JPH0773826A - Electroconductive film and fluorescent display tube with it - Google Patents

Abstract

PURPOSE:To provide an electroconductive film for use effectively in the anode conductor, etc., of a fluorescent display tube by printing a paste of a specific composition on a base board followed by a baking process. CONSTITUTION:An electroconductive film is prepared by printing an electroconductive paste on a base board, and the resultant is subjected to a baking process. The paste contains aluminoxy-titanium phosphate as an organic metal compound, graphite powder as conductive substance, and a solvent, and if necessary, a filler as additive. The aluminoxy-titania phosphate is added to improve the performance of the paste printing operation and to give a strong bonding force to a resultant conductive film formed from the paste including powder-form conductive substance. The aluminoxy-titanium phosphate is expressed by the structural formula as shown in the attached illustration, and butyl phosphate contained therein enhances the film attachment force after baking.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a conductive film useful as various electrodes, wiring conductors or functional films having various purposes, and a fluorescent display tube having such a conductive film.

[0002]

2. Description of the Related Art As shown in FIG. 6, a display portion of a fluorescent display tube is formed on an inner surface of an anode substrate 1 which constitutes a part of an envelope. That is, the wiring conductor 2 is provided on the inner surface of the anode substrate 1, and the wiring conductor 2 is covered with the insulating layer 3. A through hole 4 is formed in the insulating layer 3, and an anode conductor 5 is formed on the through hole 4. The anode conductor 5
A phosphor layer 6 is deposited on the upper surface of the anode to constitute an anode 7 as a light emitting display section. The anode conductor 5 and the wiring conductor 2 are electrically connected via a conductive material 8 filled in the through hole 4.

Generally, the anode conductor 5 is composed of a conductive film made of graphite paste. The composition of the graphite paste is, for example, 85 parts of graphite powder and ultrafine SiO.
₂ 15 parts, 66 parts of organic metal such as TOG, and 33 parts of tridecanol as a solvent.

The graphite paste is printed on the insulating layer 3 by a screen printing method and fired to form the anode conductor 5 as the conductive film. When the fired conductive paste is enlarged and observed with a microscope or the like, a structure as shown in FIG. 7 is recognized. That is, ultrafine SiO ₂ and metal oxide particles 11 are present between the graphite particles 10, and the graphite particles 10 are not in contact with each other.

[0005]

The ultrafine particles of SiO ₂ have the function of increasing the fixing strength of graphite particles and improving the printability as a paste. However, at the same time SiO ₂
The ultra-fine particles also have a problem that they adsorb water and gas and thus contaminate the cathode of the fluorescent display tube and reduce its emission characteristics. Further, when the amount of SiO ₂ is large, the resistance value of the conductive film becomes high, and it becomes impossible to set the resistance value to 100Ω / □ or less. Therefore, it was not possible to increase the SiO ₂ content in the paste too much.

Therefore, in the conventional paste for forming a conductive film, if the amount of SiO ₂ compounded is increased to improve the adhesion strength and printability of graphite, the emission of the cathode is lowered and the paste as a conductive film is formed. If the resistance value becomes large and the amount of SiO ₂ blended is reduced, the problems of emission and resistance value will be somewhat improved, but there is a problem that the fixing strength is lowered and the printability is deteriorated.

It is an object of the present invention to form a conductive film which does not contain SiO ₂ and has a good printability and which has a strong fixing force for a conductive substance such as graphite.

[0008]

The conductive film of the present invention as defined in claim 1 is characterized in that it is obtained by firing a paste containing aluminooxytitanium phosphate and a powdery conductive material.

The fluorescent display tube of the present invention according to claim 2 has the conductive film according to claim 1 obtained by firing a paste containing aluminooxytitanium phosphate and a conductive substance in powder form. There is.

[0010]

The organotitanium and butyl phosphate contained in the aluminooxytitanium phosphate strengthen the adhesion of the powdery conductive material. In addition, ethyl acetoacetate and octylene glycol have an action of enhancing printability in a paste state.

[0011]

EXAMPLE The conductive film of this example is obtained by printing a conductive paste and firing it. Then, this conductive paste is aluminooxytitanium phosphate which is an organometallic compound proposed by the present inventor, graphite powder which is a powdery conductive substance, a solvent, and a filler which is further added if necessary. Is included.

Aluminooxytitanium phosphate is added to improve the printability of the conductive paste, and to give a strong bonding force to the conductive film formed from the conductive paste containing the powdery conductive material. .

Aluminooxytitanium phosphate is represented by the structural formula shown in FIG. The oxide of Ti has a strong binding force with other substances, and the reason why the conductive film formed by the paste containing aluminooxytitanium phosphate shows a strong binding force is partly because the aluminooxytitanium phosphate is an oxide of Ti. It is thought that there is to include.

As shown in FIG. 1, aluminooxytitanium phosphate has JP (butyl phosphate). J
The structural formula of P (butyl phosphate) is shown in FIG. It is considered that another reason why the conductive film formed of the paste containing aluminooxytitanium phosphate has a strong binding force is that the aluminooxytitanium phosphate contains JP (butyl phosphate).

As shown in FIG. 1, the aluminooxytitanium phosphate has Al bound to EtAcAc (ethieracetoacetate). The structural formula of EtAcAc (Ethyl acetoacetate) is shown in FIG. Et
Al to which AcAc (Ethylacetoacetate) is bound
Is effective as a coupling agent and improves the dispersibility of graphite powder and filler added at the same time in the paste containing aluminooxytitanium phosphate.

