DE1462936A1 - Color picture tubes - Google Patents

Description

Patent and utility model auxiliary application

Applicant: Radio Corporation of America New York, N. Y., V. St. A.

The invention is concerned with improvements to color picture tubes and other (e.g. camera, radar and stereo) Cathode ray tubes which have a mask or shadow mask electrode provided with many openings which the radiation electrons on their way to the electron-sensitive, mosaic-like impact surface of the fly through nearby screen.

In the case of cathode ray tubes of the kind discussed here, the accuracy with which the electrons pass each depends Elementary areas of the screen depend to a large extent on the accuracy with which the shadow mask openings are aligned with the elementary surfaces of the screen during operation of the tube. at

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a color picture tube can accordingly, if the shadow mask due to thermal influences caused by the impact of the electron beam or beams on the shadow mask should expand the resulting misalignment between the shadow mask openings and the elementary colored areas cause the or some of the beam electrons to hit other elementary Color surfaces hit than what they actually hit should hit.

In the American patent 2,795 I'M by Morrell, a movable attachment of the shadow mask within the tubular piston is proposed to compensate for the thermal expansion of the shadow mask, which attachment consists of three supports connected to the periphery of the shadow mask, which are mounted on inclined guides attached to the tube piston slide. In American patent 2,795 to Van Hekken et al. suggests the use of a plurality of flexible joints which connect the shadow mask to a support frame, or a rotatably mounted toggle lever which has arms which slide on the shadow mask. These compensators are primarily intended for use with circular shadow masks in round tubes of moderate size and moderate deflection angle.

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The amount of misalignment (or misalignment) of the openings as a result of thermal expansion of the shadow mask is actually so small in round 21 inch color picture tubes with a deflection angle, e.g. the tube EOA 21FB22-A, that it can be permitted, which is why there is no temperature compensation at the moment is provided. However, the problem becomes more serious with 90 ° tubes, such as the 19EYP22 and 25 AP22A tubes, as these have a greater deflection and are rectangular in shape. In the color picture tube ROA 25AB22A, a rectangular shadow mask made of cold-rolled steel is arranged in a rectangular tube cap by means of animal leaf springs, the leaf springs each being welded with one end to one side of the shadow mask frame and at their other end a hole with which they are connected to a pin are on the cap of the Röhrenkolbdns engaged (so that the shadow mask can be removed in order to be able to successively apply the three sets of different color-emitting phosphor dots according to the usual ⁿ Leuehtturm "method). the amount of radial misalignment of the electron beam spots relative to The desired elementary fluorescent color, caused by the thermal expansion of the shadow mask during operation of the tube, is between 25 and 51 microns on a circle of about 18 cm radius in this tube with a larger deflection angle are not satisfactory.

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The invention is based on the object of a new and improved device for compensating the thermal To create expansion of the shadow mask of a cathode ray tube

According to one embodiment of the present invention, this is achieved by the fact that the shadow mask electrode .within the bulb and close to the Attaching the mosaic or grid screen using a new flexible fastening device · The new fastening device comprises a leaf spring which is positively connected to the tubular piston and the shadow mask electrode and which is designed in such a way that it moves in response to the heat generated by electron bombardment of the tape of the shadow mask both in the direction of the screen and outwards causes · The command? fastening device is designed in such a way that the movement of the shadow mask is sufficient takes place to the shadow mask openings during operation of the tube substantially in alignment with the To hold elementary surfaces of the screen · Preferably, the leaf spring is detachably attached to the tubular piston, so that they are quickly removed and between successive shielding operations in the manufacture of the tube can be quickly re-installed with rectangular picture tubes, preferably four fastening devices

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Services provided for temperature compensation of the shadow mask, each near the center of a the sides is arranged · However, a three-point attachment is also described, which provides temperature compensation in two different directions.

According to a further embodiment of the present invention, the object of the invention can also be achieved in this way that one attaches the shadow mask in the ear flask and near the hurry screen by means of a device, which comprises a base plate made of bimetallic sheet having two substantially flat fastening sections which are connected by an expansion bracket, one of the fastening sections being connected to the shadow mask; the device further comprises an elongated leaf spring which has one end on the height piston and at the other end is connected to the other fastening section. The leaf spring is preferably releasably attached to the tube piston so that the shadow mask can be quickly removed and between the successive shielding operations during the manufacture of the tube can be reinstalled used, with one at or near the center point of each side

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The invention is described below with reference to several examples shown in the drawing, in which demonstrate:

Fig. 1 in a longitudinal section along the line 1-1 in Fig. 2 a rectangular three-beam and Three-color picture tube with shadow mask and screen provided with fluorescent dots, their curved shadow mask according to the various embodiments of the - ^ invention is stored;

FIG. 2 shows a section along the line 2-2 in FIG. 1; FIG.

