US3922049A - Method of degassing a cathode-ray tube prior to sealing - Google Patents

Abstract

A method for making a cathode-ray tube including baking the envelope and mount assembly and simultaneously exhausting gases from the envelope, and then sealing (tipping off) the exhausted envelope. During the baking and exhausting of the tube, the following steps are carried out first sequentially and then simultaneously: (a) applying radio-frequency energy to the mount assembly and (b) passing electric current through the cathode heater.

Description

United States Patent 11 1 Sawicki 1 Nov. 25, 1975 METHOD OF DEGASSING A CATl-lODE-RAY TL'BE PRIOR TO SEALING Primary E.\'u111111erRoy Lake Assistant E.\uminer.lames W. Davie 75 I 1 Imamor gz Smnle Sawlckl' Scranton Attorney, Age/1L or FirmG. H. Bruestle; L.

I Greenspan {73] Assignee: RCA Corporation, New York, NY.

[22] Filed: Mar. 25, I974 [57] ABSTRACT [31] A L N 454 153 A method for making a cathode-ray tube including baking the envelope and mount assembly and simultaneously exhausting gases from the envelope. and then [52] S f, 6/19; 316/30 sealing (tipping off) the exhausted emelope. During i511 9/18 the baking and exhausting of the tube. the following 8] field Search 316/]71 steps are carried out first sequentially and then simul 3l6/30- 13 53/88 taneously: (a) applying radio-frequency energy to the mount assembly and (b) passing electric current [56] References and through the cathode heater.

UNITED STATES PATENTS 4 CM 1 D F 2.532.315 12/1950 Johnson ct al 316/30 rawmg 'gure l2lll098765432lllllll l3 A C l4 l5 l6 l7 l8 l9 20 El 22' 23 24 25 26 27 28 P08. lO-I8 2 P0335-42 POS.

POS.24-28 METHOD OF DEGASSING A CATI-IODE-RAY TUBE PRIOR TO SEALING BACKGROUND OF THE INVENTION This invention relates to a noveLmethod for degassing a cathode-ray tube, particularly the mount-assembly structures thereof, during the simultaneous exhausting and baking steps for making the tube. prior to sealing the tube.

In fabricating a cathode-ray tube. a luminescent screen and various conductive coatings are applied to various internal surfaces of the envelope which includes a neck portion. A mount assembly, supported on a glass stem and including the electron gun or guns, is sealed into the neck portion of the tube. The tube, which is open to the atmosphere through a glass tubulation connected to the stem. is baked at about 300 to 450C and is simultaneously exhausted to a relatively low pressure. Then, the tube is tipped off; that is, the tubulation is sealed. Apparatus for carrying out this process is described in the prior art; for example, U.S. Pat. No. 2,532,3l5 to M. E. Johnson et al and U.S. Pat. No. 3,115,732 to I. F. Stewart.

Near the end of the baking and exhausting cycle and prior to tipping off, radio-frequency energy at about l.0 to l.5 magahertz is applied to the mount assembly to degas the mount structures by heating. Then, electric current is passed through the cathode heater to heat the cathode to decompose the cathode coating material and to degas the cathode structure. It has been suggested to perform these latter two steps either sequentially or simultaneously. Each of the sequential and simultaneous orders of processing has disadvantages. Sequential application of radio-frequency energy and heater current does not produce tubes having the highest cathode emission characteristics. Simultaneous application of radio-frequency energy and heater current frequently results in an increase in the proportion oftubes that is rejected for unsatisfactory performance.

SUMMARY OF THE INVENTION In the novel method, radio-frequency energy and heater current are first applied sequentially and then are applied simultaneously to the mount assembly and cathode heater respectively during the simultaneous baking and exhausting steps prior to sealing. The initial sequential processing performs the previous functions of degassing the structures and decomposing the cathode coating. The subsequent simultaneous processing raises the temperatures of all the structures above 450C to again outgas them but in a manner that prevents redeposition of materials released from other structures. As a result, the finished tubes exhibit higher emission currents from the cathodes and there is a high yield of satisfactory tubes.

BRIEF DESCRIPTION OF THE DRAWING The sole FIGURE is a schematic plan view of an apparatus for practicing the novel method showing the relative locations of the heating zones and the process ing positions.

