KR20240087238A - Plasma lamp having an electromagnetic wave cut off equipment - Google Patents

Abstract

The present invention relates to a plasma lamp system including an electromagnetic wave shielding function.
In more detail, the high frequency generated from the magnetron for plasma discharge
Electromagnetic waves are shielded by a grid-shaped electromagnetic wave shielding filter to prevent them from being emitted to the outside.
It is about a plasma lamp system that is

Description

Plasma lamp having an electromagnetic wave cut off equipment}

The present invention relates to a plasma lamp system including an electromagnetic wave shielding function.

More specifically, it relates to a plasma lamp system in which electromagnetic waves are shielded by a grid-shaped electromagnetic wave shielding filter to prevent high frequency waves generated from a magnetron for plasma discharge from being emitted to the outside.

In general, plasma lamp systems emit electromagnetic waves.

It is a lighting device that transmits electromagnetic wave energy generated from a magnetron to a resonator through a waveguide, and when the electromagnetic wave is applied to a light bulb installed inside the resonator, the encapsulated material enclosed in the light bulb becomes plasma and emits visible light or ultraviolet light. Compared to commonly used incandescent or fluorescent lights, they have a longer lifespan and excellent lighting effects, so they are widely used for sports or industrial purposes.

This plasma lamp system generates plasma discharge by high frequency waves generated from an electromagnetic wave generator (magnetron).

The generated high frequency waves are emitted to the outside through the front opening of the housing where the light is emitted or through the discharge hole formed on one side of the housing.

In this way, a large amount of electromagnetic waves emitted to the outside can have a negative effect on the human body.

These products exceed the electromagnetic wave safety certification standards for product approval.

Serious problems that cause setbacks in product development arise.

Therefore, to overcome the irrationality of this conventional plasma lamp system,

It can be used safely by blocking electromagnetic waves unnecessarily generated by the magnetron.

There is a growing demand for plasma lamp systems.

The present invention was devised to solve the above problems,

The purpose of the present invention is to prevent electromagnetic waves emitted from the magnetron from being emitted outside the lamp housing.

The purpose is to increase safety by blocking it from happening.

Another object of the present invention is that the parts constituting the plasma lamp system are

The aim is to increase usability by compactizing it within the lamp housing.

According to one aspect of the present invention for achieving the above object,

A magnetron that generates electromagnetic waves when a source is input, a power supply module that is electrically connected to one side of the magnetron to supply power to the magnetron, and a waveguide that is connected to one side of the magnetron to transmit electromagnetic waves generated by the magnetron. , a resonator connected to one side of the waveguide, forming a resonance space therein to excite electromagnetic waves transmitted from the waveguide, and having a surface made of a mesh network, and an encapsulating material disposed inside the resonance space and undergoing plasma discharge on the inside. It includes a bulb that emits light as the encapsulating material inside is plasma discharged by electromagnetic waves guided through the waveguide, the front part is opened so that light emitted through the bulb is emitted forward, and the magnetron, waveguide, and resonator are inside. and a housing in which a storage space for storing a light bulb is formed and an exhaust hole on one side of the housing for discharging heat generated in the storage space to the outside, and surrounding the open front part of the housing.

It is provided and further includes an electromagnetic wave shielding filter that blocks electromagnetic waves emitted to the outside through the front part.

According to one aspect of the present invention for achieving the above object,

A magnetron that generates electromagnetic waves when a source is input, a power supply module that is electrically connected to one side of the magnetron and supplies power to the magnetron, and a waveguide that is connected to one side of the magnetron and transmits electromagnetic waves generated by the magnetron. , a resonator connected to one side of the waveguide, forming a resonance space therein to excite electromagnetic waves transmitted from the waveguide, and having a surface made of a mesh network, and an encapsulating material disposed inside the resonance space and undergoing plasma discharge on the inside. It includes a bulb that emits light as the encapsulating material inside is plasma discharged by electromagnetic waves guided through the waveguide, the front part is opened so that light emitted through the bulb is emitted forward, and the magnetron, waveguide, and resonator are inside. and a housing in which a storage space for storing a light bulb is formed and an exhaust hole on one side of the housing for discharging heat generated in the storage space to the outside, and surrounding the open front part of the housing.

It is provided and further includes an electromagnetic wave shielding filter that blocks electromagnetic waves emitted to the outside through the front part.

Here, the electromagnetic wave shielding filter is a metal mesh with a grid of a certain size.

is formed

In addition, the electromagnetic wave shielding filter has a certain size by silkscreening on the surface.

It may be made of a glass plate on which a grid of elements is formed.

