1. Field of the Invention
The present invention relates to an image display apparatus used for displaying characters and images, such as a display of a television receiver or a computer, and a message board, and a manufacturing method thereof.
2. Related Background Art
As an image display apparatus which has been generally spread widely, a color cathode ray tube (CRT) can be cited. Because the driving principle of the color CRT is that electron beams from the cathode thereof are deflected to make phosphors on the screen thereof emit light, the color CRT needs a depth according to the screen size thereof. Because the depth becomes long as the screen becomes large, the color CRT has problems of the expansion of the setting space thereof and of the increase of the weight thereof. Consequently, a thin-shaped flat type image display apparatus capable of being made to be light is strongly desired.
As the flat type image display apparatus, there are ones using plasma discharge, using a liquid crystal device, and using a vacuum fluorescent display. As the flat type image display apparatus attracting attention owing to its high picture quality and its low power consumption, a displaying apparatus using electron-emitting devices can be cited. The displaying apparatus using the electron-emitting devices is a displaying apparatus using a phenomenon of causing luminescence by the collision of electrons emitted in the inside of a vacuum chamber to a phosphor, to which a high voltage is applied. Accordingly, it is necessary to perform hermetic sealing of a voltage supplying path in the vacuum chamber. Japanese Patent Application Laid-Open No. 2003-92075 discloses concrete means of the hermetic sealing.
The configuration of the voltage supplying path to the phosphor disclosed in the Japanese Patent Application Laid-Open No. 2003-92075 is schematically shown in
In the configuration of
However, because the calcination temperature of the frit glass is 350° C. or more, which is very high, in the above-mentioned method, in which the hermetic lead-in terminal 103 adheres with the frit glass, the process cost of the method is high, and the high process cost is the primary factor of raising the cost of an article. Moreover, because the frit glass contains lead, the frit glass has a problem on environmental health.
It is an object of the present invention to provide an image display apparatus equipped with a hermetic container including a voltage applying path having good airtightness and being capable of applying a voltage surely from the outside to an electrode provided in the inside of the hermetic container.
Moreover, it is another object of the present invention to provide an image display apparatus including a voltage applying path capable of obtaining good airtightness without necessitating an adhesion process at a high temperature and without producing any environmental problems.
The present invention is an image display apparatus equipped with a hermetic container, which includes a first substrate, a second substrate disposed to be opposed to the first substrate, and an outer frame disposed between both of the substrates, and an electrode disposed on the first substrate in the hermetic container, including an electroconductive member sealing a hole formed in the second substrate, and adhering to the electrode to form a voltage applying path to the electrode.
In an example, the image display apparatus further includes a member enclosing the electroconductive member at a gap between the first substrate and the second substrate, the member having a melting point higher than that of the electroconductive member.
In an example, the melting point of the electroconductive member is 350° C. or less.
In an example, the electroconductive member is an alloy containing at least one selected from the group consisting of In, Li, Bi and Sn.
In an example, an image display apparatus further includes an electron source disposed on the second substrate, and a phosphor disposed on the first substrate in the hermetic container, wherein the electrode is one for accelerating electrons emitted from the electron source.
Moreover, the present invention is a manufacturing method of an image display apparatus equipped with a hermetic container, which includes a first substrate, a second substrate disposed to be opposed to the first substrate, and an outer frame disposed between both of the substrates, and an electrode disposed on the first substrate in the hermetic container, including the steps of: disposing an electroconductive sealing member on the second substrate including a hole formed therein in order to cover the hole; disposing the first substrate provided with the electrode so that the electrode and the electroconductive sealing member may be opposed to each other; and heating the electroconductive sealing member to perform adhesion of the sealing member to the electrode and sealing of the hole with the sealing member.
In an example, the electroconductive sealing member disposed on the second substrate includes a member around the electroconductive sealing member, the member having a melting point higher than that of the electroconductive sealing member.
In an example, the melting point of the electroconductive sealing member is 350° C. or less.
In an example, the electroconductive member is an alloy containing at least one selected from the group consisting of In, Li, Bi and Sn.
In an example, an image display apparatus further includes an electron source disposed on the second substrate, and a phosphor disposed on the first substrate in the hermetic container, wherein the electrode is one for accelerating electrons emitted from the electron source.
