and having an upper opening, comprising: a plate-shaped positive electrode portion for generating cations; And a cover having a sliding guide for blocking the upper opening and guiding sliding insertion along the plate direction of the positive electrode part. Accordingly, the sliding and coupling of the positive electrode part having brittle nature covers the contamination, scratches or cracks on the surface, and the negative electrode part is prevented from being deformed from scratches or shapes from external impacts, thereby preventing deterioration in ion generation performance. It is possible to prevent the ion generator from malfunctioning or shortening the service life.

Description

Ion Generator {ION GENERATING APPARATUS}

1 is an exploded perspective view of the ion generating device according to the present invention,

2 is a perspective view of a casing according to the present invention,

3 is a perspective view of a cover according to a first embodiment of the present invention;

4 is a side view of the cover shown in FIG.

5 is a perspective view of the coupling and operation of the ion generating device according to the present invention,

6 is a perspective view of the cover and the positive electrode unit according to the second embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: ion generator 10: casing

12: upper opening 14: release stopper

20: substrate 30: positive electrode portion

40: negative electrode portion 50: cover

52: opening 53: sliding guide

54: insertion stopper

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ion generating device, and more particularly, to an ion generating device having an improved coupling structure between a positive electrode unit and a negative electrode unit coupled to a casing and a cover.

The ion generating device is a device that causes a partial discharge by applying a high voltage of several kv to several thousand kv to the positive electrode portion and the negative electrode portion. Here, the ion generating device is generally used to be mounted on an electronic device such as an air cleaner or an air conditioner. For example, an air cleaner cleans the indoor space by blowing positive and negative ions generated from an ion generator installed therein together with air, and an air conditioner having an ion generator installed cold air in the indoor space. When blowing, the positive and negative ions are blown together to cool the indoor space while cooling.

Such an ion generating device includes a casing having an upper opening through which a substrate is inserted and forming an exterior of the ion generating device, a cover covering the upper opening of the casing, a positive electrode portion coupled to the plate surface of the cover by a hook coupling method, and a substrate. It is coupled to include a needle-like negative electrode portion protruding in the transverse direction with respect to the plate surface of the cover.

However, the positive electrode portion coupled to the plate surface of the ion generating device cover by a hook coupling method is made of a ceramic material, which causes scratches or cracks when the hook is coupled, thereby reducing productivity or lowering the performance of the positive electrode portion, thereby causing malfunction or service life. There is a problem that can cause a shortening. In other words, when the positive electrode portion of the weak brittle ceramic material is coupled by the hook coupling method, cracking occurs due to the pressing of the hook, thereby reducing productivity. In addition, the needle-like negative electrode portion coupled in the transverse direction with respect to the plate surface of the cover is damaged or deformed on the surface of the negative electrode portion protruding during assembly or movement of the ion generating device, there is a problem that performance may occur. .

Accordingly, an object of the present invention is to provide an ion generating device having an improved coupling structure of a positive electrode part and a negative electrode part which can prevent scratches, cracks, and shape deformation of the positive electrode part and the negative electrode part.

An ion generating device disclosed to achieve the above object is a substrate; A casing for accommodating the substrate and having an upper opening formed therein; A plate-shaped positive electrode portion generating cations; Blocking the upper opening, the cover is provided with a sliding guide along the plate direction, the positive electrode portion is achieved by sliding insertion is installed in the sliding guide.

Here, the cover may further include an insertion stopper protruding from the plate surface to limit the sliding insertion movement of the positive electrode portion.

The casing may include a release stopper for restricting movement of the positive electrode portion in a direction opposite to the sliding insertion direction.

The positive electrode portion is characterized in that the ceramic material.

The cover is provided with an opening portion through which the positive electrode portion coupled to the sliding guide is exposed, so that cations generated in the positive electrode portion can be discharged to the outside of the cover through the opening portion.

Further comprising a negative electrode portion coupled to the substrate and generating a negative ion, the cover is formed in a transverse direction with respect to the plate surface of the cover further includes a receiving portion for receiving the negative electrode portion when the casing and the cover is coupled can do.

