JPH10154465A - Thermal strain inspecting method for glass bulb and thermal strain inspecting method for electron gun - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thermal strain inspecting method by which 100% control of glass bulbs and electron guns is made possible and excess thermal strain of the glass bulbs and electron guns can be easily and reliably detected. SOLUTION: When a glass bulb 1 produced into a flask-like shape having a narrow open part in one end is supplied to a heating apparatus 10 and the narrow open part is sealed by melting and depositing a jointing plate 8 to an electron gun 2 in the narrow open part, a non-contact type radiation thermometer 14 is set in the inside of the heating apparatus, and the temperature of the melted and deposited part is measured, so that excessive strains of the melted and deposited part can be detected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for inspecting thermal distortion of a glass bulb constituting a cathode ray tube and a method for inspecting thermal distortion of an electron gun provided in the glass bulb.
The present invention relates to a method for inspecting a thermal distortion of a glass bulb and a method for inspecting a thermal distortion of an electron gun for detecting an excessive thermal distortion of a welded portion by measuring a temperature at a welded portion.

[0002]

2. Description of the Related Art A glass bulb constituting a cathode ray tube of a television receiver is formed in a substantially flask shape and has a narrow opening at one end. In the glass bulb, an electron gun for emitting an electron beam is provided on the narrow opening side. In this glass bulb, when the electron gun is provided, the narrow opening is closed by the connecting plate of the electron gun. That is, the electron gun disposed in the glass bulb has a connecting plate made of glass, and this connecting plate is joined to the narrow opening of the glass bulb. Then, by heating and welding the joined portion, the narrow opening of the glass bulb is closed, and the electron gun is arranged in the glass bulb.

[0003] In the glass bulb, some distortion occurs in the welded portion due to the heat during the glass welding. When the distortion due to heat exceeds a certain limit, the glass bulb is liable to crack at the welded portion. Therefore, it is necessary to remove a glass bulb having a thermal strain exceeding a certain limit from the production line of the television receiver as a defective product so as not to incorporate the glass bulb into the television receiver.

An electron gun disposed in a glass bulb has a molten glass extending around a dimet line connecting an internal terminal connected to a cathode and a grid electrode and an external terminal connected to a color signal input circuit. By welding, the above-mentioned connecting plate is formed. Also, in this electron gun, as in the case of welding a glass bulb, some distortion occurs in the welded portion due to heat during glass welding. In the electron gun, when the distortion due to heat exceeds a certain limit, cracks are likely to occur in the welded portion. Therefore, it is necessary to remove the electron gun having such a thermal strain exceeding a certain limit from the production line of the television receiver as a defective product so that it is not disposed in the glass bulb.

Therefore, conventionally, a process of removing defective products from the production line of the television receiver by inspecting the state of thermal distortion of the glass bulb and the electron gun has been performed.

For example, a sample for strain measurement is prepared,
The thermal strain of this sample is measured using a polarimeter. Then, a method has been adopted in which the conditions of a heating device constituted by a gas burner or the like are set on the basis of the measured data on the amount of thermal strain, thereby controlling the process.

A sample for measuring strain is prepared, and a thermocouple is attached to a welded portion of the sample to measure a welding temperature at the welded portion. Then, based on the data of the amount of thermal strain calculated from the welding temperature, by setting the conditions of the heating device constituted by a gas burner or the like,
A method for performing process control is also known.

[0008]

Incidentally, excessive thermal distortion of the glass bulb and the electron gun may be caused by a sudden malfunction of a gas burner or the like constituting a heating device.
However, the process control method described above is a process control based on sample measurement and not 100% control, so that it is possible to detect excessive thermal distortion in a glass bulb and an electron gun caused by a sudden malfunction of a gas burner or the like. Can not. Therefore, in the conventional method of process control, a glass bulb and an electron gun that have excessive thermal strain and may cause cracks are overlooked, mounted on a production line as they are, and incorporated into a television receiver, There was a risk of being shipped as a product.

Further, the process management by sample measurement requires a skillful technique in setting conditions and the like, and has a problem that the operation is complicated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for inspecting thermal distortion, which makes it possible to control the total number of glass bulbs and electron guns and to detect excessive thermal distortion of glass bulbs and electron guns reliably and easily. .

[0011]

In order to achieve the above object, a method for inspecting the thermal distortion of a glass bulb according to the present invention comprises a glass bulb having a narrow opening at one end and being formed into a substantially flask shape. Is supplied into the heating device, and a non-contact radiation thermometer is installed in the heating device when the connection plate of the electron gun is welded to the narrow opening to seal the narrow opening. The excessive distortion of the welded portion is detected by measuring the temperature of the weld.