! ig · 3 shows an embodiment in an enlarged axial section the shadow mask attachment device according to Fig. 1;

4 · in a side view, partially in section along the line 4-4 · in FIG. 3 _t the fastening device according to FIG

FIG. 5 in a representation similar to that in FIG. 4. an embodiment modified from this. ;

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Fig. 6 is a bottom view of the embodiment

FIG. 7 shows a bar position similar to FIG. 3 another * embodiment;

8 in side view, partly in section according to FIG the line 8-8, the fastening device of Figure 7;

FIG. 9 shows, in a view similar to FIG. 8, an embodiment modified with respect to this;

10 shows a further embodiment in a representation similar to FIG

Fig. 11 is a bottom plan view of the embodiment see Fig. 10;

Fig. 12 is a side view similar to Fig. 11

compared to this modified embodiment;

13 shows, in a view similar to FIG. 5, a modification of the embodiment according to FIG. 12;

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FIG. 14 shows a rectangular section in a section similar to FIG. 2 color picture tube with a three-point mounting the shadow mask according to the present invention;

15 in a view similar to FIG. 4 to one of the Shadow mask fastening devices according to FIG. 14t

16 shows, in an enlarged axial section along the line 16-16 in # Fi _{g #} 18, a further embodiment of the shadow mask fastening device according to FIG. 1;

17 in a side view, partly in section according to the line 17-17 in FIG. 18, the fastening device according to FIG. 16;

FIG. 18 is a ^B odenansicht of the fastening device in FIGS · 16 and 17;

19 is a diagram showing the x & diale distortion of the Shadow mask electrode during the heating time of the tube according to FIGS. 1, 2 and 16-18 shows; and the

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20, 21 and 22 show a modified form of a top view, front view and side view Mounting plate.

Figs. 1 and 2 show a color picture tube rom a shadow mask type which has an evacuated glass bulb 1 with a Has longitudinal axis X-X which runs through the neck 3 and the funnel-shaped portion 5 of the piston. at this picture tube is of the tube type with "hole mask covering the impact surface of a screen provided with fluorescent dots", in which red, blue and green fluorescent dots 6 in a mosaic-like cough on the back or impact surface 7 of one Screen glass plate 9a are attached, which in the present case is the end face or the window the drilling forms · The impact surface 7 can have any suitable shape (circular or pike-corner shape) and curvature (ζ · Β · spherical or cylindrical) · In the drawing, the impact surface 7 is considered to be essentially rectangular section from a spherical surface shown. The screen glass plate 9a forms the main part of a cup-shaped piston cap 9 »which with its Side wall 9b tightly with the funnel-shaped section 5 connected is·

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The cover electrode 10, which is provided with openings, for the grid screen 6 comprises a high mask 11, which is preferably consists of a thin (e.g. 0.1 to 0.2 mm) metal part (e.g. pluck, nickel, iron or steel) "which has a positive temperature expansion coefficient. Cold rolled steel is used because of its low cost and its strength properties preferred · Alternatively The perforated mask 11 can also consist of a glass provided with holes, which on one or both main surfaces is made conductive by metallization. The perforated mask 11 corresponds to the contour of the spherical Impact surface 7 curved. However, the distance between the perforated mask 11 and the impact surface 7 on the outer Edge portions of the screen be smaller than in its central portions, so, as with the American Patent 5,109,116 by Epstein et al., Radiation deviations causing degrupping due to dynamic convergence be compensated. The shadow mask 11 has a substantially rectangular shape, which is similar but somewhat is smaller than that of the impact area, and is on the provided most of its area with numerous holes 11a. The shadow mask 11 is integral with an axial directed outer edge 11b formed, which over an axially directed Plansch 12a of a substantially rectangular, is pushed over in cross-section L-shaped metal frame 12 and welded to this. Preferably

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the frame 12 is also made of cold-rolled steel. The thickness of the two flanges of the perforated mask frame 12 is normally at least ten times the bead of the perforated mask 11, so that an appropriate support is provided for this still described.