DETAILED DESCRIPTION OF THE INVENTION The invention may be practiced in the continuous apparatus disclosed in U.S. Pat. No. 2,532,315 to M. E. Johnson et al. The apparatus shown in the sole FIG- URE is similar to the apparatus described in the Johnson et al patent; however, the apparatus employs the improved cart disclosed in U.S. Pat. No. 3.1 15,732 to J. F. Stewart. The apparatus shown in the sole FIGURE comprises a train of carts A moving counter clockwise along a closed, elongated loop. A tunnel oven B of a generally U-shaped plan is located over a portion of the train of carts in a manner to enclose the tubes being processed. The tunnel is divided into 28 zones that are numbered I through 28. Except for zones 13 and 14, the zones are straight and of equal length of about 10 feet. Bus bars delivering electrical energy for processing the tubes are located along zones 15 through 24 and are divided into processing positions C numbered 1 through 42. The processing positions are each about 28 inches in length.

A sequence of 25 V-size color television picture tubes (assembled but not yet exhausted and sealed) is loaded successively, one tube to a cart, onto the train of carts A passing continuously into and through the tunnel oven B of this apparatus at the rate of about 54 to carts per hour. Each tube includes an envelope having a faceplate, a funnel portion, and a glass-neck portion. The neck portion is closed at one end by a glass stem having metal stem leads and a glass tubulation extending outwardly therefrom. The metal stem leads also extend inwardly and support the mount assembly of the tube. The mount assembly includes the electron guns of the tube. Each gun includes an indirectly heated thermionic cathode having a heated side and an emitting side, a cathode heater spaced from the heated side of the cathode, and a grid (GI) spaced from the emitting side of the cathode. The tubulation is connected to equipment for exhausting the tube of gas, and the stem leads are connected so that a current may be passed through the cathode heater. A coil is disposed about the neck so that radio-frequency energy may be applied to the mount assembly of the tube.

Each cart passes through the tunnel oven B in about two to three hours. The temperatures of the zones increase from about room temperature (at zone 1) to about 440C (at zone 11) and then decrease to about C (at zone 28). During most of the transit through the oven B (zones 1 to 25), pumps are removing gas from the interior of each tube through the exhaust tubulation extending from the stem that is sealed into the tube neck. Starting at zone 17 (processing positions 10 through 18), radio-frequency energy at about 1.0 to L5 megahertz is applied to the mount assembly according to the schedule in the TABLE. No radiofrequency energy is applied at processing positions 19 through 23. However, a cathode-heater current of about 1.] amp is passed through the cathode heaters with an applied voltage of about 12.0 volts dc at position 23. The applied voltage is higher than the normal operating voltage of about 6.3 volts, and causes the cathode temperature to rise about to 250 C above the normal operating temperatureof about 800C. At processing positions 24 through 28, both radiofrequency energy and cathode-heater current are applied simultaneously to the mount assembly and the cathode heaters respectively according to the schedule in the TABLE. The heating effect on the cathode, on grid No. 1 (GI) and grid No. 3 (G3) of the tube at the various positions is also shown in the TABLE. At positions 29 to 34, heat is applied to melt a portion of the tubulation and to seal (tip-off) the tube interior from the atmosphere.

The prior factory process follows the schedule shown in the TABLE except that the radio-frequency energy (rf) and the cathode heater current (If) are both zero at positions 24 through 28. This permits the temperature of the cathode, ofGl, and of G3, to drop continuously to about 200C at position 28 (in zone 2| Contrary to this, in the novel method, the simultaneous application of radio-frequency energy and cathode-heater current at positions 24 through 28 raises the temperature of the cathode and the grid No. 1 above 450C, and preferably above 600C. This additional high-temperature heating is believed to clean and degas the surfaces of the various structures without causing lifting of the coating on the cathode. Results have shown an increase in cathode-emission current in the finished tubes of about 8 percent, and a reduction of reject tubes due to lifted cathode coatings and other causes, as compared with the prior process which employs only the sequential application of radio-frequency energy and cathodeheater current.

While the above example employs a particular schedule on a particular cathode-ray-tube type and on a particular machine, the novel method is not limited to any of these. The method may be practiced with different schedules and various tubes and on a variety of machines. For example, the invention may be practiced on a stationary machine with periodic tube processing. However, the novel method does require first the sequential application of radio-frequency energy and cathode-heater current, followed by the simultaneous application of both radio-frequency energy and cathode-heater current to the mount assembly and cathode heater respectively, and preferably is conducted for at least 2 minutes.