According to this inspection method, at the same time as the welding of the joint between the narrow opening of the glass bulb and the connecting plate of the electron gun, the temperature is measured by the non-contact radiation thermometer installed in the heating device. Since the inspection of distortion at the welded part is performed, it is possible to control the total number of manufactured glass bulbs, and it is possible to reliably detect excessive thermal distortion of the glass bulb caused by sudden malfunction such as gas burner. it can.

Further, according to the method for inspecting thermal distortion of an electron gun according to the present invention, an internal terminal connected to a cathode for emitting an electron beam and a grid electrode for controlling the electron beam is connected to the internal terminal via a dimet wire. An electron gun having an external terminal to be supplied is supplied into the heating device, and molten glass is welded around the periphery of the jimet wire to form a connection plate.
A non-contact radiation thermometer is installed in the heating device, and by measuring the temperature of the welded portion, excessive distortion of the welded portion is detected.

According to this inspection method, the connecting plate is formed from the molten glass around the dimet line of the electron gun, and at the same time, the distortion at the welded portion is measured by measuring the temperature of the non-contact radiation thermometer installed in the heating device. Is performed, the total number of electron guns manufactured can be controlled, and excessive thermal distortion of the electron gun caused by a sudden malfunction of a gas burner or the like can be reliably detected.

[0015]

Embodiments of the present invention will be described below in detail with reference to the drawings.

A glass bulb 1 constituting a cathode ray tube of a television receiver, as shown in FIG. 1, for example, has a property of blocking X-rays so that it does not become dark brown even with collision of an electron beam due to high voltage acceleration. Made of excellent lead glass etc.
It is formed so as to have a substantially flask shape as a whole.

The glass bulb 1 has a narrow opening 1a at one end, and an electron gun for emitting an electron beam is disposed on the narrow opening 1a. The narrow opening 1a of the glass bulb 1 is closed by a connecting plate of an electron gun, which will be described later, and the joint between the edge of the connecting plate and the opening end of the narrow opening 1a is heated. , And the narrow opening 1a is sealed.

The glass bulb 1 has a wide-opening 1b at the other end, and a panel glass (not shown) is attached to the wide-opening 1b so that an image is projected on the panel glass. I have.

The electron gun 2 emits an electron beam toward the panel glass based on the color signal output from the color signal output circuit. For example, as shown in FIG. And a plurality of grid electrodes G ₁ , arranged on a coaxial line at predetermined intervals to control, accelerate, and focus an electron beam emitted from the cathode 3.
G ₂ , G ₃ , and G ₄ . The plurality of grid electrodes G ₁ , G ₂ , G ₃ , G ₄ are respectively engaged with an insulating support rod 4 made of glass or the like, and are integrally connected.

[0020] The electron gun 2 has an internal terminal 5 of the plurality of which is connected to the cathode 3 and the first grid electrode G ₁ and the like. The internal terminal 5 is connected to an external terminal 6 connected to a color signal input circuit (not shown) via a dimet line 7 having a thermal expansion coefficient close to that of glass.

Further, the electron gun 2 is provided with a connection plate 8 formed in a flat plate shape using glass as a material over the periphery of the Zimette wire 7. That is, the connection plate 8 is provided with the jimet wire 7 connecting the internal terminal 5 and the external terminal 6. The Gimmet wire 7 has a coefficient of thermal expansion close to that of glass and is easily adapted to glass.
Even if provided, disconnection can be avoided.

In the electron gun 2, as shown in FIG. 3, the connecting plate 8 is connected to the narrow opening 1a of the glass bulb 1 described above.
Is disposed in the glass bulb 1 so as to close the glass bulb. And
Connecting plate 8 of electron gun 2 and narrow opening 1b of glass bulb 1
Is heated and welded, whereby the electron gun 2 and the glass bulb 1 are joined together,
The narrow opening 1a of the glass bulb 1 is sealed.

Incidentally, the sealing of the narrow opening 1a of the glass bulb 1 constructed as described above and the formation of the connecting plate 8 of the electron gun 2 are performed by, for example, joining portions in a heating device 10 as shown in FIG. Is performed by melting the glass and welding the joint portion. Then, the glass bulb 1 and the electron gun 2 are welded in the heating device 10 at the same time as the temperature of the welded portion is measured and excessive distortion in the welded portion is detected. I have.