The radiation electrons for activating the different colored fluorescent spots of the screen 6 are from a three electron beam generator 13 supplied, the is arranged in the neck 3 of the tubular piston, as described, for example, in the American patent 2,595,548 by Schroeder The horizontal and vertical deflection forces required for the scanning movement of the three electron beams are simultaneously supplied by a common deflection yoke 15, which can be understood as two pairs of electromagnetic coils, which are each arranged at right angles to one another on the shark 3. The line A-A in Fig. 1 represents the "deflection plane" at which it is calibrated is the plane in which the axis of each deflected ray, extended backwards, the zero axis of this Beam intersects. The axial position of the deflection plane changes slightly with changes in the beam deflection Di two dash-dotted lines B show the center of gravity or the theoretical center of the three rays at their

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maximum horizontal deflection from the deflection plane Pure a 90 ° tube (90 ° diagonal) is the maximum horizontal deflection angle (between lines B) about 78 °, while the maximum vertical deflection angle is around 63 °.

Normally the shadow mask is within the tubular envelope by means of at least three and preferably by means of four (for a rectangular tube) supported by leaf springs attached to the shadow mask frame (or to one welded to the frame Hook plate) are welded and detachably attached to the piston, the leaf springs each having a hole, with which they are embedded in the flask wall with one each Metal pegs are engaged. The usual arrangements allow a radial or outward direction Movement of the shadow mask in tennis tends to expand, but otherwise keep the shadow mask in relation to the mosaic-like one Impact area 7 in only one position. The three different sets of red, green and blue phosphor dots are on the impact surface 7 after customary "lighthouse" process using a removable mask as a stencil to create the to expose corresponding portions of the layers of the photosensitive phosphor material. According to this procedure a mosaic is made that contains three red, green and blue emitting fluorescent dots 6,

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wherein the centroid of each threesome is essentially aligned with one of the shadow mask openings 11a. at During the production of the shield there is of course no significant heating of the shadow mask.

If during operation of the color picture tube, the shadow mask 11 and its frame 12 as a result of heating by electron bombardment expand, color impurity is caused in the three-color image of the screen due to the misdirection between the holes 11a and the phosphor dots 6. To eliminate such misalignment or To reduce to a minimum, the shadow mask electrode 10 according to an embodiment of the invention by means of a Device stored, which comprises such leaf springs that they cause a movement of the shadow mask in the direction of the screen during the outward expansion movement of the shadow mask when heat is generated by electron bombardment.

Figures 1 to 4 show an embodiment of the invention in which the shadow mask frame 12 is provided by means of four L-shaped leaf springs 19 is releasably attached to four tapered metal pins 17, which are in the inner wall the piston cap 9 are embedded or otherwise permanently connected to this. The pins 17 and springs 19 are preferably at or near the midpoint of the sides of the

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arranged rectangular cap 9, as can be seen from FIG. Each spring 19 comprises at least one bimetallic Base section or short leg 19a and a long spring leg 19 "b · This spring 19 can be L-shaped Strip made of spring material, with a rectangular strip made of a different type of metal connected to the short leg to form the bimetallic base section 19a. Alternatively, the entire spring 19 made of resilient, bimetallic sheet metal material. The long leg 19b is in an acute angle to the plane of the base portion 19a along a line 19c bent outward and with a Hole 19d provided, which, as shown, may be out of round in order to releasably engage the pin 1? to soften. Of the The base portion 19a of the spring 19 is welded, for example at points 25, to the flange 12a of the frame 12, whereby the shadow mask 11 is arranged in the correct position relative to the screen. The base section 19a is already provided during its manufacture with an angle along a line 26 to the original clearance between create the main part of the base portion and the flange 12a su as shown in FIG. The materials for the bimetallic base section 19a are chosen so that the lower end thereof is when heated moved inward toward the frame 12 as indicated by the arrow 27 in FIG. So therefore must

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the temperature coefficient of the metal layer lying on the frame can be smaller than the coefficient of the other metal layer · For example, the one lying on the lame Metal layer consist of Invar, the coefficient of thermal expansion of which is almost zero, while the other Layer can consist of spring steel

