KR20080067984A - Electronic energy saving lamp capable of shielding radiation - Google Patents

Abstract

An electronic energy saving lamp is provided to protect a user from an excessive radiation by forming an EMI shielding material layer inside the lamp. An electronic energy saving lamp includes a lamp cap(1), a lamp tube(2), an electronic ballast, a ballast mounting unit, and a housing(3). The electronic ballast is connected to the lamp cap and the lamp tube. The housing encloses the electronic ballast and the ballast mounting unit. A radioactive ray is emitted from an inner portion of the lamp to the outside. An EMI shielding material layer(5) is applied on at least one of inner components of the lamp. An ITO(Indium Tin Oxide) material is used as a shielding material.

Description

ELECTRONIC ENERGY SAVING LAMP CAPABLE OF SHIELDING RADIATION}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to electronic energy saving lamps, and more particularly, to electronic energy saving lamps capable of radiation shielding, which are arranged on a path of electromagnetic radiation that diffuses from the inside to the outside, such as the body or glass bulb of a lamp tube. On one or more components of the electronic energy saving lamp, a layer of shielding material is applied for electromagnetic radiation shielding.

It is well known that excellent energy savings, low onset voltages and long lifetimes are some of the advantages of electronic energy saving lamps that are more welcomed by consumers. However, the principle of operation of the lamp is that by converting a low frequency AC voltage source into a high frequency voltage source, harmful electromagnetic radiation is produced, at which time the lamp is activated, which is even worse, especially for high power electronic energy saving lamps. .

Preventive measures against electromagnetic radiation are currently being carried out in a variety of ways in electrical energy saving lamps and other various fields. For example, a microwave oven may be provided with a dedicated shield, the radiation screen may be arranged on a computer, and people in the related field may wear radiation resistant clothing. However, radiation of energy saving lamps, in particular high power electronic energy saving lamps, is generally ignored by the public. Yet, notable and fundamental measures have been devised to shield the human body from high frequency electromagnetic radiation, which are generated by electronic energy saving lamps and which can pose an invisible hazard to the human body.

SUMMARY OF THE INVENTION An object of the present invention is to provide an electromagnetic energy saving lamp capable of shielding radiation, thereby shielding electromagnetic radiation generated by a high power electronic energy saving lamp and causing an invisible human body. For example by applying a layer of shielding material on the body of the lamp tube, the glass bulb and / or the housing of the electronic energy saving lamp for electromagnetic radiation shielding. This technique is effective for high power electronic energy saving lamps and can eliminate potential damage to the human body caused by the electromagnetic radiation.

Technical solution for achieving the above object is achieved by a radiation shieldable electronic energy saving lamp according to the present invention, a lamp cap, a lamp tube, an electronic ballast connected to the lamp cap and the lamp tube, the lamp tube And a device for mounting the electronic ballast, and a housing surrounding the electronic ballast and the device, wherein the electronic energy saving lamp diffuses electromagnetic radiation from the inside of the lamp to the outside. On one or more of the components, a layer of shielding material for electromagnetic radiation shielding is applied.

The shielding material layer can be grounded through a conductor, which ITO (Indium tin oxide, chemical formula _{In 2 O 3 / SnO 2)} , or pure ethyl alcohol, SnCl ₄ or SnCl _2, and InCl ₃ or CdCl ₃ or SbCl it is formed of a shielding material composed of a mixture of _three preferred bar, the pure ethyl alcohol amount of 79-98wt%, SnCl ₄ or SnCl ₂ amount 1.2-18.1wt%, and InCl ₃ or CdCl ₃ or SbCl ₃ amount 0.1-4.5wt% to be. The thickness of the shielding material layer is generally 0.1-10 μm.

In the electronic energy saving lamp as described above, the shielding material layer is applied on the lamp tube, and the shielding material layer on the lamp tube is applied on the inner wall or the outer wall of the lamp tube.

According to the invention, the shielding material layer is applied to the inside of the housing; Optionally, it may be applied to the inside of the housing and to the lamp tube.

In a preferred embodiment of the invention, the shielding material layer applied inside the housing is a metal shield, which consists of a metal or alloy with good conductivity, such as copper, aluminum or an aluminum alloy, It is firmly attached and is connected via a conductor to the rectified negative terminal of the electronic ballast of the electronic energy saving lamp.

In another preferred embodiment of the present invention, the shielding material layer is applied on the glass bulb surrounding the lamp tube and mounted to the bottom of the housing, and the shielding material layer is applied to the inner wall or the outer wall of the glass bulb. Can be.

