JP2001200249A - Oxidation-resistant phosphor and production method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an oxidation-resistant phosphor of which the luminance is not degraded by oxidation without changing the conventional baking step and a production method therefor. SOLUTION: This phosphor comprises particles of which the surface is covered with a layer of magnesium fluoride or calcium fluoride.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oxidation-resistant phosphor which hardly deteriorates, for example, a decrease in luminance due to oxidation, and a method for producing the same.

[0002]

2. Description of the Related Art Conventionally, when a fluorescent lamp is manufactured using a phosphor, the phosphor is slurried, applied to a substrate such as a glass tube, and then baked to form a predetermined phosphor film. Have got a lamp to have.

[0003] The temperature at the time of baking must be sufficient to thermally decompose and remove the binder and the like added to strengthen the phosphor film. For this reason,
When the phosphor is heated at the same time, the phosphor may be oxidized and the luminance may be reduced. For example, in the baking in the current fluorescent lamp manufacturing process, the coated glass tube having the fluorescent material applied to the inner wall is heated to a high temperature of 600 ° C. or more, and most of the fluorescent material has luminance due to oxidation caused by this process. Cause a decline.

[0004] As a countermeasure, it has been studied to suppress a decrease in luminance due to oxidation of a phosphor by performing a baking step in a weak reducing atmosphere.

However, thermal decomposition of the binder may be insufficient due to insufficient oxidation, and it is very difficult to control the atmosphere.

[0006] In some fluorescent lamps, some of the phosphors to be used may include phosphors whose brightness is reduced by setting the atmosphere to a weak reducing atmosphere. The method is not generally available.

Further, there is a method of lowering the baking temperature in order to prevent the phosphor from being oxidized. However, in this case, too, the decomposition and removal of the binder due to the insufficient temperature are apt to be insufficient, and the phosphor film is firmly formed. Can not be.

Therefore, development of a phosphor having high oxidation resistance has been desired. Therefore, a phosphor coated with silicon oxide has been proposed as having enhanced oxidation resistance of the phosphor, and it has been shown in powder evaluation that the phosphor has an effect of suppressing a decrease in luminance due to oxidation. (JP-A-60-115683
No.).

[0009]

However, a lamp using a phosphor coated with silicon oxide has a remarkable decrease in luminous flux when used for a long period of time, because the phosphor coated with silicon oxide has a negative effect. It has been pointed out that the difference in charging tendency with mercury oxide increases due to charging, and that more mercury oxide is adsorbed than ordinary phosphors, resulting in large deterioration of luminous flux and the like (J . Illum. En
gst. Inst. Jpn. Vol. 76 No. 10 1992).

[0010] The present invention has been made in view of such circumstances, and without changing the conventional baking process.
An object of the present invention is to provide an oxidation-resistant phosphor capable of suppressing a decrease in luminance due to oxidation of the phosphor and a method for producing the same.

[0011]

The oxidation-resistant phosphor according to the first aspect of the present invention has phosphor particles whose surfaces are coated with a magnesium fluoride layer.

The oxidation-resistant phosphor according to the second aspect of the present invention is one in which the surface of the phosphor particles is covered with a calcium fluoride layer.

[0013] The oxidation-resistant phosphor according to the third aspect of the present invention is obtained by forming a magnesium fluoride film layer on the surface of the phosphor using magnesium chloride and ammonium fluoride.

The oxidation-resistant phosphor according to the fourth aspect of the present invention is obtained by forming a calcium fluoride coating layer on the phosphor surface using calcium chloride and ammonium fluoride.

According to a fifth aspect of the present invention, there is provided a method for manufacturing an oxidation-resistant phosphor, comprising adding ammonium fluoride to a suspension mixture of phosphor particles and magnesium chloride to form a fluorophore on the surface of the phosphor particles. This is a method in which magnesium fluoride is deposited and adhered, and is then dehydrated and dried to form a magnesium fluoride film layer.