The heating device 10 has a plurality of positions. In the present embodiment, 12 positions P
_{1, P 2, P 3,} P 4, P 5, P 6, P 7, P 8,
An example in which the heating device 10 including P ₉ , P ₁₀ , P ₁₁ , and P ₁₂ is used will be described. The first position P ₁ of these 12 positions is a charging position for charging the glass bulb 1 and the electron gun 2 into the heating device 10, and the second to fifth positions P ₂ , P ₃ , P ₄ , P ₅
Is a preheating position for preheating the glass bulb 1 and the electron gun 2. The position P ₆ of the sixth is indeed the main seal position to perform welding of the joint.

The seventh to eleventh positions P ₇ , P
₈ , P ₉ , P ₁₀ and P ₁₁ are annealing positions for gradually cooling the glass bulb 1 and the electron gun 2 to which the joints are welded, and a twelfth position P ₁₂ is for heating the glass bulb 1 and the electron gun 2 This is a takeout position for taking out from the inside of the apparatus 10.

A heating mechanism is provided at each of these positions other than the first position P ₁ and the second position P ₂ .

The heating mechanism 11 includes, for example, a gas burner 13 having a plurality of nozzles 12 as shown in FIG. The plurality of nozzles 12 are arranged such that all the outlets are directed to one point, and when the combustion gas is radiated from the outlets of the nozzles 12, these combustion gases are concentrated at one point. ing.

The heating device has a fifth position P ₅ , a sixth position P ₆ and an eleventh position P
_11, the radiation thermometer 14 in a non-contact type for measuring the temperature of the welded portion of the glass bulb 1 and the electron gun 2 is disposed.

The radiation thermometer 14 is a thermometer that senses the wavelength of the heat energy emitted from the object and calculates the temperature of the object from the wavelength. In this case, the measurement location is in the combustion gas (mainly CO ₂ ) of the gas burner 13, the object is a transparent glass, and the measurement range is a limited range of the welded portion. 6 μm
It is desirable to use a radiation thermometer whose front and rear infrared rays are used and whose measurement range is φ5 mm or less. In the present embodiment, the trade name: Thermo-Meter. SHG5
(Made by OPTEX Co., Ltd.).

The radiation thermometer 14 has an alarm device 1
5 is connected, and when the radiation thermometer 14 detects a temperature outside a predetermined range, the alarm device 15 issues an alarm. Then, by the alarm issued by the alarm device 15, the occurrence of excessive distortion of the welded portion of the glass bulb 1 or the electron gun 2 can be sequentially confirmed.

Next, the heating apparatus 1 configured as described above
Next, a method of supplying the glass bulb 1 and the electron gun 2 to each other and performing welding and distortion detection at the joint will be described.

First, the electron gun 2 is supplied to the heating device 10,
While connecting the molten glass to form the connecting plate 8,
A method for detecting excessive thermal strain at the welded portion will be described.

The electron gun 2 includes a cathode 3 and a grid electrode G.
₁ , G ₂ , G ₃ , G ₄ , and G ₅ , a main body portion, an internal terminal 5 and an external terminal 6 connected via a jimet wire 7, and a glass member forming a connecting plate 8. in state, it is introduced into the heating device 10 from the first position P _1. Then, the second to fifth positions P ₂ ,
At P ₃ , P ₄ , and P ₅ , preheating is applied to the glass member forming the connecting plate 8.

[0034] Then, the heated glass member, at positions P ₅ of the fifth, the temperature of the heating portion is measured by the radiation thermometer 14. At this time, if the temperature of the heating part is too low, the sixth seal, which is the main seal position thereafter.
There is a high possibility that the connecting plate 8 will be broken by heating at the position. On the other hand, if the temperature of the heated portion is too high, the thermal distortion of the welded portion becomes excessive and causes cracks. Therefore, when the temperature of the heating portion is out of the predetermined range, the alarm device 15 issues an alarm to notify that the preheating has not been properly performed.

Next, at a sixth position P ₆ , which is the main seal position, a predetermined portion of the glass member is melted, and a gymet wire 7 is formed at the molten portion of the glass member.
The internal terminal 5 and the external terminal 6 which are connected via the terminal are inserted. At this time, the internal terminal 5 and the external terminal 6 connected via the jimet wire 7 are inserted so that the jimet wire 7 is embedded in the glass member. This allows
The connecting plate 8 is formed around the circumference of the jimet wire 7.