Likewise, the shielding material layer may be applied to the inside of the housing and the glass bulb. The shielding material layer applied on the housing is a metal shield, which consists of a metal or alloy with good conductivity, such as copper, aluminum or an aluminum alloy, which is firmly attached to the inside of the housing and through the conductor the electron energy. The saving lamp is connected to the rectified negative terminal of the electronic ballast.

The shielding material layer applied on the lamp tube and the glass bulb is uniformly covered and has a high light transmittance such that light passing through the shielding material layer is not affected by it.

In summary, a radiation shieldable electronic energy saving lamp according to the invention comprises one or more components of the electronic energy saving lamp (especially the lamp tube, glass bulb and the like) in which electromagnetic radiation is diffused from the interior of the lamp to the outside. A shielding material layer for electromagnetic radiation shielding is applied on the housing, and the shielding material layer effectively prevents electromagnetic radiation from harming the human body by effectively shielding electromagnetic radiation spreading from the inside of the lamp to the outside. . Also, the shielding material layers are applied on the lamp tube and glass bulb of the present invention, pure ethyl alcohol, SnCl ₄ or SnCl _2, and InCl ₃ or CdCl ₃ or indium tin water or colorless and transparent liquid oxide is mixed with SbCl ₃ It may consist of a mixture. The lighting efficiency of the electronic energy saving lamp is not affected by controlling the thickness of the shielding material layer having good conductivity, and the shielding material layer is grounded through a ground conductor so that the electromagnetic radiation can be further reduced. It is possible to ground the induction current generated during operation of the lamp, to promote the increase of the operational stability of the electronic energy saving lamp, and to optimize the environment in which humans work and live. In the present invention, the shielding material layer applied inside the housing of the electronic energy saving lamp may be optionally replaced with a metal shield formed of a conductive material, the shield being rectified of the electronic ballast of the electronic energy saving lamp. The connection to the negative terminal allows the shielding of electromagnetic radiation generated by the ballast to be made in a more reliable manner.

The shielding material layer of the present invention is simple in structure, easy to manufacture, low in cost, and high in effect. This can be widely applied in various electronic energy saving lamps to reduce the damage to the health of the user caused by the electromagnetic radiation generated therefrom.

1 to 3, each of the radially shieldable electronic energy saving lamps of the present invention is shown. It basically comprises a lamp cap 1, a lamp tube 2, an electronic ballast (not shown), a device (not shown), and a housing 3. The electronic ballast is connected respectively with the conductive contacts of the lamp cap 1 having an input end and the fixing portions of the lamp tube 2 with an output end, the device being connected to the lamp tube 2. And for mounting the electronic ballast, the housing 3 is mounted at the bottom end of the lamp cap 1 by surrounding the electronic ballast and the device. Although the structure of the lamp is not essential to the present invention, it will not be described herein, and details thereof may be related to a conventional electronic energy saving lamp. As can be seen from FIGS. 1 to 3, a layer of shielding material for electromagnetic radiation shielding is applied on one or more components of the electronic energy saving lamp in which electromagnetic radiation diffuses from the inside of the lamp to the outside.

The preferred shielding material used in the present invention is indium tin oxide (ITO), which has better electromagnetic radiation shielding ability and will not affect the luminous flux of the lamp. Optionally, the shielding material layer comprises three materials: 1. pure ethyl alcohol; 2. SnCl ₄ or SnCl ₂ ; 3. InCl ₃ or CdCl ₃ or may be formed of a mixture of SbCl _3, wherein the amount of 79-98wt% pure ethyl alcohol, SnCl ₄ or SnCl ₂ amount 1.2-18.1wt%, and InCl ₃ or CdCl ₃ or SbCl ₃ amount 0.1-4.5 wt%. In the latter case, the shielding material layer of the present invention preferably consists of a mixture of 88-92 wt% pure ethyl alcohol, 5-10 wt% SnCl ₄ , and 2-3 wt% InCl ₃ . For example, such a shielding material may consist of 1 L of pure ethyl alcohol, 90 g of SnCl ₄ , and 26 g of InCl ₃ , which have a high light transmittance as a colorless transparent liquid, whereby light beams effectively diffuse through the shielding material. Therefore, the lighting efficiency of the electronic energy saving lamp coated with the shielding material will not be basically affected. The thickness of the shielding material layer is preferably 0.1-10 μm to ensure that adequate shielding of electromagnetic radiation and the luminous flux of the electronic energy saving lamp applied with the shielding material are almost unaffected. In addition, the above-described shielding material is a conductive material, the ground current is grounded to the conductor through the induced current generated during the operation of the electronic energy saving lamp can be introduced into the ground.