The negative electrode portion is characterized in that the needle.

Hereinafter, with reference to the accompanying drawings will be described in detail for the ion generating device. Prior to the description, it will be appreciated that the ion generating device of the present invention can be applied to all electronic devices for generating ions, such as air cleaners, air conditioners, and refrigerators.

1 and 2, the ion generating device 1 according to the present invention includes a casing 10, a substrate 20 accommodated in the casing 10, and a positive electrode portion connected to the substrate 20. 30 and a negative electrode portion 40, and a cover 50 for covering the upper portion of the casing (10).

The casing 10 includes a casing body 11 forming an outer appearance of the ion generating device 1 and a hook 13 provided on a wall surface of the casing body 11 and hooked with a cover 50 to be described later. Here, three hooks 13 formed on the wall surface of the casing 10 are formed as one example of the present invention, but may be formed more than three to increase the bonding force. The casing 10 is formed with an upper opening 12 into which the substrate 20 is inserted. In addition, an accommodation space in which the substrate 20 is accommodated is formed in the casing 10.

On the other hand, the casing 10 has a breakaway stopper 14 protruding from the wall surface of the casing body 11 to restrict the movement of the positive electrode portion 30 coupled to the cover 50 to be described later in the opposite direction of the sliding insertion direction. do. Detailed description of the release stopper 14 will be described together in the configuration related to the cover 50 to be described later. The casing 10 is provided with a coupling portion 15 to be coupled to the receiving portion 55 for receiving the negative electrode portion 40 to be described later. In this case, the coupling part 15 is provided with a negative electrode opening part 16 so as to release the negative ions generated from the negative electrode part 40.

The substrate 20 is connected to the positive electrode portion 30 and the negative electrode portion 40. The substrate 20 is connected to the positive electrode portion 30 by a cable 60, and is directly connected to the plate surface of the substrate 20 directly on the negative electrode portion 40. The substrate 20 is provided with a high voltage circuit (not shown) for applying several kv to several thousand kv to generate positive and negative ions in the positive electrode unit 30 and the negative electrode unit 40.

이온을 발생한다.The positive electrode part 30 is manufactured in a plate shape. The positive electrode unit 30 is made of a ceramic material to generate cations. The positive electrode part 30 is exposed to air so that positive ions can be moved from the ion generating device 1 to the outside. That is, the positive electrode part 30 is an example of the present invention, and is exposed to air by the opening part 52 to be described later. Here, the positive electrode unit 30

Generates ions.

를

로 대전시킨다.The negative electrode portion 40 is spaced apart from the positive electrode portion 30 and connected in a horizontal direction with respect to the plate surface of the substrate 20. The negative electrode portion 40 is made of a needle. Here, the negative electrode portion 40 is in the air

To

Charge with.

이온과 음전극부(40)에서 발생된 전자(e)가 결합하여 활성수소 H가 생성된다. 즉, 양전극부(30)와 음전극부(40)에 의해서 활성수소 H와 산소 이온

가 발생되는 것이다.On the other hand, generated from the above-described positive electrode portion 30

The active hydrogen H is generated by combining the ions and electrons e generated in the negative electrode part 40. That is, active hydrogen H and oxygen ions are formed by the positive electrode portion 30 and the negative electrode portion 40.

Will be generated.

3 and 4, the cover 50 according to the first embodiment of the present invention is formed on the cover body 51 and the plate surface of the cover body 51 to form the appearance of the cover 50 Sliding insertion movement of the open portion 52, the sliding guide 53 for guiding sliding insertion along the plate surface direction of the positive electrode portion 30, and the positive electrode portion 30 are exposed It includes an insertion stopper 54 for limiting the, a receiving portion 55 for receiving the negative electrode portion 40, and a hook coupling portion 56 for engaging the hook 13 formed in the casing (10). Here, the cover 50 covers the upper opening 12 of the casing 10 described above to prevent breakage of the substrate 20 accommodated in the casing 10.