In addition, the power supply module is disposed behind the magnetron,

An internal storage space of the housing is formed in the front-to-back longitudinal direction so that the waveguide and the resonator are arranged in a row in front of the magnetron,

Between the magnetron and the power supply module,

An electromagnetic wave blocking plate is installed to prevent electromagnetic waves generated from being emitted to the rear end of the housing to seal the internal storage space of the housing, and a heat dissipation fan is installed on the electromagnetic wave blocking plate to discharge heat emitted from the magnetron to the rear. , an exhaust hole is formed at the rear end of the housing to discharge heat passing through the heat dissipation fan to the outside, and the electromagnetic wave shielding filter is further installed in the heat dissipation fan.

Moreover, the power supply module is disposed on top of the magnetron,

An internal storage space of the housing is formed in front of the magnetron so that the waveguide and the resonator are arranged in a row, and the housing includes upper and lower covers for storing the magnetron and the power supply module inside, and the upper and lower A light projection guide coupled to the front cover to surround a reflector that is installed on the front and back of the cover and has a plurality of discharge holes on the surface, and a reflector that is formed in a hemispherical shape so that the front part is open and surrounds the outside of the resonator. It includes a cover, and the electromagnetic wave shielding filter is provided including a first shielding filter installed on the front part of the light projection guide cover, and second and third shielding filters installed on the discharge holes of the front and rear covers. .

In addition, the waveguide is located at the bottom of the magnetron in the front and rear longitudinal direction.

is formed, and an internal storage space of the housing is formed so that the resonator is installed on both sides of the waveguide, and the front and rear portions of the housing are opened so that light emitted through the bulb is emitted to the outside, and the front of the housing is , The electromagnetic wave shielding filter is coupled to the rear part.

According to the present invention as described above, the front part of the plasma lamp housing

A grid-shaped electromagnetic wave shielding filter is installed in the opening where light is emitted and the exhaust hole formed on one side of the housing to discharge internally generated heat to the outside, blocking electromagnetic waves from being emitted outside the lamp housing to ensure stable operation of the product. There are effects that can be used.

In addition, magnetrons and waveguides can be placed in various configurations inside the lamp housing.

In addition, by selecting a structure that can output light sources on both sides by placing lamps at both ends, the light source can be used efficiently according to the purpose, which has the effect of increasing usability.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the attached drawings.

will be explained in detail.

1 shows a plastic device with an electromagnetic wave shielding function according to an embodiment of the present invention.

It is a perspective view showing the plasma lamp system, Figure 2 is an exploded perspective view of the housing of the plasma lamp system including an electromagnetic wave shielding function according to an embodiment of the present invention, and Figure 3 is an exploded perspective view according to an embodiment of the present invention. It is an exploded perspective view showing in detail the internal structure of a plasma lamp system including an electromagnetic wave shielding function, and Figure 4 is a diagram showing another example of an electromagnetic wave shielding filter according to the present invention.

Referring to the drawings, the electromagnetic wave shielding function according to an embodiment of the present invention is included.

The included plasma lamp system includes a housing (70), a reflector (60), a resonator (40), a bulb (50), a waveguide (30), a magnetron (10), and an electromagnetic wave shielding filter (80) in which the parts are stored inside. It is composed.

The housing 70 has a magnetron 10, a power supply module 20, and a waveguide on the inside.

(30), a storage space is formed to store the resonator 40, the light bulb 50, etc., and the

In one embodiment, it is formed in the front-to-back longitudinal direction, the front part is open so that light emitted through the bulb 50 is emitted forward, and the rear part has an exhaust hole 71 for discharging heat generated in the storage space to the outside. This is formed.

The magnetron (10) is electrically connected to the power supply module (20) at the rear end.

Electromagnetic waves are generated by the high voltage power supplied from the power supply module 20.

The electromagnetic waves generated from this magnetron 10 correspond to a high frequency of 2.45 GHz.

The waveguide 30 is disposed in front of the magnetron 10 and is connected to the magnetron 10.

It is connected so that electromagnetic waves generated from it are transmitted.

The resonator 40 is a cylindrical metal mesh body whose surface is made of a mesh network.

Connected to one side of the waveguide 30, a resonance space is formed inside to excite electromagnetic waves transmitted from the waveguide 30, and allows light emitted from the bulb 50 to pass through and blocks the electromagnetic waves from leaking to the outside.

The bulb 50 is placed inside the resonance space and produces plasma discharge inside.

The encapsulating material is included and light is emitted as plasma is discharged inside the resonance space by electromagnetic waves guided through the waveguide 30.

The reflector 60 is formed in a hemispherical shape to surround the outside of the resonator 40.

The light passing through the resonator 40 is reflected on the surface of the reflector 60 and the light is emitted to the outside of the housing 70.

