JPS61143928A - Color cathode ray tube - Google Patents

Abstract

PURPOSE:To improve color purity and contrast of a color cathode ray tube by forming, on its face plate, a filter layer which includes an appropriate chelating agent that can chelate Nd<3+> ions. CONSTITUTION:Within a face plate 13, a fluorescent screen 18 having fluorescent material in stripes and index stripes of red, green and blue is formed, while in a position confronting this fluorescent screen 18 in the neck part an electron gun 15 is installed. To the outside surface of the face plate 13, which is to become an image screen, a glass panel 14 is pasted through the interposition of a metal spacer 19, and between the face plate 13 and the glass panel 14 a liquid coolant that will also play the role of a filtering layer is filled in. By adding to the liquid coolant, which comprises ethylene grycol solvent, Nd<3+> ions and also a chelating agent capable of chelating Nd<3+> ions, it is possible to improve color purity and contrast of images.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a color cathode ray tube, for example a color cathode ray tube for a projector.

[Conventional technology]

In a color cathode ray tube, unnecessary emission colors are included in the emission spectrum emitted from the phosphor on the fluorescent surface, and color purity and contrast are degraded due to this. To improve this, for example, a filter layer made of a solution containing neodymium nitrate Nd (NO3)3, that is, a liquid containing Nd3 ÷ ions, is placed in front of the cathode ray tube to absorb unnecessary emitted light colors and improve color purity. A color cathode ray tube has been proposed (George Pan, H.
(See N. Hirshe, S. Kablan, Electrochemical Chictology, nL, 531-534, (1969)).

(Problems to be Solved by the Invention) On the other hand, color cathode ray tubes for single-tube projectors use phosphors that emit high-intensity light, such as YAG:
Tb (green phosphor), Y2O3:Bu (red phosphor) has an unnecessary emission color in the region (5) of 580 to 600n-, as shown in emission spectra (2) and (3) in Figure 3. exhibits. However, (1) is the blue emission spectrum, (2
) shows a green emission spectrum, and (3) shows a red emission spectrum.

In order to remove such unnecessary emission colors, when a filter layer containing NdJ◆ ions is used as in the past, the peak of the absorption spectrum (4) is at about 570 nm.
580~600n-) due to the difference between 580~600n-)
Unnecessary luminescent colors present at 0rv cannot be effectively removed.

The present invention provides a color cathode ray tube provided with a filter layer that can effectively remove unnecessary emission colors that exist in the region of 580 to 600 nm, thereby improving color purity and contrast. It is something.

[Means for solving problems]

The color cathode ray tube of the present invention is characterized in that a filter layer to which Nd3+ ions are added and a suitable chelating agent capable of chelating the Nd3+ ions is provided on the image plane.

The filter layer can be formed of liquid or solid. In color cathode ray tubes for projectors, the cooling liquid placed in front of the image plane also serves as a filter layer.

As the chelating agent, EDTA (ethylediaminetetraacetic acid), NTA (trilotriacetic acid), etc. can be used.

Nd3+ ion is neodymium nitrate Nd(NO3)3,
Neodymium chloride NdCl3, neodymium carbonate Ndz (CO3
) 3 etc.

[Effect]

By adding a chelating agent capable of chelating Nd3+ ions together with NdJ÷ ions into the filter layer, the peak of the absorption spectrum, which was conventionally located at about 570 nmO, moves to the longer wavelength side. This improves the color purity and contrast of images.

〔Example〕

Hereinafter, a case will be described in which the present invention is applied to a color cathode ray for a single tube projector.

In FIG. 1, (12) shows the color cathode ray tube of the present invention as a whole, and the inner surface of the face plate (13) is red.
A fluorescent surface (18) having green and blue phosphor stripes and index stripes is formed, and this fluorescent surface (18) is formed.
An electron gun (15) is disposed within the neck portion opposite to the electron gun (18). A glass panel (14) is attached to the outer surface of the face plate (13), which becomes the image plane, via a metal spacer (19).
) is sealed, and a cooling liquid (11) that also serves as a filter layer is placed between the face plate (13) and the glass panel (14).
is included. (16) is an electron beam, (17) is an electromagnetic deflection device for horizontal and vertical deflection, and (20) is a detector that detects the optical signal from the index stripe.