When operating the drill shown in Figs If the shadow mask electrode 10 heats up as a result of electron bombardment, it is also warmed up by heat conduction or heat radiation from the frame 12 of the metallic Section 19a and moves in the calibration of arrow 27. This causes, in part due to the bending of the leg section 19b, a movement of the hole 19d opposite the frame 12 in the direction of arrow 29 · Since the hole 19d is fixed in position by the pin 17 on the piston cap 9, the result of the movement of the bimetallic section 19a relative to the frame is a movement component of the shadow mask electrode 10 in the opposite direction, i.e. in the direction of the screen, when the shadow mask expands outwards. Preferably, the shape of the spring 19 and the thermal Coefficients of the bimetallic round section 19a chosen such that the resulting movement of the shadow mask openings 11a at the edge of the shadow mask 11, over the normal operating temperature range of the tube,

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substantially along the maximum deflection path of the beam (B in Hg. 1), so that a misalignment of the openings opposite the assigned phosphor is reduced to a minimum.

FIGS. 5 and 6 show a modified version compared to FIGS. 1 to 4 Embodiment in which the torsion in the leaf spring, which causes a movement of the shadow mask in the direction on the screen caused by the expansion of the shadow mask frame outwards instead by heating a bimetal part The shadow mask frame 12 is attached to the pin 17 by means of leaf springs 33 of the tubular piston supported. Each leaf spring 33 includes an end portion 33a which is welded to the frame 12 is, an end portion 33b having a hole 33c which is in engagement with a pin 17, and a connecting portion 33c opposite the end portions 33a and 33b is bent along lines 35 and 37 at an angle θ such that an outward expansion of the frame 12 forces the end portion 33b to move relative to the frame in the direction of arrow 39 in FIG. 5, so he moves the shadow mask electrode 10 in a seal on the screen, as in Fig. 1, are preferably the bends 35 and 37 in the spring 33 such that after the installation of the shadow mask in the piston, the end portions 33a and 33b lie in substantially parallel planes. the

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Abkröpfu & gslinien 35 and 3? run at an angle θ significantly less than all 9Ü ^Ö , fe.B. 45 °, to the connecting line between the attachment points of the end sections 33 ^ i 33b »whereby the bath tube 33b fixed in position on the ßShrenkolben is closer to the screen side than the movable end tube 33a, the crank angles fall as in the example (see fig. 6) are smaller than 90 ° . In Abkröpfwinkeln of more than 9O ^Ö the movable Endabsöhnitt 33a was nearer the Bildschirmeeite.

7 and 9 aeigen two embodiments in which at least a! Length part of the fastening spring lies in a plane which is perpendicular to the plane of the shadow mask frame and passes through the longitudinal axis of the drill. In the tig *? and 8. 41 has the leaf spring one end portion 41a 'to the Rah s is welded ig, a EndabßChnitt 41b with a hole 41c, the steh't with a pin 17 of the Kolbeae in Singriff, uad a ^v erblndun "· - section 41d , 4er at an epitaea angle zn springs dtr aidabsehnitte eteht. T _o raug6Wei *% ftind the angles dad after the installation of the hole in the piston, the dung section 41ö runs in the weeklong right to aaxta * l «& Ableakbahn 1, as shown in Hf, 7. Mfern 41 that that of the deh & end »& iiahueÄe 12 is essentially. 4er BäIäi I r ^ flfc ^ ft. B * i according to the modification

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the fastening spring 45 is L-shaped with a long leg 45a welded to the frame 12 at 47 and a short leg 45b, The design of the entire leaf spring 41 according to FIGS. 7 and 8 is identical. First of all, the (four) springs 45 only welded to the frame 12 at points 47, and the other end of the long leg 45a, which lies flat against the frame, is still left unattached to the To facilitate removal and reinstallation of the shadow mask in the successive screen manufacturing steps After the production of the screen, the leg 45a is also permanently welded to the frame 12 at 49. she Embodiments according to FIGS. 7 to 9 have opposite those according to FIGS. 1 to 6 have the advantage that the movement of the shadow mask electrode 10 with each fastening device during the warming up essentially on a radial plane (or on the relative displacement of this plane) is limited, which runs through the mounting pin 17 and the Höhrenachse.