A first aspect of the present invention is an image display apparatus equipped with a hermetic container, which includes a first substrate, a second substrate disposed to be opposed to the first substrate, and an outer frame disposed between both of the substrates, and an electrode disposed on the first substrate in the hermetic container, including an electroconductive member sealing a hole formed in the second substrate, and adhering to the electrode to form a voltage applying path to the electrode.
A second aspect of the present invention is a manufacturing method of an image display apparatus equipped with a hermetic container, which includes a first substrate, a second substrate disposed to be opposed to the first substrate, and an outer frame disposed between both of the substrates, and an electrode disposed on the first substrate in the hermetic container, including the steps of: disposing an electroconductive sealing member on the second substrate including a hole formed therein in order to cover the hole; disposing the first substrate provided with the electrode so that the electrode and the electroconductive sealing member may be opposed to each other; and heating the electroconductive sealing member to perform adhesion of the sealing member to the electrode and sealing of the hole with the sealing member.
The voltage applying path according to the present invention is high in hermetic reliability and excellent in the reliability of electrical connection with an electrode.
Moreover, the voltage applying path according to the present invention can use an electroconductive member having a low melting point, and no high temperature processes are needed. Consequently, the voltage applying path can be implemented at a low price. Moreover, because the voltage applying path does not use any frit glass, it is excellent also in environmental health. Accordingly, by adopting the voltage applying path according to the present invention, it is possible to provide a highly reliable image display apparatus at a lower price.
In the following, the present invention will be described by exemplifying embodiments.
In
The voltage applying path according to the present invention is formed between the positive electrode (not shown) connected to the electrode 3 in the inside of the hermetic container and the outside of the hermetic container by sealing the hole 4 formed in the second substrate 2 with the electroconductive member such as the low melting point metal 5, and by making the electroconductive member adhere to the electrode 3 formed on the first substrate 1.
In the voltage applying path in
Next, a manufacturing process of the voltage applying path of
The low melting point metal 5 as the electroconductive sealing member is disposed in order to cover the hole 4 in the second substrate 2, on which the under electrode 9 has been formed.
From the opposite side of the hole 4 covered by the low melting point metal 5, the head for energization heating 10 is inserted, and is contacted with the low melting point metal 5. Then, a current is flown to melt the low melting point metal 5 (
When the low melting point metal 5 has been completely melted, the first substrate 1, on which the electrode 3 has been formed, is made to descend, and the melted low melting point metal 5 and the electrode 3 are made to be contacted with each other. Then, they are held for 10 minutes or more in that contacted state (
The head for energization heating 10 is retracted from the hole 4, and the sealing of the hole 4 by the electroconductive sealing member 5 and the adhesion of the sealing member 5 and the electrode 3 to each other are performed through natural heat dissipation by radiation (
Moreover, after the manufacturing by the above process, mounting for applying a voltage from the outside is performed. The mounting is to attach the insulating cover 7, the electroconductive part 6 and the voltage supply cable 8 to the substrates 2 in the state of
In the embodiment shown in
In the embodiment of
In the embodiment of
In the embodiment of
Moreover,
In the present invention, as shown in
As described above, in the voltage applying path according to the present invention, the seal-bonding temperature can be lowered while the hermetic reliability is being kept. Then, the image display apparatus can be produced at a lower price. Moreover, the image display apparatus can be produced without any problems on the environmental health.
A voltage applying path having the form shown in
Before pasting the first substrate 1 and the second substrate 2 to each other, the positive electrode wire 3 and the under electrode 9 were printed on the first substrate 1 and the second substrate 2, respectively, with Ag paste. The first and the second substrates 1 and 2 were calcinated at 530° C. in a batch type furnace to form the positive electrode 3 and the under electrode 9. Subsequently, an outer frame, the first substrate 1 and the second substrate 2 were pasted together to form a container.