As shown in FIG. 1, aluminooxytitanium phosphate has OG (octylene glycol (2-ethyl1.3 hexanediol)). The structural formula of OG is shown in FIG. As you can see from Figure 4, this OG
Contains eight Cs. The present inventor
Various studies were carried out on aluminooxytitanium phosphate containing G. As a result, when the number of Cs in OG is 8,
It has been found that the stability of aluminooxytitanium phosphate is the best, the viscosity of the paste is appropriate, the thixotropic property is improved, and the printability is good. When the number of C is larger than this, the denseness of the paste is deteriorated, and the viscosity is increased to deteriorate the printability. On the contrary, when the number of C is less than this, the aluminooxytitanium phosphate becomes unstable.

Next, examples (1), (2) and (3) of more specific composition of the conductive paste will be shown. Example (1) 55 to 80 parts of graphite powder, 45 to 20 parts of filler, 66 parts of aluminooxytitanium phosphate, 33 parts of solvent. As the filler, TiO ₂ or Al ₂ O having a particle size of 0.2 μm is used.
₃ can be used. As the solvent, octylene glycol, tridecanol, terpineol, carbitol and the like can be used.

Example (2) 100 parts of graphite powder, 40 to 100 parts of aluminooxytitanium phosphate, 33 parts of solvent. In this example, a filler is not used.

Example (3) 80 parts of conductive metal oxide powder other than graphite, filler 20
Part, 66 parts of aluminooxytitanium phosphate, solvent 3
3 copies. Examples of conductive metal oxides other than graphite include IT
O, WO ₃ , In ₂ O ₃ or the like can be used, and it is preferable that the resistance does not increase even after firing.

In order to form the conductive film of this embodiment, the paste composed of the above-mentioned raw material mixture using the aluminooxytitanium phosphate or the like may be screen-printed on a desired object and baked. .

The paste of this embodiment has a conventional Si content.
Although it does not contain O ₂ , the one component aluminooxytitanium phosphate contains EtAcAc and OG, so that it has good thixotropic properties and excellent printability. Therefore, even with a complicated pattern, uniform printing can be performed with a required thickness. Therefore, it is effective for forming a conductor portion having a complicated display pattern such as an anode conductor of a fluorescent display tube.

Further, since the conductive film of the present embodiment does not contain SiO ₂ , there is no fear that the cathode will deteriorate and the emission will decrease even when applied to a fluorescent display tube as described above. In this sense as well, the conductive film made of the paste of the present embodiment is particularly useful as a conductive shielding film provided on an electrode portion such as an anode conductor in a fluorescent display tube or on the inner surface of an envelope.

FIG. 5 is a graph showing the results of the continuous lighting experiment conducted by the present inventor, showing the effect when the conductive film is used as an anode conductor of a fluorescent display tube in comparison with a conventional example. . When the conductive film of this embodiment is used as an anode conductor,
It can be seen that the anode current value did not decrease with the passage of the test time, and the emission at the cathode did not decrease. .
On the other hand, according to the conventional conductive film formed of the paste containing SiO ₂ , the anode current value surely decreases with the elapse of the test time. This indicates that SiO ₂ contained in the conductive film deteriorates the cathode and reduces its emission.

Further, according to the conductive film of this embodiment, SiO
_{Since 2} is not included, the contact area between the conductive materials becomes large, which reduces the resistance value. In this embodiment, the resistance value can be set from 20Ω / □, which is the limit of the conventional value.
It was much lower than 00Ω / □. Therefore, the conductivity with other wiring materials is improved, and the reliability is improved.

Further, according to the conductive film of this embodiment, JP was added to the aluminooxytitanium phosphate in the raw material paste.
(Butyl phosphate) is included, and since phosphorus enhances sintering during firing and forms a Ti-Al-P composite oxide, even if SiO ₂ is not used, the bond strength between powders is higher than conventional. I was able to improve.

The conductive film using the paste of this embodiment is not limited to fluorescent display tubes, but is widely used for wiring, conductors, various conductive functional films, etc. in other display elements, electronic elements and general equipment. It can be applied and has the excellent effect of improving the functionality of these objects to be applied because of the unique effects described above.

[0027]

Since the conductive film according to the present invention is formed by firing a paste containing aluminooxytitanium phosphate and a powdery conductive material, the following effects can be obtained. 1) Since the dispersibility of the powdery conductive material is improved, the thixotropic property in the paste state is excellent and the printability is improved. Further, the resistance value after firing becomes lower than in the conventional case, the resistance value can be arbitrarily controlled, and the reliability of electrical connection with wiring or the like increases.

2) Butyl phosphate contained in aluminooxytitanium phosphate improves the sticking strength after firing.

3) Even when applied to a fluorescent display tube, the emission of the cathode is not reduced. This is because no SiO ₂ was used, which was the cause of lowering the emission of the cathode.

[Brief description of drawings]

FIG. 1 is a diagram showing a structural formula of aluminooxytitanium phosphate.

FIG. 2 is a diagram showing a structural formula of butyl phosphate.

FIG. 3 is a diagram showing a structural formula of ethyl acetoacetate.

FIG. 4 is a diagram showing a structural formula of octylene glycol.

FIG. 5 is a graph showing changes in the anode current value with the passage of test time in a fluorescent display tube using the conductive film of the present example as the anode conductor and a conventional fluorescent display tube using the conductive film as the anode conductor. is there.

FIG. 6 is a cross-sectional view showing a general structure in the vicinity of an anode conductor of a fluorescent display tube.

FIG. 7 is an enlarged view showing the structure of a conductive film formed of a conventional paste.

Claims (2)

[Claims] 1. A conductive film obtained by firing a paste containing an aluminooxytitanium phosphate and a powdery conductive material. 2. A fluorescent display tube having the conductive film according to claim 1.