As described above, the cover body 51 has an open portion 52 through which the positive electrode portion 30 is exposed. The cover body 51 is manufactured in a plate shape and manufactured to a size that can cover the region of the upper opening 12 of the casing 10.

The sliding guide 53 is a first embodiment of the present invention, protrudes from the cover body 51 toward the casing 10 in the transverse direction with respect to the plate surface of the cover body 51, the end of the cover body 51 It is bent in the plate direction. Sliding guide 53 is provided in a pair on the outer side of the opening 52 in the sliding direction along the plate surface direction of the positive electrode portion 30 on the outer side. Here, the sliding guide 53 will be described with reference to FIG. 4, and the sliding guide 53 will be bent on both sides of the opening portion 52 in the slide insertion direction of the positive electrode portion 30.

The insertion stopper 54 protrudes from the cover body 51 toward the casing 10 to the plate surface of the cover body 51 to limit the sliding insertion movement of the positive electrode part 30. That is, the insertion stopper 54 restricts the movement of the positive electrode unit 30 so that the sliding inserted positive electrode unit 30 may be located in the opening 52. On the other hand, the above-mentioned release stopper 14 is disposed opposite the insertion stopper 54. Here, the breakaway stopper 14 is provided in the casing 10 because it interferes with the sliding insertion of the positive electrode portion 30 when protruding from the cover body 51. When the casing 10 and the positive electrode unit 30 are coupled to the cover 50, the release stopper 14 restricts the positive electrode unit 30 from moving in the direction opposite to the sliding insertion direction.

The accommodating part 55 accommodates the negative electrode part 40 which protrudes through the plate surface of the cover 50. The receiving part 55 is formed with an opening so that electrons (e) emitted from the negative electrode part 40 can be discharged to the outside. Receiving portion 55 is coupled to the engaging portion 15 of the casing (10).

The hook coupling portion 56 is provided to engage with the hook 13 of the casing 10 described above. The hook coupling portion 56 protrudes from the plate surface of the cover 50 in the transverse direction toward the casing 10. Hook coupling portion 56 is an example of the present invention, three are provided so as to correspond to the three hooks (13). However, as an embodiment of the present invention, the hook 13 is provided in the casing 10 and the hook coupling portion 56 is provided in the cover 50, the hook coupling portion 56 is provided in the casing 10 And a hook 13 may be provided in the cover 50.

Hereinafter, an assembly process and an operation process of the ion generating device 1 according to the first embodiment of the present invention will be described as follows.

First, the substrate 20 connected to the positive electrode part 30 and the cable 60 through the upper opening 12 of the casing 10 and in contact with the negative electrode part 40 is inserted. The positive electrode part 30 is inserted by sliding using the sliding guide 53 of the cover 50. At this time, the positive electrode portion 30 is stopped by the insertion stopper 54, the sliding movement is stopped.

The cover 50 is coupled to the upper opening 12 of the casing 10. The hook 13 provided on the casing 10 and the hook coupling portion 56 provided on the cover 50 are engaged with each other. Here, the departure stopper 14 restricts the movement of the positive electrode unit 30 in the casing 10. In addition, the negative electrode portion 40 is accommodated in the receiving portion of the cover 50.

이온을 발생하고, 음전극부(40)에서 전자(e)를 방출하여 공기 중의

를

로 대전시킨다. 여기서, 양전극부(30)에서 발생된

이온과 음전극부(40)에서 방출한 전자(e)가 결합하여 활성수소 H를 생성한다. 이에, 이온발생장치(1)로부터 발생된 이온은 중성의 활성수소 H와 산소 이온

이 된다.On the other hand, the ion generator 1 is applied to the positive electrode portion 30 and the negative electrode portion 40 in the high voltage circuit provided on the substrate 20 in the positive electrode portion 30

Generates ions, emits electrons (e) from the negative electrode portion 40,

To

Charge with. Here, the positive electrode portion 30 generated

The ions and the electrons (e) emitted from the negative electrode unit 40 combine to form active hydrogen H. Thus, the ions generated from the ion generator 1 are neutral active hydrogen H and oxygen ions