In order to apply or apply the shielding material onto the desired portion of the electronic energy saving lamp, conventional technical means in the art may be employed, which will not be fully described herein.

In FIG. 1, the lamp tube 2 of the electronic energy saving lamp is applied with the above-mentioned layer of shielding material 5, which is applied to shield electromagnetic radiation diffused from the lamp tube 2. According to the invention, the shielding material layer 5 can be selectively applied on the inner wall or the outer wall of the lamp tube 2. The shielding material layer 5 applied on the lamp tube 2 may be evenly spread so that the light of the electronic energy saving lamp is uniformly spread through the shielding material layer.

In the electronic energy saving lamp as shown in FIG. 2, a shielding material layer 5 ′ is applied to the inside of the housing 3 for shielding electromagnetic radiation generated by the electronic ballast. Preferably, as shown in FIG. 3, the shielding material layers 5, 5 ′ are applied together inside the housing 3 and on the lamp tube 2 of the electronic energy saving lamp, thereby providing the electromagnetic radiation. Enables effective shielding and prevention of human body damage caused by electromagnetic waves. 3, the shielding material layer applied on the housing 3 is shielded applied on the lamp tube 2 in that the metal shield 5'-1 is made of a metal or alloy having good conductivity. It is different from the material layer. In this embodiment, the metal shield is made of copper. In order to achieve a better shielding effect, the metal shield is designed to be formed almost in the same shape as the metal shield of the housing. Thus, it can be firmly attached on the inside of the housing 3 and can be connected via a conductor to the rectified negative terminal of the electronic ballast of the electronic energy saving lamp, the electromagnetic radiation generated by the electronic ballast being It can be effectively shielded, and the induced current generated during the operation of the electronic energy saving lamp can also flow into the ground.

Referring to FIGS. 4 and 5 where other electronic energy saving lamps are shown, this includes the glass bulb 4 as well as all components as shown in the foregoing embodiments. The glass bulb 4 is a spherical portion which is mounted to the bottom end of the housing 3 in such a way that the lamp tube 2 is surrounded by it.

The embodiment shown in FIG. 4 differs from the embodiment shown in FIG. 1 in that a layer of shielding material for electromagnetic radiation shielding is applied on the glass bulb 4 rather than the lamp tube 2. Likewise, the shielding material layer 5 may be applied to the outer wall as well as the inner wall of the glass bulb 4. The shielding material layer applied on the glass bulb 4 may be evenly spread so that the light of the electronic energy saving lamp is uniformly spread through the shielding material layer. Preferably, shielding material layers 5, 5 ′ are applied on the inside of the housing 3 and the glass bulb 4 so that the electromagnetic radiation can be shielded in a more reliable manner.

The layer of shielding material applied on the glass bulb 4 is the same as the layer of shielding material applied on the lamp tube 2. Suitable materials are indium tin oxide; Alternatively, it may be colorless transparent liquid formed from a mixture of pure ethyl alcohol, SnCl ₄ or SnCl _2, and InCl ₃ or CdCl ₃ or SbCl _3. The shielding material layer is colorless and transparent and has a high light transmittance so that it does not affect the light transmittance of the glass bulb 4 of the electronic energy saving lamp. Since the shielding material layer 5 is a conductive material, it can be grounded through the grounding conductor.

With regard to the electronic energy saving lamp with a glass bulb, the shielding material layer 5 is enclosed by the glass bulb 4, as can be seen from the one shown in FIG. 5. It can also be applied on the inner and outer walls of the. In the electronic energy saving lamp as shown in FIG. 5, a metal shield 5'-1 is further provided on the inner side of the housing 3, but as shown in FIG. 3, the metal shield is made of copper. , Metal or alloy having good conductivity, such as aluminum or aluminum alloy, which is firmly attached on the inside of the housing 3 and connected via a conductor to the rectified cathode terminal of the electronic ballast of the electronic energy saving lamp. do. The glass bulb 4 when the shielding material layer 5 applied on the lamp tube 2 of the present embodiment is sufficient to shield the electromagnetic radiation, and it can serve as a protective means for the lamp tube 2. It can be seen that no layer of shielding material needs to be applied on).