The electromagnetic wave shielding filter 80 surrounds the open front part of the housing 70.

It is combined to block electromagnetic waves emitted to the outside through the front part of the housing 70. The electromagnetic waves generated from the magnetron 10 are a high frequency of 2.45 GHz and excite the bulb 50 to emit light by plasma discharge. However, unnecessary electromagnetic waves are emitted outside the housing 70, so in the present invention, an electromagnetic wave shielding filter ( 80) to prevent electromagnetic waves from being emitted to the outside.

This electromagnetic wave shielding filter 80 has a certain regulation as shown in the drawing.

A grid of a certain size is formed using a similar metal mesh network. Here, the spacing of the grid formed in the electromagnetic wave shielding filter 80 is determined by the size of the electromagnetic wave. The electromagnetic wave used in the present invention is 2.45 GHz to 5 GHz, so a space of less than 1/4 of the wavelength is formed to block the electromagnetic wave. It is desirable that the grid spacing is less than 4.87mm in diameter.

In addition, referring to Figure 4, another embodiment of the electromagnetic wave shielding filter 80 is

Electromagnetic waves can be shielded by forming a grid with the above specifications using a silkscreen method on the surface of a heat-sensitive white glass or tempered glass plate.

This structure is developed along with the front light source irradiation of the plasma lamp system.

By acting as a secondary shielding filter for generated electromagnetic waves, a more complete electromagnetic wave shielding function is secured, resulting in the existing electromagnetic wave leakage being reduced to less than 1/3.

In addition, in one embodiment of the present invention, the internal storage space of the housing 70 is

It is formed to be long in the longitudinal direction, so that the power supply module 20 is placed inside the magnetron 10, and the waveguide 30 and the resonator 40 are arranged in a row in front of the magnetron 10. . In this way, each part is integrated in the longitudinal direction inside the housing 70, making wiring easy and manufacturing very convenient.

And between the magnetron (10) and the power supply module (20), there is a magnetron

An electromagnetic wave blocking plate 72 is installed to prevent electromagnetic waves generated in (10) from being emitted to the rear end of the housing 70 to seal the storage space inside the housing 70.

This electromagnetic wave blocking plate (72) contains the radiation emitted from the magnetron (10).

A heat dissipation fan 74 is installed to discharge heat to the rear, and an installation hole 73 is formed in the electromagnetic wave blocking plate 72 to install the heat dissipation fan 74, and is formed at the rear end of the housing 70. The internal heat is discharged to the outside through the discharge hole 71.

In addition, electromagnetic waves can be emitted to the outside through the installation hole 73, so the installation

An electromagnetic wave shielding filter 80 is installed separately in the hole 73.

Below is an electromagnetic wave shielding function according to an embodiment of the present invention.

The driving method of the plasma lamp system will be explained in detail.

First, high voltage power is supplied to the magnetron (10) through the power supply module (20).

It is input so that high frequencies are generated in the magnetron 10, and the high frequencies are transmitted to the resonator 40 through the waveguide 30.

Electromagnetic waves are excited in the resonance space of the resonator 40, and inside the resonance space

The placed bulb 50 is plasma discharged by electromagnetic waves to emit light. The light emitted in this way is reflected through the reflector 60 and shines on the front part of the housing 70, so that the light is emitted to the outside.

At this time, the electromagnetic waves emitted along with the light are first made up of a mesh network.

Electromagnetic waves are primarily blocked by the generator 40, and electromagnetic waves are secondarily blocked by the electromagnetic wave shielding filter 80 installed to surround the front part of the housing 70 to increase blocking efficiency. In this way, electromagnetic waves that are primarily blocked through the resonator 40 often have problems passing the relevant electromagnetic wave standards, so the electromagnetic waves blocked secondarily by the electromagnetic wave shielding filter 80 are at a very low level compared to the first. Prevents leakage of electromagnetic waves.

In addition, electromagnetic waves are also emitted through the discharge hole 71 formed at the rear end of the housing 70.

An electromagnetic wave shielding filter 80 is also installed on the heat dissipation fan 74 for discharging heat inside the housing 70 to the outside to completely shield electromagnetic waves from being emitted from the inside of the housing 70 to the outside.

The plasma lamp system according to an embodiment of the present invention is small and

It is formed long only in the longitudinal direction and can be placed inside a ready-made tex (30cm) installed on an indoor ceiling. In addition, as it is small and the light source is weak, a light pipe is installed in the front to make it visible from a distance.

Figure 5 shows a platform including an electromagnetic wave shielding function according to another embodiment of the present invention.

It is a perspective view showing a plasma lamp system, and Figure 6 is an exploded perspective view showing in detail the internal structure of a plasma lamp system including an electromagnetic wave shielding function according to another embodiment of the present invention.