According to a sixth aspect of the present invention, there is provided a method for producing an oxidation-resistant phosphor, comprising adding ammonium fluoride to a suspension mixture of phosphor particles and calcium chloride, and adding a fluoride to the surface of the phosphor particles. This is a method in which calcium fluoride is deposited and adhered, dehydrated and dried to form a calcium fluoride film layer.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the present invention, the surfaces of phosphor particles are coated with a magnesium fluoride layer or a calcium fluoride layer. Specifically, a magnesium fluoride layer is formed using magnesium chloride and ammonium fluoride. Also, a calcium fluoride film layer is formed using calcium chloride and ammonium fluoride. For this reason, a decrease in luminance due to oxidation of the phosphor can be suppressed.

That is, in the present invention, the substance for coating the phosphor
As magnesium fluoride or calcium fluoride
Selected. This is when the phosphor is coated
Do not reduce the light characteristics and luminous efficiency, specifically fluorescence
Ultraviolet light source for body excitation (for lamps; 254, 365)
problem with transmission of 147 nm and 173 nm for PDPs
Was chosen because there is no. Magnesium oxide (Mg
O) Aluminum oxide (Al) ₂O₃) ・ Silicon oxide (SiO
₂) Indicates the wavelength of the ultraviolet light used as the excitation source, as described above.
The wavelength range of the ultraviolet light did not match, and it was rejected. still,
Silicon oxide has low luminous flux when used for a long time.
The fact that the bottom is remarkable is as described above.

Further, in view of simplification of the process of coating the phosphor and ease of handling when the coated phosphor is actually used (coated), the substance forming the coating layer of the present invention is water. Those that were insoluble or had the lowest solubility were selected. Aluminum fluoride (AlF ₃ ), lithium fluoride (LiF), barium fluoride (BaF ₂ ) and the like have been rejected because of their high solubility in water.

As a result, as a substance covering the phosphor,
The present invention has been accomplished by selecting magnesium fluoride or calcium fluoride having the above-mentioned wavelength of the ultraviolet ray serving as the excitation source and the wavelength range of the ultraviolet ray which can be transmitted, and having low solubility in water. Note that the magnesium fluoride layer or the calcium fluoride layer was found to have an effect of suppressing a decrease in luminance due to oxidation of the phosphor.

The phosphor used in the present invention may be any one that can be coated with a magnesium fluoride layer or a calcium fluoride layer. Is remarkable.

As a method for producing the oxidation-resistant phosphor, a magnesium fluoride film layer or a calcium fluoride layer is formed on the phosphor surface using magnesium chloride and ammonium fluoride or calcium chloride and ammonium fluoride. Is the way.

More specifically, ammonium fluoride is added to a mixed solution of phosphor particles and magnesium chloride or a mixed solution of phosphor particles and calcium chloride, and magnesium fluoride or magnesium fluoride is added to the surface of the phosphor particles. This is a method in which calcium fluoride is deposited and adhered, dehydrated and dried to form a magnesium fluoride or calcium fluoride coating layer.

In the present invention, since the surface of the phosphor particles is coated with a magnesium fluoride or calcium fluoride layer, the phosphor particles can be oxidized without changing the conventional fluorescent lamp manufacturing process. Luminance reduction can be suppressed. Further, in the present invention, since the negative charge is not caused by covering with magnesium fluoride or calcium fluoride, even when the fluorescent lamp is used for a long time, the deterioration of the luminous flux due to the increased adsorption of mercury oxide is also improved.

As a method for producing this oxidation-resistant phosphor, the phosphor is slurried, magnesium chloride or calcium chloride is added thereto, and a solution of ammonium fluoride is added dropwise with sufficient stirring to obtain phosphor particles. Magnesium fluoride or calcium fluoride is deposited and adhered to the surface, which is dehydrated and dried to form a magnesium fluoride or calcium fluoride coating layer.

The phosphor used in the present invention is not limited to the phosphor used in ordinary fluorescent lamps.
An improvement in oxidation resistance can be expected for a phosphor such as a phosphor used for a display such as a PDP, which has a problem of luminance degradation due to oxidation in a manufacturing process when the phosphor is used.

[0027]

[Embodiment 1] Production of phosphor coated with magnesium fluoride layer Table 1 shows that 1,2,3,5% of 50 g of a europium-activated barium magnesium aluminate phosphor was used.
The weights of magnesium chloride and ammonium fluoride required to coat the magnesium fluoride are shown.