Obviously, a layer of shielding material of the invention capable of radiation shielding may be applied on the inside of the housing 3 and on the lamp tube 2 or on the inside of the glass bulb 4 and the housing 3, or a combination thereof. Can be. In this way, the invisible hazards caused by the electronic energy saving lamps, in particular high power and high frequency electromagnetic radiation, can be effectively shielded or eliminated, which is beneficial to human health.

The shielding material layer of the present invention is simple in structure, easy to manufacture, low in cost, and high in effect. This can be widely applied in various electronic energy saving lamps to reduce the damage to the health of the user caused by the electromagnetic radiation generated therefrom.

In summary, the foregoing description relates only to some preferred embodiments of the present invention. Logical analysis, reasoning, or limited experimentation based on the prior art in connection with the guidance of the present invention can be seen that all technical solutions achieved by those skilled in the art will be included within the scope of the claims of the present invention. will be.

1 is a partial perspective view of an electronic energy saving lamp capable of radiation shielding, wherein a layer of shielding material is applied on the lamp tube.

2 is a partial perspective view of an electronic energy saving lamp capable of radiation shielding, wherein a layer of shielding material is applied on the housing.

3 is a partial perspective view of an electronic energy saving lamp capable of radiation shielding, showing that a layer of shielding material is applied on the lamp tube and the housing, wherein the layer of shielding material applied on the housing is a metal shield.

4 is a partial perspective view of an electronic energy saving lamp capable of radiation shielding, wherein a layer of dentifrice material is applied onto a glass bulb.

FIG. 5 is a partial perspective view of an electronic energy saving lamp capable of radiation shielding, showing that a layer of shielding material is applied on the lamp tube and the housing inside the glass bulb, wherein the layer of shielding material applied on the housing is a metal shield.

Claims (18)

Electronic edging savings comprising a lamp cap, a lamp tube, an electronic ballast connected to the lamp cap and the lamp tube, a device for mounting the lamp tube and the electronic ballast, and a housing surrounding the electronic ballast and the device A lamp according to claim 1, wherein a layer of shielding material for electromagnetic radiation shielding is applied on one or more components of the electromagnetic energy saving lamp from which electromagnetic radiation is emitted from the inside of the lamp to the outside. The method of claim 1, Electronic energy saving lamp, characterized in that indium tin oxide is used as the shielding material. The method of claim 1, The shielding material forming the shielding layer of pure ethyl alcohol, SnCl ₄ or SnCl _2, and InCl ₃ or CdCl ₃ or electronic energy saving lamp comprising the SbCl _3. The method of claim 3, wherein The shielding material of pure ethyl alcohol 79-98wt%, SnCl ₄ or SnCl ₂ 1.2-18.1wt%, and InCl ₃ or CdCl ₃ or electronic energy saving lamp comprising the SbCl ₃ 0.1-4.5wt%. The method of claim 4, wherein The shielding material is 88-92wt% pure ethyl alcohol, 5-10wt% SnCl ₄ , and 2-3wt% InCl ₃ electronic energy saving lamp. The method according to any one of claims 2 to 5, And the thickness of the shielding material layer is 0.1-10 μm. The method of claim 1, The shielding material layer is applied on the lamp tube. The method of claim 7, wherein The shielding material layer is applied on an inner wall or an outer wall of the lamp tube. The method of claim 1, And the shielding material layer is applied to the inside of the housing. The method of claim 1, And the shielding material layer is applied inside the housing and on the lamp tube. The method according to claim 9 or 10, The shielding material layer applied to the inside of the housing is a metal shield, which is made of a metal or alloy having good conductivity, and is in contact with the inside of the housing and is rectified cathode of the electronic ballast of the electronic energy saving lamp through a conductor. Electronic energy saving lamp, characterized in that connected to the terminal. The method of claim 11, And said metal is copper or aluminum and said alloy is an aluminum alloy. The method of claim 1, And the shielding material layer is applied on a glass bulb surrounding the lamp tube and mounted to the bottom of the housing. The method of claim 13, The shielding material layer is applied to an inner wall or an outer wall of the glass bulb. The method of claim 13, And the shielding material layer is further applied inside the housing. The method of claim 15, The shielding material layer applied on the housing is a metal shield, which is made of a metal or alloy with good conductivity, which is firmly attached to the inside of the housing and rectified of the electronic ballast of the electronic energy saving lamp through a conductor. An electronic energy saving lamp, characterized in that connected to the negative terminal. The method of claim 15, And said metal is copper or aluminum and said alloy is an aluminum alloy. The method according to claim 7 or 13, And the shielding material layer applied on the lamp tube and the glass bulb is uniformly covered and has a high light transmittance.

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