Referring to the drawings, the electromagnetic wave shielding function according to another embodiment of the present invention

In the included plasma lamp system, unlike one embodiment, the power supply module 20 is placed in the storage space inside the housing 70 on top of the magnetron 10, and the waveguide 30 and the resonator are located in front of the magnetron 10. (40) is arranged in a row.

The housing 70 in another embodiment of the present invention includes an upper cover 70a,

70b), front and rear covers 70c, 70d installed on the front and back of the upper covers 70a, 70b, and a light projection guide cover 70e coupled to the front of the front cover.

The upper cover (70a, 70b) has the magnetron (10) and power supply module (20) inside.

It is joined at the top and bottom to be stored in, and a plurality of discharge holes 71 are formed on the surfaces of the front and rear covers 70c and 70d to allow heat generated inside to be discharged to the outside through the discharge holes 71.

In addition, the front part of the light projection guide cover 70e is open, and the front part of the resonator 40 is opened.

It is to surround the reflector 60, which is installed in a hemispherical shape to surround the outside.

In another embodiment of the present invention, the length of the housing 70 is reduced to

It is a compact structure, and the narrow internal structure allows the heat generated inside the housing 70 to be easily discharged to the outside through the discharge holes 71 formed on the front and rear covers 70c and 70d. An electromagnetic wave shielding filter 80 is installed separately to prevent electromagnetic waves from being emitted to the outside.

The electromagnetic wave shielding filter 80 in another embodiment of the present invention is a light projection

The first shielding filter 81 installed on the front of the guide cover 70e, and the second and third shielding filters 82 and 83 installed on the discharge holes 71 of the front and rear covers 70c and 70d. It is composed including. In addition, an exhaust hole 71 for heat dissipation is formed in the light projection guide cover 70e, and a fourth shielding filter 84 is installed inside the light projection guide cover 70e to prevent electromagnetic waves from being emitted through the discharge hole 71. Install it.

The front part is open so that the light emitted through the bulb is emitted forward,

A housing having a storage space formed on one side for storing the magnetron, waveguide, resonator, and light bulb, and an exhaust hole formed on one side for discharging heat generated in the storage space to the outside, and an open front of the housing. A plasma lamp system with an electromagnetic wave shielding function, further comprising an electromagnetic wave shielding filter that is coupled to surround the part and blocks electromagnetic waves emitted to the outside through the front part.

Claims (4)

A magnetron that generates electromagnetic waves when power is input,
Electrically connected to one side of the magnetron to supply power to the magnetron
A power supply module that supplies
It is connected to one side of the magnetron and emits electromagnetic waves generated from the magnetron.
A waveguide that transmits,
Connected to one side of the waveguide to excite electromagnetic waves transmitted from the waveguide
A resonator with a resonance space formed inside and a surface made of a mesh network,
It is disposed inside the resonance space, and contains an encapsulating material that is plasma discharged inside.
The encapsulating material inside is converted into plasma by electromagnetic waves guided through the waveguide.
A light bulb that emits light as it is discharged,
The front part is open so that the light emitted through the bulb is emitted forward,
A storage space is formed on the side to store the magnetron, waveguide, resonator, and light bulb.
a housing having an exhaust hole formed on one side for discharging heat generated within the storage space to the outside;
It is coupled to surround the open front part of the housing, and passes through the front part.
It is characterized by further including an electromagnetic wave shielding filter that blocks electromagnetic waves emitted to the outside.
A plasma lamp system with an electromagnetic wave shielding function. According to clause 1,
The electromagnetic wave shielding filter is characterized by forming a grid of a certain size with a metal mesh body.
Plasma lamp system with electromagnetic wave shielding function. According to clause 1,
The electromagnetic wave shielding filter has a grid of a certain size on the surface using a silk screen method.
A plasma lamp with an electromagnetic wave shielding function, characterized in that it is a formed glass plate.
system. According to any one of claims 2 or 3,
The power supply module is disposed on the upper part of the magnetron, and the magnetron
The inside of the housing such that the waveguide and the resonator are arranged in line at the front of
A storage space is formed,
The housing is
Upper and lower covers storing the magnetron and the power supply module inside,
It is installed on the front and back of the upper and lower covers, with multiple discharge holes formed on the front and rear surfaces.
The cover and the front part are open and formed in a hemispherical shape to surround the outside of the resonator.
It includes a light projection guide cover coupled to the front cover to surround the reflector,
The electromagnetic wave shielding filter is
A first shielding filter installed on the front part of the optical projection guide cover, and the front and rear covers
Electromagnetic waves, characterized in that they include second and third shielding filters installed in the discharge hole of the burr.
Plasma lamp system with shielding function.