The container was disposed in the vacuum atmosphere at 1×10−6 Pa or less, and In alloy was disposed as the low melting point metal 5 in order to cover the voltage applying hole 4 in the second substrate 2 (
Next, the head for energization heating 10 was inserted into the voltage applying hole 4 from the opposite side thereof, and was contacted to the low melting point metal 5. Then, current was flown to melt the low melting point metal 5 (
When the low melting point metal 5 had been completely melted, the first substrate 1, on which the positive electrode wire 3 was formed, descended to make the low melting point metal 5 and the positive electrode wire 3 be contacted with each other, and they were held for 10 minutes or more in that state (
After that, the head for energization heating 10 was retracted from the voltage applying hole 4, and natural heat dissipation by radiation was performed for 30 minutes. Thereby, the In alloy was solidified, and the voltage applying hole 4 was sealed (
Moreover, mounting for the voltage application from the outside was performed. First, the electroconductive part 6 and the voltage supply cable 8, which are made to adhere to each other by soldering, are inserted and fixed into the insulating cover 7. The electroconductive part 6 was made by the press working of brass, and nickel base gilding was performed on the surface of the brass. The gilding is for improving the reliability of soldering with the voltage supply cable 8. Then, the insulating cover 7 was fixed in the state in which the low melting point metal 5 was contacted with the electroconductive part 6. As the fixing means, the pressing force from the back surface of the insulating cover 7 was used. The insulating cover 7 has the principal component of silicone rubber, and was installed so that the insulating cover 7 may adhere closely to the second substrate 2.
By configuring the voltage applying path as described above, an image display apparatus could be produced at a low seal-bonding temperature while securing hermetic reliability.
A voltage applying path of the form shown in
First, a member produced by inpouring melted Sn alloy as the low melting point metal 5 into the control member 31 made of stainless to solidify therein was previously prepared. Incidentally, a projecting portion to be fitted to the voltage applying hole 4 was formed on the low melting point metal 5.
Like Example 1, a container formed by pasting the first substrate 1 and the second substrate 2 together with each other was disposed in an vacuum atmosphere of 1×10−6 Pa or less, and the low melting point metal 5 solidified in the control member 31 was disposed in order that the projecting portion thereof should be fit into the voltage applying hole 4 (
The head for energization heating 10 was inserted into the voltage applying hole 4 from the opposite side to the one covered by the low melting point metal 5 to be contacted with the low melting point metal 5. Then, a current was flown to melt the low melting point metal 5 (
When the low melting point metal 5 had completely melted, the first substrate 1, on which the positive electrode wire 3 was formed, was made to descend, and the low melting point metal 5 and the positive electrode wire 3 were contacted to each other. Then, a pressure was applied to the first substrate 1 from the outside thereof to bend the control member 31 (
The head for energization heating 10 was retracted from the voltage applying hole 4, and natural heat dissipation by radiation was performed for 30 minutes. Thereby, Sn alloy was solidified, and the voltage applying hole 4 was sealed (
Moreover, mounting for the voltage application from the outside was performed. First, the electroconductive part 6 and the voltage supply cable 8 which were made to adhere with each other by soldering were inserted and fixed into the insulating cover 7. The electroconductive part 6 was produced by performing the press working of brass, and nickel base gilding was performed on the surface of the brass. The gilding is for improving the reliability of the soldering with the voltage supply cable 8. First, the fixing nut 32 was made to adhere to the substrate 2 with the epoxy adhesive 33 to be fixed thereto, and the thread portion of the electroconductive part 6 was inserted into the internal thread portion of the fixing nut 32 to be rotated therein. Then, the screw was tightened until the screw touched at the low melting point metal 5. The insulating cover 7 has the principal component of silicone rubber, and was installed so that the insulating cover 7 might adhere closely to the second substrate 2.
By configuring the voltage applying path as described above, an image display apparatus could be produced at a low seal-bonding temperature while securing hermetic reliability. Moreover, in the present example, the accuracy of controlling the shape of the low melting point metal 5 was improved by means of the control member 31, and it became possible to apply a voltage stably.
A voltage applying path of the form shown in
First, a member produced by inpouring melted Bi alloy as the low melting point metal 5 into the control member 31 made of carbon to solidify therein was previously prepared. Incidentally, a projecting portion to be fitted to the voltage applying hole 4 was formed on the low melting point metal 5.