Becomes

은 공기 중으로 방출되면 세균이나 바이러스와 접촉하게 된다. 공기 중에 방출된 활성수소 H와 산소 이온

은 세균이나 바이러스를 구성하는 세포막 단백질을 공격하게 된다. 이온발생장치(1)에서 발생된 활성수소 H와 산소 이온

이 세균이나 바이러스의 세포막에 도달하면 세포막 단백질과의 화학반응에 의하여 활성산소

로 변화한다. 여기서, 반응성이 강하여 불안정한 상태인 활성산소

는 세균이나 바이러스 표면의 (+) 정전기와, 세포막 단백질 구성물질 중 3개의 수소원자(H)를 빼앗아 중성인

분자로 변화하고 정전기와 수소원자를 빼앗긴 세포막 단백질은 자연스럽게 파괴된다. 즉, 화학반응 후 생성물질은

뿐이므로 반응 후에도 공기 중에 유해물질을 남기지 않는다.Active hydrogen H and oxygen ions generated in the ion generator 1

When released into the air, they come into contact with bacteria or viruses. Activated hydrogen H and oxygen ions released into the air

Attacks the membrane proteins that make up bacteria and viruses. Active hydrogen H and oxygen ions generated in the ion generator 1

When it reaches the cell membrane of this bacterium or virus, free radicals are formed by chemical reaction with cell membrane proteins.

To change. Here, active oxygen which is unstable due to strong reactivity

(+) Static on the surface of bacteria and viruses, and neutralizes the three hydrogen atoms (H) of the membrane protein components

Membrane proteins that have been transformed into molecules and deprived of static electricity and hydrogen atoms are naturally destroyed. In other words, the product after the chemical reaction

It does not leave any harmful substances in the air even after the reaction.

Thus, by inserting and sliding the positive electrode portion having brittle properties to prevent contamination, scratches or cracks on the surface, and cover the negative electrode portion to prevent the scratch or shape from deformation from external impact, thereby reducing the ion generating performance of the electrode portion It can prevent the malfunction and shorten the service life of the ion generator.

Meanwhile, in the above-described embodiment, a sliding guide for guiding the sliding movement of the positive electrode portion is provided on the rear surface of the cover body. As a second embodiment of the present invention, as shown in FIG. 6, the positive electrode portion is disposed on the front plate of the cover body. A sliding guide may be formed and a sliding guide may be formed around the accommodation space to guide sliding insertion of the positive electrode part.

As described above, according to the present invention, by sliding-inserting the positive electrode portion having brittle nature to cover the surface of contamination, scratches or cracks and the negative electrode portion to prevent scratches or shapes from deformation from external impact, There is provided an ion generating device which can prevent deterioration of ion generating performance and prevent malfunction or shorten the service life of the ion generating device.

Claims (7)

A substrate; A casing for accommodating the substrate and having an upper opening formed therein; A plate-shaped positive electrode portion generating cations; Blocking the upper opening, comprising a cover provided with a sliding guide along the plate surface direction, The positive electrode unit is characterized in that the sliding insert is installed in the sliding guide. The method of claim 1, The cover further comprises an insertion stopper protruding from the plate surface to limit the sliding insertion movement of the positive electrode portion. 3. The method of claim 2, The casing comprises an escape stopper for limiting the movement of the positive electrode portion in the direction opposite to the sliding insertion direction. The method according to any one of claims 1 to 3, The positive electrode unit is an ion generating device, characterized in that the ceramic material. The method according to any one of claims 1 to 3, The cover is formed with an open portion for exposing the positive electrode portion coupled to the sliding guide, the ion generating device characterized in that the cations generated in the positive electrode portion can be discharged to the outside of the cover through the opening. The method according to any one of claims 1 to 3, It further comprises a negative electrode portion coupled to the substrate for generating a negative (-) ion, The cover is formed in a transverse direction with respect to the plate surface of the cover ion generating device further comprising a receiving portion for receiving the negative electrode portion when the casing and the cover is coupled. The method of claim 6, The negative electrode unit is an ion generating device characterized in that the needle.

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