[0036] Then, the end of the internal terminal 5 is connected to the cathode 3 and the first grid electrode G ₁ and the like of the main body portion, an electron gun 2 that is integrated is formed.

In the sixth position P ₆ of the electron gun 2, the temperature of the melting point is measured by the radiation thermometer 14. At this time, if the temperature of the melting point is too low, the welding becomes incomplete and causes cracks. On the other hand, if the temperature of the melting point is too high, the glass of the connecting plate 8 is dripped, and the connection between the connecting plate 8 and the Gimmet wire 7 becomes poor. Therefore, when the temperature of the melting point is out of the predetermined range, the alarm device 15
Alerts the user that the welding was not performed properly.

Next, at the seventh to eleventh positions P ₇ , P ₈ , P ₉ , P ₁₀ and P ₁₁ of the electron gun 2, the welded portions are gradually cooled. The electron gun 2 also in position P ₁₁ of the first 11, the temperature of the molten portion is measured by the radiation thermometer 14. Here, if the temperature of the melting point is too low, the thermal distortion of the welded portion becomes excessive and causes cracks. Also, when the temperature of the melting point is too high, the thermal distortion of the welded portion becomes excessive similarly, which causes cracking. Therefore, when the temperature of the melting point is out of the predetermined range, the alarm device 15 issues an alarm to notify that the cooling has not been properly performed.

In the process in which the electron gun 2 passes through the heating device 10, if any of the alarm devices 15 does not issue an alarm, it is recognized that the distortion value of the welded portion of the electron gun 2 is within an appropriate range. . Then, the electron gun 2 in which the value of the distortion of the welded portion is within an appropriate range is used in the subsequent process.
It is arranged in. On the other hand, when the alarm device 15 issues an alarm while the electron gun 2 passes through the inside of the heating device 10, the electron gun 2 is removed from the television receiver manufacturing line and is handled as a defective product.

Next, the electron gun 2 in which the glass bulb 1 and the connecting plate 8 are formed is supplied to the heating device 10, and the opening end of the narrow opening 1 a of the glass bulb 1 is joined to the edge of the connecting plate 8. A method of melting the portion, sealing the narrow opening 1a of the glass bulb 1 with the molten glass, and detecting excessive thermal distortion in the welded portion will be described.

The electron gun 2 glass bulb 1 and the coupling plate 8 is formed, it is introduced into the heating device 10 from the first position P _1. Then, in the second to fifth positions P ₂ , P ₃ , P ₄ , and P ₅ , preheating is applied to the joint between the opening end of the narrow opening 1 a of the glass bulb 1 and the edge of the connecting plate 8. .

[0042] Then, the heated junction, in position P ₅ of the fifth, the temperature of the heating portion by a radiation thermometer 14 is measured. At this time, if the temperature of the heating part is too low, the sixth seal, which is the main seal position thereafter.
Due to the heating at the position, there is a high possibility that the joint between the opening end of the narrow opening 1a of the glass bulb 1 and the edge of the connecting plate 8 is broken. On the other hand, if the temperature of the heating point is too high,
Excessive thermal distortion of the welded portion causes cracks to occur. Therefore, when the temperature of the heating portion is out of the predetermined range, the alarm device 15 issues an alarm to notify that the preheating has not been properly performed.

Next, at the sixth position P ₆ , which is the main seal position, the joint between the opening end of the narrow opening 1 a of the glass bulb 1 and the edge of the connecting plate 8 is melted, and the molten glass is used to melt the glass. The narrow opening 1a of the bulb 1 is sealed, and the electron gun 2 is disposed in the glass bulb 1.

The narrow-mouthed glass bulb 1 in which the opening 1a is sealed, at the position P ₆ of the sixth, the temperature of the welded portion is measured by the radiation thermometer 14. At this time, if the temperature of the melting point is too low, the welding becomes incomplete and causes cracks. On the other hand, if the temperature of the melting point is too high, the glass at the bonding portion is dripped, and the bonding between the opening end of the narrow opening 1a of the glass bulb 1 and the edge of the connecting plate 8 becomes poor. Therefore, when the temperature of the melting point is out of the predetermined range, the alarm device 15 issues an alarm to notify that the welding has not been properly performed.