10 to 15 show two embodiments in which each fastening spring is effective on opposite one Ends hinged to the shadow mask frame 12 and the tube piston cap 9 is connected, and each spring is special Means for generating a shadow mask movement in sighting on the. Screen (when the shadow mask is expanded)

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are arranged. In the embodiment according to FIGS. 10 and

11, a leaf spring 51 is rotatably connected on a saide 51a to the frame 12, ζ · Β · by means of a rivet 53, and has a hole 51c on the other E5n.de 51b, which receives a pin 17 of the piston cap 9 · the spring 51 is originally bent so sharply along a line 51d that the hole 51c or the end 51b is held securely in engagement with the pin 17. ^E in elongated bimetal strip 55 is welded with one end 55a to the radial flange 12b of the frame 12 with the other end 55b to the edge of the end 51a of the leather 51. The metals of the bimetallic strip 55 are chosen such that the end 55b moves when heated relative to the frame 12 in the direction of the arrow 57 (FIG. 10) and thus causes a displacement of the shadow mask towards the screen when the shadow mask expands radially. In FIGS. 12 and 13, a leaf spring 51 is connected in an articulated manner to the frame 12 and the pin 17, as in FIGS. 10 and 11. The desired displacement of the shadow mask towards the screen depending on an outward expansion The shadow mask is created here by a beveled block or wedge 57 which is attached to the flange 12a of the frame

12 is welded on. The wedge 57 has an inclined surface 57a which is at the top of the end 51b of the spring 51 attacks the surface 57a should be essentially parallel to the main deflection path B so that the hole

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mask is displaced along this path when its ligament is widened. A retaining leaf spring 59 " welded to the frame 12" engages around the lower edge "" of the end 51b of the spring 51 and holds the latter in contact with the wedge surface 57a.

All of the shadow mask attachments shown in FIGS. 1 to 13 can be used in particular with symmetrical four-point mounting in rectangular tubes or with three- or multi-point mounting in round tubes thermal expansion of the shadow mask, both a transverse displacement and an outward (radial) displacement of the shadow mask openings with respect to the fluorescent points. An arrangement for compensating for misalignment in both the radial direction and in the transverse direction in the case of a three-point mounting is shown in FIGS. 14 and 15 shown, - ^ ie shadow mask 11 is supported in the piston cap 9 by means of three leaf springs 61, 62 and 63, which are each attached to the shadow mask frame 12 and articulated to the cap 9, for example through a hole receiving a pin 17 of the cap . The spring 61 is located near the center of one side of the cap, in the "twelve o'clock position", and the two springs 62 and 63 are at the ends of the cap about midway between

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that opposite to the attachment side of the spring 61 Side and the horizontal center line of the cap Movement in expansion of the warming smile mask 10 allow, the shadow mask expands upwards (twelve o'clock) much more than downwards (six o'clock), like is indicated by the long and short arrows 64 and 65 in Fig. 14, since the greater part of the shadow mask is above the line C-C running through the two lateral bearing points. To essentially the alignment the shadow mask openings and the fluorescent dots at To maintain operation, it is necessary to attach fastening springs to the bearing points on the side !! to use, which compensate for both the outward and the transverse expansion of the shadow mask. Each of the in the 1 to 13 shown temperature compensating springs can be used as spring 61 in the twelve-Unr position will; however, a spring such as that shown in Figures 7 and 8 is preferred which is essentially none lateral shift yields. The springs 62 and 63 can in the same way as those according to FIGS. 7 and 8, but be made a little longer, and be welded to the frame 12 at an acute angle, as in FIG Fig. 15 is shown so that the adjacent parts of the Shadow mask and broaching downwards (as movement at six

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Clock) and also be guided against the screen when the frame expands outwards. The feathers 62 and 63 extend in directions inclined to the longitudinal axis X-X of the tube (not parallel and not Schneider ^, in contrast to the axial alignment of the spring 41 in Fig. 7, the length of the springs 62 and 63 should be such that the component of movement of the shadow mask towards the screen is substantially the same that of spring 61 is.

If the perforated mask 11 and expand their frame 12 due to the heat generated by electron bombardment, is due to the misalignment the openings 11a and the phosphor points 6 a color impurity in the three-color image. To a To eliminate or minimize such misalignment, according to a further embodiment of the invention, the shadow mask electrode 10 is provided by a Attached device comprising leaf springs and bimetallic parts which the shadow mask in the direction of the Relocate the screen when the shadow mask expands outwards due to the heat generated by electron bombardment

1, 2, 16 and 17 show an embodiment of the invention in which the shadow mask frame 12 is detachably mounted on four metal pins 17, which in dl "luuenwami duv

BAD ORtQfNAi.