Like Example 1, a container formed by pasting the first substrate 1 and the second substrate 2 together with each other was disposed in an vacuum atmosphere of 1×10−6 Pa or less, and the low melting point metal 5 solidified in the control member 31 was disposed in order that the projecting portion thereof should be fit into the voltage applying hole 4 (
The head for energization heating 10 was inserted into the voltage applying hole 4 from the opposite side to the one covered by the low melting point metal 5 to be contacted with the low melting point metal 5. Then, a current was flown to melt the low melting point metal 5 (
When the low melting point metal 5 had completely melted, the first substrate 1, on which the positive electrode wire 3 was formed, was made to descend, and the low melting point metal 5 and the positive electrode wire 3 were contacted to each other. Then, a pressure was applied to the first substrate 1 from the outside thereof to bend the control member 31 (
The head for energization heating 10 was retracted from the voltage applying hole 4, and natural heat dissipation by radiation was performed for 30 minutes. Thereby, Bi alloy was solidified, and the voltage applying hole 4 was sealed (
Moreover, mounting for the voltage application from the outside was performed. First, the electroconductive part 6 and the voltage supply cable 8 which were made to adhere with each other by soldering were inserted and fixed into the insulating cover 7. The electroconductive part 6 was produced by performing the press working of brass, and nickel base gilding was performed on the surface of the brass. The gilding is for improving the reliability of the soldering with the voltage supply cable 8. Then, the contact and the conduction were secured by inserting the needle portion of the electroconductive part 6 into the melting point metal 5. The insulating cover 7 has the principal component of silicone rubber, and was installed so that the insulating cover 7 might adhere closely to the second substrate 2. By disposing the low melting point metal 5 to be embedded in the voltage applying hole 4 of the second substrate 2, the conduction structure with the electroconductive part 6 became easy.
By configuring the voltage applying path as described above, an image display apparatus could be produced at a low seal-bonding temperature while securing hermetic reliability. Moreover, in the present example, the accuracy of controlling the shape of the low melting point metal 5 was improved by means of the control member 31, and it became possible to apply a voltage stably.
A voltage applying path of the form shown in
First, a member produced by inpouring melted In alloy as the low melting point metal 5 into the control member 31 shaped by press working of SUS 304 to solidify therein was previously prepared. Incidentally, a projecting portion to be fitted to the voltage applying hole 4 was formed on the low melting point metal 5.
Like Example 1, a container formed by pasting the first substrate 1 and the second substrate 2 together with each other was disposed in an vacuum atmosphere of 1×10−6 Pa or less, and the low melting point metal 5 solidified in the control member 31 was disposed in order that the projecting portion thereof should be fit into the voltage applying hole 4 (
The head for energization heating 10 was inserted into the voltage applying hole 4 from the opposite side to the one covered by the low melting point metal 5 to be contacted with the low melting point metal 5. Then, a current was flown to melt the low melting point metal 5 (
When the low melting point metal 5 had completely melted, the first substrate 1, on which the positive electrode wire 3 was formed, was made to descend, and the low melting point metal 5 and the positive electrode wire 3 were contacted to each other. Then, a pressure was applied to the first substrate 1 from the outside thereof to bend the control member 31 (
The head for energization heating 10 was retracted from the voltage applying hole 4, and natural heat dissipation by radiation was performed for 30 minutes. Thereby, In alloy was solidified, and the voltage applying hole 4 was sealed (
Moreover, mounting for the voltage application from the outside was performed. First, the electroconductive part 6 and the voltage supply cable 8 which were made to adhere with each other by soldering were inserted and fixed into the insulating cover 7. The electroconductive part 6 was produced by performing the press working of brass, and nickel base gilding was performed on the surface of the brass. The gilding is for improving the reliability of the soldering with the voltage supply cable 8. Then, the potting agent 71 was coated on the side of the second substrate 2 opposite to the first substrate 1 in the neighborhood of the low melting point metal 5 with a dispenser, and the potting agent 71 was solidified in the state in which the electroconductive part 6 was contacted and conducted to the low melting point metal 5. The potting agent 71 was one-liquid type silicone, and one of the type of absorbing the moisture in the air to be solidified was used. The insulating cover 7 has the principal component of silicone rubber, and was installed so that the insulating cover 7 might adhere closely to the second substrate 2. By disposing the low melting point metal 5 to be embedded in the voltage applying hole 4 of the second substrate 2, the conduction structure with the electroconductive part 6 became easy.