TABLE Position rt ll TC TC TC Amps Amps Cathode GI G3 7.0 0 200 300 250 l l 7.0 0 260 400 325 12 7.0 0 320 450 375 13 7.0 0 380 475 425 M 7.0 0 420 500 475 15 9.0 0 420 575 505 to 9.0 0 480 575 575 I7 l2.5 0 560 750 625 I8 l2.5 0 640 770 675 I9 0 0 560 550 600 0 0 480 500 525 21 0 0 400 450 450 22 0 0 320 400 375 23 0 1.1 950 350 300 24 9.0 0.8 850 525 440 25 9.0 0.8 860 $70 480 26 9.0 0.8 870 600 520 27 9.0 0.8 880 620 560 28 9.0 0.8 890 640 560 29 0 0 400 480 420 30 0 0 320 380 350 I claim:

1. In a method for making a cathode-ray tuhe comprising an envelope and a mount assembly including at least one cathode and a heater therefor sealed in said envelope, said method including the steps of baking said envelope and mount assembly at about 300 to 450C and simultaneously exhausting gases from said envelope and then sealing said envelope,

the steps during said baking and exhausting of said envelope comprising first l sequentially and then (2) simultaneously (a) applying radio-frequency energy to said mount assembly and (b) passing electric current through said heater, whereby said simultaneous application step (2) heats said mount assembly including said cathode above 450C.

2. The method defined in claim I wherein said simultaneous step (2) is conducted for at least 2 minutes.

3. In a method for making a cathode-ray tube comprising an envelope having a neck portion, a mount assembly sealed in said neck portion, said mount assembly including at least one indirectly-heated thermionic cathode having an emitting side and a heated side. a grid spaced from said emitting side of said cathode and a heater spaced from the heated side of said cathode, and an exhaust tubulation extending from said envelope,

said method including the steps of baking said envelope and mount assembly at about 300 to 450C. simultaneously exhausting gases from inside said envelope through said exhaust tubulation and, in sequence during said baking and exhausting steps:

a. applying radio-frequency energy to said mount assembly to heat the metal parts thereof above 450C.

b. removing said radio-frequency energy,

c. passing electric current through the heater of said mount assembly to heat the cathode thereof above 450C then simultaneously passing electric current through said heater and applying radio-frequency energy to said mount assembly to heat both said cathode and the metal parts of said mount assembly above 450C,

e. removing said simultaneously applied electric current from said heater and radio-frequency energy from said mount assembly, and

f. sealing off said exhaust tubulation envelope to seal the interior of said tube from the ambient.

4. The method of claim 3 wherein said simultaneous application step (d) heats said grid and said cathode above 600C.

Claims (4)

1. In a method for making a cathode-ray tube comprising an envelope and a mount assembly including at least one cathode and a heater therefor sealed in said envelope, said method including the steps of baking said envelope and mount assembly at about 300* to 450*C and simultaneously exhausting gases from said envelope and then sealing said envelope, the steps during said baking and exhausting of said envelope comprising first (1) sequentially and then (2) simultaneously (a) applying radio-frequency energy to said mount assembly and (b) passing electric current through said heater, whereby said simultaneous application step (2) heats said mount assembly including said cathode above 450*C.

2. The method defined in claim 1 wherein said simultaneous step (2) is conducted for at least 2 minutes.

3. In a method for making a cathode-ray tube comprising an envelope having a neck portion, a mount assembly sealed in said neck portion, said mount assembly including at least one indirectly-heated thermionic cathode having an emitting side and a heated side, a grid spaced from said emitting side of said cathode and a heater spaced from the heated side of said cathode, and an exhaust tubulation extending from said envelope, said method including the steps of baking said envelope and mount assembly at about 300* to 450*C, simultaneously exhausting gases from inside said envelope through said exhaust tubulation and, in sequence during said baking and exhausting steps: a. applying radio-frequency energy to said mount assembly to heat the metal parts thereof above 450*C, b. reMoving said radio-frequency energy, c. passing electric current through the heater of said mount assembly to heat the cathode thereof above 450*C, d. then simultaneously passing electric current through said heater and applying radio-frequency energy to said mount assembly to heat both said cathode and the metal parts of said mount assembly above 450*C, e. removing said simultaneously applied electric current from said heater and radio-frequency energy from said mount assembly, and f. sealing off said exhaust tubulation envelope to seal the interior of said tube from the ambient.

4. The method of claim 3 wherein said simultaneous application step (d) heats said grid and said cathode above 600*C.

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