Piston cap 9 let in or otherwise permanently connected to this. The frame 12 is supported by four L-shaped leaf springs 19 * and four bimetallic base plates 21. Preferably, the pins 17, springs 19 'and plates 21 are located at or near the midpoints of the sides of the rectangular cap 9, as shown in FIG. Each spring 19 'comprises a base section or short limb 19a ¹ and a long limb 19b ^1. The long limb 19b ¹ is bent outwards at an acute angle from the plane of the base section 19a ¹ along the line 19c ¹ (FIG. 18) and provided with a hole 19d ^f , which may be out of round, as shown, and which is used for detachable attachment to the pin 17. Each base plate is provided with two essentially flat fastening sections 21a and 21b, which are connected in one piece via an expansion bracket or folded section 21c, which protrudes at a constant height above the fastening sections. The upper fastening section 21a is welded, for example at points 23 ', to the flange 12a of the frame 12, the bracket 21c being essentially parallel to the frame (FIG. 17). The lower part of the base section 19a ^{1 of} the spring 19 'is welded, for example at points 25 », to the lower bearing section 21b of the plate 21, the perforated mask being arranged in the correct position relative to the screen. The base plate 21 can have a hook 21d at one end,

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for receiving an end section 19e * of the spring 19 ' is suitable to hold the spring group before the welding process during assembly on the base plate.

The material for the bimetallic base plate 21 is selected in such a way that, when heated, the lower end 21b moves inwardly towards the frame 12, as indicated overall by the arrow 27 in FIG. As a result, the temperature coefficient of the metal layer adjacent to the frame must be smaller than that of the other metal layer. For example, the metal layer closest to the frame can consist of Invar (36% Ni, 64% Fe), the temperature coefficient of which is almost zero, while the other layer consists of a metal with a composition of 22% Ni, y / o Cr and 75 ^{° C} / ° Fe can exist.

If the operation shown in Figs. 1, 2, 16-18 Tube, the shadow mask electrode 10 is heated by electron bombardment, is also heated by heat? conduction and thermal radiation from the frame 12 from the bimetallic plate 21, and the expansion bracket 21c opens, which causes downward movement of the lower portion 21b

the spring 19 'and also the associated section 19a ¹ ZI of the seal about the arrow 27 causes. As a result, the hole 19d 'is displaced relative to the frame 12 in the direction of the arrow 29 (FIG. 17). This shift is going through

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the inclination of the leg 19b ¹ with respect to the plane of the base section 19a 'is increased. Since the hole 19d 'is fixed by the pin 17 on the cap 9, the end result of the movement of the bimetallic section 21b relative to the frame is a movement component of the shadow mask electrode 10 in the opposite direction, that is, in the direction of the screen when the The shape of the springs 19 'and the thermal coefficients of the bimetallic base plate 21 are preferably selected such that the resulting movement of the shadow mask openings 11a at the edge of the shadow mask, over the normal operating temperature range of the tube, essentially along the maximum Deflection path (B in Fig. 1) runs, so that a misalignment of the openings with respect to the associated light substance points is reduced to a minimum.

19 shows a diagram in which the arch, the distortion caused by the expansion of the mask 11, is shown for the first ninety minutes of operation. The ordinate indicates the radial displacement of the electron impact points, caused by the radial displacement of the shadow mask openings 11a, in relation to the fluorescent points of the screen 6 in microns, namely to different lead after switching on the drill, the measurements at predetermined points of a rectangular 2 $ Tariff

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Tube with 90 ° deflection at a larbferhseheirpifeiger. The measurements were carried out at eight points on a circle with a ^{radius of <4} JWa 16 cm at the points: twelve o'clock, one o'clock * thirty, three o'clock etc. . 19 is the mean of the eight measurements at a given time. A positive ordinate value indicates an outward "displacement of the electron impact points, and a negative ordinate value indicates an inward displacement. The dashed curve C shows the mean displacement of the impact points during the first ninety minutes of operation of a tube whose shadow mask is made by means of four conventional leaf springs Curve 0 initially shows a slight negative displacement of approximately 9 microns, which is followed by a positive displacement up to approximately 30 microns Screen 6 because the thin shadow mask 11 heats up faster than the thick frame 12 during the first five minutes of operation f place.