By configuring the voltage applying path as described above, an image display apparatus could be produced at a low seal-bonding temperature while securing hermetic reliability. Moreover, in the present example, the accuracy of controlling the shape of the low melting point metal 5 was improved by means of the control member 31, and it became possible to apply a voltage stably.
Moreover, by using the potting agent 71, the ingress of an alien substance into the insulating cover 7 could be prevented, and a stable voltage supply and a stable image display could be obtained.
A voltage applying path of the form shown in
First, a member produced by inpouring melted Sn alloy as the low melting point metal 5 into the control member 31 made of copper alloy, in which a metal part 91 made of copper alloy was put, to solidify therein was previously prepared. Incidentally, a projecting portion to be fitted to the voltage applying hole 4 was formed on the low melting point metal 5.
Like Example 1, a container formed by pasting the first substrate 1 and the second substrate 2 together with each other was disposed in an vacuum atmosphere of 1×10−6 Pa or less, and the low melting point metal 5 solidified in the control member 31 was disposed in order that the projecting portion thereof should be fit into the voltage applying hole 4 (
The head for energization heating 10 was inserted into the voltage applying hole 4 from the opposite side to the one covered by the low melting point metal 5 to be contacted with the low melting point metal 5. Then, a current was flown to melt the low melting point metal 5 (
When the low melting point metal 5 had completely melted, the first substrate 1, on which the positive electrode wire 3 was formed, was made to descend, and the low melting point metal 5 and the positive electrode wire 3 were contacted to each other. Then, a pressure was applied to the first substrate 1 from the outside thereof to bend the control member 31 (
The head for energization heating 10 was retracted from the voltage applying hole 4, and natural heat dissipation by radiation was performed for 30 minutes. Thereby, Sn alloy was solidified, and the voltage applying hole 4 was sealed (
Moreover, mounting for the voltage application from the outside was performed. First, the electroconductive part 6 and the voltage supply cable 8 which were made to adhere with each other by soldering were inserted and fixed into the insulating cover 7. The electroconductive part 6 was produced by performing the press working of brass, and nickel base gilding was performed on the surface of the brass. The hook 92 was made of SUS 304. The gilding is for improving the reliability of the soldering with the voltage supply cable 8. Then, the contact and the conduction were secured by inserting the hook 92 into the hole of the metal part 91. The insulating cover 7 has the principal component of silicone rubber. Since the flange portion of the insulating cover 7 was adapted to expand by a reaction force when the hook 92 was hung on the metal part 91, the insulating cover 7 could adhere closely to the second substrate 2. Moreover, a tension is always generated at the contacting portion of the hook 92 and the metal part 91.
By configuring the voltage applying path as described above, an image display apparatus could be produced at a low seal-bonding temperature while securing hermetic reliability. Moreover, in the present example, the accuracy of controlling the shape of the low melting point metal 5 was improved by means of the control member 31, and it became possible to apply a voltage stably.
Moreover, by using the metal part 91, the stability of shaping the low melting point metal 5 was increased. Consequently, an image display apparatus including a voltage applying path having a higher reliability could be produced.
This application claims priority from Japanese Patent Application No. 2004-115239 filed Apr. 9, 2004, which is hereby incorporated by reference herein.
Number | Date | Country | Kind |
---|---|---|---|
2004-115239 | Apr 2004 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6885156 | Tajima et al. | Apr 2005 | B2 |
7101244 | Kamiguchi | Sep 2006 | B2 |
20030025443 | Kamiguchi | Feb 2003 | A1 |
20030085651 | Takahashi | May 2003 | A1 |
20060217024 | Kamiguchi | Sep 2006 | A1 |
Number | Date | Country |
---|---|---|
2000-208031 | Jul 2000 | JP |
2002-182585 | Jun 2002 | JP |
2003-92075 | Mar 2003 | JP |
2004-111376 | Apr 2004 | JP |
Number | Date | Country | |
---|---|---|---|
20050225229 A1 | Oct 2005 | US |