[0028]

[Table 1]

The specific formation of the magnesium fluoride layer is as follows.
50 g of the phosphor and magnesium chloride are added to 300 ml of pure water and stirred to form a uniform slurry. Next, while the slurry is being stirred, ammonium fluoride previously dissolved in 200 ml of pure water is dropped, and magnesium fluoride is deposited and adhered to the surface of the phosphor particles. After stirring for a while, dehydration and drying (110 ° C, 5H)
An oxidation-resistant phosphor in which the surface of the phosphor particles was coated with a magnesium fluoride layer was obtained.

The oxidation resistant phosphor thus obtained and the phosphor before the coating treatment were subjected to a heat treatment at 600 ° C. for 1 hour in the air, and the reduction ratio of luminance and luminance / y is shown in Table 2. Shown in The values in the table are relative values when the values of the luminance and luminance / y of the phosphor before the coating treatment are set to 100.

[0031]

[Table 2]

As is evident from Table 2, the method of the present invention can prevent the luminance and the luminance / y from decreasing by up to 10%.

Embodiment 2 FIG. Production of phosphor coated with calcium fluoride layer Table 3 shows that 50 g of europium-activated barium / strontium / magnesium / aluminate phosphor was
The weight of calcium chloride and ammonium fluoride required to coat 2.5% calcium fluoride is indicated.

[0034]

[Table 3]

To form a concrete calcium fluoride layer, 50 g of a phosphor and calcium chloride are added to 300 ml of pure water and stirred to form a uniform slurry. Next, while the slurry is being stirred, ammonium fluoride previously dissolved in 200 ml of pure water is dropped, and calcium fluoride is deposited and adhered to the surface of the phosphor particles. After stirring for a while, dehydration and drying (110 ° C., 5H) can provide an oxidation-resistant phosphor whose phosphor particle surfaces are covered with a calcium fluoride layer.

The oxidation-resistant phosphor thus obtained and the phosphor before the coating treatment were subjected to a heat treatment at 600 ° C. for 1 hour in air to show the luminance and the rate of decrease in luminance / y. Shown in Note that the values in the table are relative values when the luminance and luminance / y values of the phosphor before the coating treatment are set to 100.

[0037]

[Table 4]

As is apparent from Table 4, the method of the present invention can prevent the luminance of 2.5% and the luminance / y from decreasing by 3.5%.

[0039]

As described above, according to the present invention, it is possible to obtain an oxidation-resistant phosphor and a method for producing the same, which can suppress a decrease in luminance due to oxidation of the phosphor without changing the conventional baking step. This has the effect.

 ──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Riki Kanda 2-2-1 Shimotsuruma, Yamato-shi, Kanagawa F-term in Tokyo Chemical Laboratory Co., Ltd. (reference) 4H001 CC08 CF01 5C028 EE11

Claims (6)

[Claims] 1. An oxidation-resistant phosphor, wherein the surfaces of the phosphor particles are coated with a magnesium fluoride layer. 2. An oxidation-resistant phosphor, wherein the surface of the phosphor particles is coated with a calcium fluoride layer. 3. An oxidation-resistant phosphor, wherein a magnesium fluoride film layer is formed on the phosphor surface using magnesium chloride and ammonium fluoride. 4. An oxidation-resistant phosphor, wherein a calcium fluoride coating layer is formed on the phosphor surface using calcium chloride and ammonium fluoride. 5. An ammonium fluoride is added to a suspension mixture of phosphor particles and magnesium chloride to deposit and adhere magnesium fluoride on the surface of the phosphor particles, which is then dehydrated and dried to obtain magnesium fluoride. A method for producing an oxidation-resistant phosphor, comprising forming a coating layer. 6. An ammonium fluoride is added to a suspension mixture of phosphor particles and calcium chloride to deposit and adhere calcium fluoride on the surface of the phosphor particles, which is then dehydrated and dried to obtain calcium fluoride. A method for producing an oxidation-resistant phosphor, comprising forming a coating layer.