Next, the glass bulb 1 in which the narrow opening 1a is sealed is moved to the seventh through eleventh positions P ₇ ,
At P ₈ , P ₉ , P ₁₀ , and P ₁₁ , the welded portion is gradually cooled. Glass bulb 1 is also in the position P ₁₁ of the first 11, the temperature of the welded portion is measured by the radiation thermometer 14. Here, if the temperature of the melting point is too low, the thermal distortion of the welded portion becomes excessive and causes cracks. Also, when the temperature of the melting point is too high, the thermal distortion of the welded portion becomes excessive similarly, which causes cracking. Therefore, when the temperature of the melting point is out of the predetermined range, the alarm device 15
Alerts that the cooling was not performed properly.

In the process where the glass bulb 1 passes through the heating device 10, if any of the alarm devices 15 does not give an alarm, the welding portion between the narrow opening of the glass bulb 1 and the connecting plate 8 of the electron gun 2 is used. It is recognized that the value of the distortion at is within an appropriate range. Then, the electron gun 2 in which the value of the distortion of the welded portion is within an appropriate range is disposed in the casing of the television receiver in a subsequent process. On the other hand, when the glass bulb 1 passes through the heating device 10, the alarm device 15
When an alarm is issued, the glass bulb 1 is removed from the production line of the television receiver because the glass bulb 1 has excessive distortion and may cause cracks,
Treated as defective.

According to such a method of measuring thermal strain, the detection of thermal strain is performed simultaneously with the glass welding, and the occurrence of excessive strain can be immediately known. Management can be performed, and the production of defective products due to sudden malfunction of the gas burner 13 is not overlooked.

[0048]

According to the method for inspecting thermal distortion of a glass bulb according to the present invention, the joint between the narrow opening of the glass bulb and the connecting plate of the electron gun is welded, and at the same time, the detection of excessive thermal distortion of the welded part is performed. Since it is performed, the total number of glass bulbs can be managed. Therefore, the risk of overlooking the glass bulb having excessive thermal distortion and the incorporation of this glass bulb into a television receiver can be avoided in advance.

In the method for inspecting thermal distortion of an electron gun according to the present invention, since a molten glass is fused to form a connecting plate, and at the same time, excessive thermal distortion of a welded portion is detected, the total number of electron guns can be controlled. It can be performed. Therefore, the danger of overlooking the electron gun having excessive thermal distortion and disposing the electron gun in the glass bulb can be avoided in advance.

[Brief description of the drawings]

FIG. 1 is a side view of a glass bulb.

FIG. 2 is a side view of the electron gun.

FIG. 3 is a cross-sectional view of a glass bulb provided with an electron gun.

FIG. 4 is a schematic view of a heating device.

FIG. 5 is a schematic diagram of a heating mechanism.

[Explanation of symbols]

1 glass bulb, 1a narrow opening, 2 electron gun, 3
Cathode, 5 internal terminal, 6 external terminal, 7 dimet wire, 8 connecting plate, 10 heating device, 14 radiation thermometer, 15 alarm device

Claims (8)

[Claims] 1. A glass bulb having a narrow opening at one end and formed into a substantially flask shape is supplied into a heating device.
In welding the connecting plate of the electron gun to the narrow opening and sealing the narrow opening, a non-contact radiation thermometer is installed in the heating device to measure the temperature of the welded portion. Inspection method for thermal distortion of glass bulb by detecting excessive distortion of welded part. 2. The method according to claim 1, wherein the radiation thermometer uses an infrared ray having a wavelength of about 6 μm and has a measurement range of φ5 mm or less. 3. The heating device has a plurality of heating mechanisms,
2. The method according to claim 1, wherein the temperature is measured by a plurality of heating mechanisms. 4. The method according to claim 1, wherein an alarm device issues an alarm when a temperature abnormality is detected in the welded portion. 5. An electron gun having an internal terminal connected to a cathode for emitting an electron beam and a grid electrode for controlling the electron beam, and an external terminal connected to the internal terminal via a dimet wire, is placed in a heating device. Supplying and forming a connecting plate by fusing the molten glass around the perimeter of the dimet wire, installing a non-contact radiation thermometer in the heating device, and measuring the temperature of the welded portion, Method for inspecting thermal distortion of electron guns to detect excessive distortion. 6. The method according to claim 5, wherein the radiation thermometer uses infrared rays having a wavelength of about 6 μm and has a measurement range of φ5 mm or less. 7. The heating device has a plurality of heating mechanisms,
6. The method according to claim 5, wherein the temperature is measured by a plurality of heating mechanisms. 8. The method according to claim 5, wherein an alarm device issues an alarm when a temperature abnormality is detected in the welding portion.