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The weighted curve D in FIG. 19 shows the mean displacement of the points of impact at the radius of 18 cm during the first ninety minutes of operation for a similar tube, the mask electrode of which is provided by means of four bimetallic plates 21 and four leaf springs 19 in the form according to FIGS. 1 _f 2, and 16 to 18 is stored · The maximum positive or negative shift was always less than eight microns, which is well within the 12.5 micron distortion that can usually be allowed, since this does not yet produce any noticeable color resolution in the image viewed . The negative part of the curve after about fifty minutes results from a slight overcompensation, that is, the radial expansion of the shadow mask has been shifted too much towards the screen. «The examinations were only carried out for the first fifty minutes, since afterwards the temperature of the shadow mask remains constant ·

20, 21 and 22 show a modified bimetallic plate 31 _t which can be used instead of the plate 21 in the embodiment according to FIGS. 1, 2 and 16 to 18. The plate 31 has two essentially flat fastening sections 31a and 31b which are integrally connected to one another via an expansion bracket or folded section 31c, while this bracket had a constant height in the embodiment according to FIG. 18,

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the height of the bracket 31c changes from a maximum at one end to essentially zero at the other end, as can be seen from FIG. If this modified Base plate 31 instead of base plate 21 in the embodiment 1, 2 and 16 to 18 are used is then forced the spring 19 'to rotate slightly clockwise in Fig. 17, causing the displacement of the hole 1 ° / d 'opposite the frame in the direction of the Arrow 29 is further strengthened.

20 to 22 also show a modified hook 31d on the plate 31, which consists of the bearing section 31b is punched out and points laterally instead of in the longitudinal direction of the plate. The bimetallic base plates 21 and 31 are preferably formed with the rolling direction transverse rather than longitudinal to the elongated plate, in which case the hook 31d can be produced more easily than the hook 21d.

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Claims (21)