The coolant (11) in this case consists of an ethylene glycol solution. In this example, neodymium nitrate Nd(NO3)3.6H20 and EDTA tetrasodium salt EDTA.4Na are added to the coolant (11) to function as a filter layer.

Example 1 Ethylene glycol solution (ethylene glycol: water = 1
:4. Volume ratio) 60g neodymium nitrate Nd (NO3)
After adding 3g of 3.6H20 and mixing, it becomes 1/10 mol per 1 mol of neodymium nitrate II!
DTA tetrasodium salt EDTA 4Na 0.3g
The absorption spectrum of the added cooling liquid (11) was measured. This result is shown in curve (21) in FIG. In addition,
The reason why EDTA is made into a sodium salt is to make it easily soluble in water.

Example 2 Ethylene glycol solution (ethylene glycol: water-1
=41 volume ratio) 60g of neodymium nitrate Nd (NO3)
After adding 3g of 36H20 and mixing, add 4 mol of EDTA to 1/2 mol per 1 mol of neodymium nitrate.
The absorption spectrum of the coolant (11) to which 1.6 g of sodium salt EDTA 4Na was added was measured. This result is shown in curve (22) in FIG.

Example 3 Ethylene glycol solution (ethylene glycol: water = 1
:4. Volume ratio) 60g neodymium nitrate Nd (NO3)
After adding 3g of 3.6H20 and mixing, add 4g of EDTA to give 1a+ol per mol of neodymium nitrate.
The absorption spectrum of the coolant (11) to which 3.2 g of sodium salt EDTA.4Na was added was measured. This result is shown in curve (23) in FIG.

Comparative Example Ethylene glycol solution (ethylene glycol: water = 1
:4. Volume ratio) 60g neodymium nitrate Nd (NO3)
The result of measuring the absorption spectrum of the coolant (11) to which 3g of 3.6H20 alone was added is shown in curve (4) in Figure 2.
Shown below.

, From the above example, Nd3 was added to the cooling liquid of the filter layer.
It can be seen that by adding 4 ions and 1liDT^ which can chelate this Nd3+ ion, the peak of the absorption spectrum shifts to the longer wavelength side compared to the case of only Nd3+ ions. Especially the ED
TA to 31 mol of Nd (NO3) 1/2
If more than mo1 is added, the peak shift will be significant. From the viewpoint of stability, 1/2 mol is better.

In the above embodiments, an ethylene glycol solution was used as the solvent, but similar effects can be obtained when water is used as the solvent.

Moreover, although the filter layer was constructed by including chelated Nd3 ÷ ions in the liquid on the upper side, the filter layer may also be constructed by including chelated Nd3+ ions in the solid.

Furthermore, the present invention is applicable not only to single tube projectors but also to other color cathode ray tubes.

〔Effect of the invention〕

According to the present invention, since unnecessary emitted light colors existing particularly in the 580 to 600 nm region are efficiently absorbed, a color cathode ray tube with excellent color purity and contrast can be obtained.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view showing a color cathode ray tube according to the present invention, FIG. 2 is a graph showing the absorption spectrum of a coolant according to an example, and FIG. 3 is a graph showing blue phosphor, green phosphor, and red phosphor. 2 is a graph showing an emission spectrum of a body and an absorption spectrum of a conventional coolant. (11) is a filter layer, and (12) is a color cathode ray tube. ) 1 filter layer 350 450 500 60
0 70OtL&(nm)

Claims (1)

[Claims] A color cathode ray tube characterized in that a filter layer containing chelated Nd^3^+ ions is provided on an image plane.