KR880003370Y1 - Cathode for high resorution cathode ray tube - Google Patents

Abstract

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Description

Cathode Structures for High-Definition TVs

1 is a state diagram of a conventional fast-moving cathode structure installation.

Figure 2 is a longitudinal cross-sectional view of the negative electrode structure installation state of the present invention.

3 is a longitudinal cross-sectional view of a conventional negative electrode structure.

* Explanation of symbols for main parts of the drawings

1: heater 2: cathode sleeve

3: holder 4: cathode support

5: first electrode

The present invention relates to a cathode structure for a cathode ray tube of a high-definition TV, and improves the installation structure of the cathode structure so that the heat transfer of the heater is transmitted to the cathode sleeve and the cathode support almost simultaneously so that the image on the TV screen does not cause an initial change. It was devised for the purpose.

Referring to the conventional cathode mounting structure, as shown in FIG. To rise by a certain height (H) The fixed holder 3 'is fixed to the inside of the negative electrode support 4' while maintaining a constant distance between the negative electrode sleeve 2 'and the upper first electrode 5'.

By the way, since the fast cathode has a low speed load such as a low resolution television, it is only desired that the image appears on the screen quickly and to obtain a stable screen quickly. Therefore, the cathode sleeve 2 'is oxidized and blackened in a wet hydrogen furnace. An electron-spinning material was attached to the upper surface, and the heater 1 'inside the heater improved the thermal radiation efficiency by thinning tungsten, the material, and blackened the surface to achieve better heat emissivity, thereby providing a heater 1'. When the power is supplied, the rapid heating temperature rises in about 2 seconds and is transferred to the surrounding cathode sleeve 2 '. At this time, the transferred heat heats the electron emitting material to emit electrons. The heat of the sleeve 2 'is transferred through the holder 3' to the cathode support 4 'so that the cathode sleeve 2' first expands upward in the direction of the first electrode 5 '. The negative electrode support 4 'expands downward in the reverse direction of the expansion of the negative electrode sleeve 2', thereby achieving a balance between the negative electrode sleeve 2 'and the first electrode 5' in the initial design. .

Therefore, the shipping time, which is the time until the image appears on the screen, is advanced to about 5-6 seconds, and the shipping time is easily absorbed by the heat radiated from the heater 1 'by the blackening of the cathode sleeve 2'. Contributions to

In the conventional negative electrode structure, although the distance D between the negative electrode sleeve 2 'and the negative electrode support 4' was large at an interval of 0.6-0.8 mm, such a structure has a low load state such as a low resolution television. Is not a problem.

Because it takes a long time to expand in the direction of the first electrode 5 'of the cathode sleeve 2' when the heater 1 'is switched on, the change of the image brightness on the television screen is made very slowly. It doesn't matter.

However, with the advent of high-definition television, the overload condition occurs, and even in the structural changes around the cathode and the cathode, the expansion of the cathode sleeve occurs rapidly, and the change of the cathode support expands faster than that of the low resolution television, but the expansion of the cathode sleeve is changed. It is relatively slow compared to.

As a result, television screens are initially unstable and appear very bright at first, then sooner than the first.

This is because the distance between the first electrode and the cathode becomes closer when the cathode slip is first expanded, which increases the amount of electron radiation due to the theory of electron radiation, and the image of the television screen becomes bright, and then the distance between the first electrode and the cathode due to the expansion of the cathode support. As is returned to the normal state, the image on the screen becomes darker than the first and becomes stable.

Therefore, in order to solve the shortcomings of the initial instability of the screen occurring in high-definition television, the present invention narrows the gap between the cathode sleeve and the cathode support so that the expansion of the cathode sleeve and the expansion of the cathode support occur almost simultaneously. The initial value of is hardly caused to change as described in detail by the accompanying drawings as follows.

That is, in the fixed installation of the negative electrode sleeve 2 having the thinned heater 1 therein between the negative electrode support 4 to have a predetermined distance from the upper first electrode 5, the negative electrode support ( 4) the inner diameter of the cathode sleeve 2 is reduced to be slightly larger than the outer diameter of the cathode sleeve 2, and the cylindrical holder 3 having a predetermined length of 0.2 mm or less in thickness is inserted into and fixed to the lower peripheral portion of the cathode sleeve 2; After installation, the holder 3 is press-fitted into the inner lower end of the negative electrode support 4, so that the lower end of the negative electrode support 4 and the negative electrode sleeve 2 coincide with each other as a cylindrical holder 3 therebetween. It is fixedly coupled so that the distance d is kept below 0.2 mm.

Looking at the operating state of the present invention configured as described above are as follows.

When the heater (1) is turned on, the heat generated during instantaneous heating is quickly transferred to the cathode sleeve (2), and the heat is transferred to the electron emitting material at the top of the cathode sleeve (2) to generate electrons. It is also delivered to the cathode support 4 via the holder 3.

At this time, the negative electrode sleeve 2 receiving the heat from the heater 1 is expanded in the direction of the first electrode 5 (upward), and the contact portion of the holder 3 of the negative electrode support 4 is rapidly heated. By simultaneously expanding in the direction opposite to the expansion direction of the sleeve 2, the cathode sleeve 2 and the first electrode 5 will always be kept at a constant interval, the electromagnetic radiation amount by the electron radiation theory It remains constant so that the screen image is initially stabilized.

Therefore, the cylindrical holder 3 must be inserted into the lower portion of the inner wall of the negative electrode support 4, but only the contact portion received from the holder 3 with the instantaneous heat generated from the negative electrode sleeve 2 expands downward. The sleeve 2 is to be balanced with its own expansion, and the most ideal way is to contact the lower part.

Further, since the gap d between the negative electrode sleeve 2 and the negative electrode support 4 is designed to be 0.2 mm or less, heat transfer from the negative electrode sleeve 2 to the support 4 takes place in an instant. The expansion of the cathode sleeve 2 and the cathode support 4 takes place at about the same time.

In the present invention constructed and operated as described above, since the distance d between the negative electrode sleeve 2 and the negative electrode support 4 is designed to be narrow to 0.2 mm or less, the support 4 in the negative electrode sleeve 2 is provided. Since heat transfer to is performed in an instant, the expansion of the cathode sleeve 2 and the cathode support 4 takes place at about the same time.

The present invention constructed and operated as described above, the lower portion between the negative electrode sleeve 2 and the negative electrode support 4 is inserted into the mutually coupled cylindrical holder (3) having a thickness of 0.2mm or less, the heater ( The heat transfer of 1) is transferred to the lower portion of the cathode sleeve 2 and the cathode support 4 at substantially the same time, and they simultaneously expand in opposite directions to establish an initial design interval between the cathode sleeve 2 and the first electrode 5. There is an extraordinary effect of keeping it unchanged initially on the screen of a high-definition television.

Claims (1)

In the fixed installation of the negative electrode sleeve 2 having the thinned heater 1 therein between the first electrode 5 and the negative electrode support 4 so as to maintain constant shortness, the negative electrode support 4 is fixed. While forming the inner diameter of the slightly larger than the cathode sleeve (2), inserting a cylindrical holder (3) having a predetermined height of 0.2 mm or less in thickness at the lower end of the outer peripheral surface of the cathode sleeve (2), and then holder (3) to the cathode A negative electrode structure for a high-definition television, characterized in that it is press-fitted into the lower end of the support 4 to fix the gap d between the cathode sleeve 2 and the support 4 to be 0.2 mm or less.