Claims 1 «cathode ray tube with an evacuated flask, a screen that has a electron-sensitive, Has a mosaic-like impact surface and is arranged transversely to the longitudinal axis of the piston at one end of the piston 1st, with an electron gun placed near the other end of the piston is and provides at least one electron beam for screen scanning, and with a shadow mask electrode, the transverse to the longitudinal axis of the piston between the jet generator and the screen in the Is arranged near the screen and has a shadow mask and a reinforcing edge which Shadow mask has a multitude of openings through which the electrons pass on their orbits to the elementary surfaces of the raster screen, which are aligned with the openings of the shadow mask, and wherein the shadow mask electrode consists of a Material that expands due to the heat generated by electron bombardment, characterized in that that the shadow mask electrode (10) by means of flexible fastening devices in the piston (9) is mounted, each comprising a leaf spring (19), which is positively connected to the piston (9) and the shadow mask electrode (10) and a displacement 6353-66 * ^{Pee / S} 809812/0893 U62936 the shadow mask electrode renders towards the screen when the shadow mask electrode is located when heated by electron bombardment, and that the shadow mask electrode expands to such an extent is shifted that the alignment of the shadow mask openings (11a) on the elementary surfaces of the screen is maintained substantially during the operation of the tube. 2. Cathode ray tube according to claim 1, characterized in that the connection between the leaf spring (19) "and the tubular piston is detachable, including on Tubular piston a tapered pin (17) is provided, which in a hole (19a) of the spring (19) intervenes 3. Cathode ray tube according to claim 1, characterized in that the screen (9a) and the shadow mask electrode (10) are essentially rectangular and that the shadow mask electrode is close to the center points by means of four fastening devices (17 and 19) of the four sides of the rectangle is mounted in the tube piston. 4 _# cathode ray tube according to claim 1, characterized in that the fastening device comprises a bimetallic element (19a) which is attached to the leaf spring (19) - - - ■ · ' <.-.
is arranged. 809812/0893 ._ί -Η62936 5. Cathode ray tube according to claim 4, characterized in that one end (19Tj) of the leaf spring (19) is hinged to the piston and that the other bath comprises a bimetallic section (19a) which is attached to the frame (12) of the perforated electrode is. ^! 6 · Cathode ray tube according to claim 4, characterized in that that the leaf spring (51) is pivotally connected to FEN tubular piston and the frame (12) and that a special bimetal strip (55) is attached between the frame and the spring (51) " 7. Cathode ray tube according to claim 1, characterized in that that the leaf spring (33) consists of an elongated resilient metal strip which is in the essentially extends in the plane of the frame and is attached to this frame with a side (33a), while its other end (33b) is pivotally connected to the piston, and that a middle section (33d) of the spring bent laterally along a TiInIe inclined with respect to the aforementioned plane is· 809812/0893 8. Cathode ray tube according to Claim 1, characterized in that the spring (4-1) has an elongated section (41d) which runs essentially in a plane which is perpendicular to the plane of the frame lies and contains the longitudinal axis of the piston, and lies in a direction within this plane, which is essentially perpendicular to the maximum deflection path of the electron beam. 9 · Cathode ray tube according to claim 8, characterized in that that the elongated portion is the short leg (45b) of an L-shaped ffeder, whose long leg (45a) is attached to the frame 10. Cathode ray tube according to claim 1, characterized in that the fastening device has an elongated leaf spring (51) which is articulated with one end (51a) to the frame (12) and at the other end a hole (51c) into which a Pin (17) of the piston engages, and a further element (55 or 57) which is arranged between the shadow mask electrode (frame 12) and the F _e of (51) and a movement of the frame and the shadow mask in the direction of the screen caused by electron bombardment depending on their heating. 809812/0893 11. Cathode ray tube according to claim 10, characterized in that that the further element consists of an elongated bimetal strip (55) with his Ends in each case on the frame and attached to the other end (51b) of the leaf spring (51) mentioned. 12. Cathode ray tube according to claim 1, characterized in that the bulb, the screen and the shadow mask electrode have similar, substantially rectangular shapes, that the shadow mask electrode is mounted in the bulb with three fastening devices (61, 61 and 65), that the fastening device (61 ) is arranged in the middle of one long side of the rectangle and that the other two fastening devices (62 and 63) are arranged on the two short sides of the pike corner and close to but at a distance from the other long side and are designed in such a way that they displace the cause adjacent portions of the shadow mask electrode and of the frame laterally to the other longitudinal side as well as a transverse displacement of the screen toward a function of the thermal expansion of the shadow mask and the frame. 809812/0893 ^{| l} i? $ ". \ C * 5 13 · Cathode ray tube according to claim 12, characterized in that that each of the other two fastening devices (62 and 63) is an elongated leaf spring comprises, which is arranged inclined with respect to the longitudinal axis of the piston. 14. Cathode ray tube according to claim 4, characterized in that the bimetallic element consists of a Base plate (21) consists of bimetallic sheet metal, which has two fastening sections (21a and 21b) which are connected to one another via an expansion bracket (21c), wherein one of the fastening sections andfer shadow mask electrode and the other (21b) attached to the end (19a) of the spring (19) ″ are. 15 · Cathode ray tube according to claim 14, characterized in that that the leaf spring is releasably attached to the piston and for this purpose a tapered pin (17) is provided on the piston, which is inserted into a hole (I9d) in the * eder. 16. Cathode ray tube according to claim 14, characterized in that the base plate (21) has an elongated, rectangular plate with a longitudinal fold (21c) ven U-shaped cross-section, which the expansion 809812/0893 -y- forms bracket, and that the base plate (21) is attached to the shadow mask electrodes that the The fold (21c) extends essentially parallel to the shadow mask electrode 17. Cathode ray tube according to claim 16, characterized in that the height of the fold (21c) opposite the fastening sections is substantially the same over the full length. 18 · Cathode ray tube according to claim 16, characterized in that that the height of the fold (51c) with respect to the fastening sections increases from a maximum reduced to almost zero at one end at the other end 19 _# cathode ray tube according to claim 14, characterized in that the leaf spring (19) is attached to the base plate (2i), the longitudinal axis of this spring running essentially parallel to the shadow mask electrode 20. Cathode ray tube according to claim 14, characterized in that that the other end (19b) of the leaf spring (19) at an acute angle to the base plate outside has · *,; 809812/089 3 '"' ^: - '-. -S- U62936 21. Katlionesstralil tube according to claim 14, characterized in that that the base plate (31) comprises a hook-shaped part (31d) which is one end of the Leaf spring in contact with the base plate, "before the spring is attached to the base plate '8O98T2W893