PL114561B1 - Picture tube - Google Patents

Description

The subject of the invention is an imaging lamp, in particular an imaging lamp with electron beam directing elements, in which at least one and preferably each of a plurality of electron beams selects a different part of the surface of the luminous stall. a large-surface screen, containing a thin rectangular bank, with one of the large walls of this cuboid being a front plate, on which the screen is applied with an insensitive screen. Inside the banister there are many spaced parallel load-bearing walls to protect against external atmospheric pressure, positioned perpendicular to the large walls of the banks and between them so that the load-bearing walls define many parallel channels, transversely to one of the ends. In each channel there is an electron gun which directs at least one electron beam along each of the channels. In each channel there are electron beam guiding elements that limit the electron beam in the channel and direct the beam along the channel. The beam directing elements also provide for deflection of the electron beam beyond these elements at selected points along these elements. The beams in all the channels are simultaneously deflected past the beam guiding means towards the luminescent screen at each of the selected points to effect the linear selection of the raster elements. In a known picture tube of this type it is necessary to use a number of electron beams as many image elements are needed to obtain the proper horizontal resolution in the case of black and white image synthesis, and in the case of color image synthesis - two or three times as many. U. S. Patent No. 3,766,410, an imaging lamp comprising a mask having rows of slots for a strip-shaped luminescent screen. On the other hand, from United States patent application No. 607,490 there is known an imaging lamp having electron beam directing elements of the above-described type. U.S. Patent No. 285M64 discloses an imaging lamp having an electron gun including a linear cathode extending along a portion of the bank transversely to the ends of the channels. The image lamp according to the invention comprises deflecting electrodes arranged along a second path in each path. from the channels and disposed between the first track and the luminescent screen such that the second track passes between the trailing electrodes for selecting the entire luminescent screen by the total number of electron beams, less than the total number of image elements. *: '114 561114561 Each of the deflection electrodes lies along a separate one of the side walls or the support walls forming the side walls of the bank or stone. It is preferable according to the invention that each deflection electrode is a metal layer. The advantage of the invention is that by moving each of them A beam on a screen transversely to each of the channels, with a channel width much greater than the diameter of the bundle, a significant reduction in the number of beams necessary to provide the bleeding and over the entire width of the image tube is achieved. For example, in a picture lamp with a width of A ^ ^ bones_JLI) J (L ~, cm, having a channel width of A ^ ^ 5cim * kojni | t, it is only necessary to use 40 beams for the reproduction of black and white images or 40 ensembles pof three beams for the reconstruction of the colt. The history has been achieved by simplifying the 1 - - © sans4ffoflication of the electron gun used in such a picture lamp. It also simplifies the internal structure of the picture lamp by reduction in the number of bearer walls and guiding elements needed.In addition, since the channels have a much larger width than the diameter of the electron beam, the tolerance of the width of the guiding elements is no longer critical. The subject of the invention is illustrated in the example of the drawing in which FIG. shows) a flat picture lamp equipped with electron beam directing elements according to the invention, in perspective view, Fig. 2 - a part of the picture lamp in a section along Mnii 2 - 2 in Fig. 1 and Fig. 3 - a part of the picture lamp A sectional view taken along line 3-3 of FIG. 2. FIG. 1 shows a flat image lamp 10 incorporating a deflection and selection system according to the invention. The imaging lamp 10 comprises a vacuum bank 12, usually made of glass, having a picture portion 14 and a portion 16 in which an electron gun is located. The pictorial portion 14 comprises a rectangular front wall 18 on which an image display screen is provided and a rectangular rear wall 20 spaced from and parallel to the front wall 18. The front wall 18 and the rear wall 20 are connected by the side walls 22. The front wall 18 and the rear wall 20 are of such dimensions as to obtain the required screen dimensions, e.g. about 75 cm by 100 cm, and are usually spaced apart from each other. by 2.5 to 7.5 cm. As shown in FIG. 2, between the end wall 18 and the rear wall 20 are attached multiple spaced parallel bearing walls 24 made of an electrical insulator, such as glass. The bearing walls 24 extend from the portion 16 in which the electron gun is located to the opposing side wall 22 banks 12. The bearing walls 24 provide the internal structural reinforcement of the vacuum bank 12, preventing external a / taospheric pressure and dividing the image portion 14 into multiple channels. 26. The end of each of the bearing walls 24 near the end wall 18 is tapered to provide a minimum contact area between the bearing walls 24 and the end wall 18. A luminescence screen 28 is provided on the inner surface of the end wall 18. In the case of a black and white image display ¦ the luminescent screen 28 has the complete composition known in the art for imaging lamps to display black and white images. In the case of displaying a color image, the luminescent screen 28 is preferably of a strip-like structure. the strips are made of conventional phosphor components that emit red, green and blue light when excited with electrons. A coating 30 of metal, such as aluminum, is provided on the luminescent screen 28. In the picture lamps for displaying a color image 15 across each of the channels 26 lies a mask 32, located close to the luminescent screen 28 but not in contact with it. The mask 32 is mounted on the supporting walls 24 and extends over the entire length of the channels 26. 20 W In the case of the strip-like structure of the luminaire screen 28, rows of slots are provided in the mask 32. Each of the channels 26; Near the rear wall 20 are the electron beam directing elements. The electron beam guiding means may be of any design to direct one or more electron beam along a first track along the channel and allow the bundle cdcnylain at 30 points spaced along the channel to direct the beam along the second track in the direction of the channel. of the luminescent screen 28. The electron beam directing elements include a first metal base shape 35 34 extending along the inner surface of the back wall 20 and a second metal base shape 36 parallel to the first base shape 34 and not in contact with the base shape. In the base-shape 34 there are three gutters 38, each of which has a U-shaped cross-section with the open side facing the base-shape 36. Gutters 38 lie parallel to each other along the entire channel 26. The base-shape 34 can be made of 45 one sheet of metal or a plurality of metal strips parallel to each other across channel 26 and extending along the channel. Base shape 36 is formed from a sheet of metal and has three rows of holes 40 spaced apart at certain distances from each other. each of these rows of openings is located above a separate gutter 38 in the base shape 34. 55 A plurality of conductors 42 are disposed between the base shape 34 and the base shape 36 transversely to the channel 26. The conductors 42 are located transversely to the longitudinal axis. of the channel, parallel and at certain distances to each other, over the entire length of channel 26. The lines 42 are fixed between the holes 40 made in the base book 36. Near the base-shape 36, but at a certain distance from it, extends in each 114 561 6 channel 26 focal plate 44 and adjacent to focal plate 44 but at a certain distance from it, in each channel 26 the accelerator plate 46. The focus plate 44 and the accelerator plate 46 are made of metal and extend over the entire length of channel 26. In focus plate 44 and accelerator plate 46, three rows of holes are formed, respectively 48 and 50, with holes 48 and 50 opposite holes 40 in base shape 36. Each channel 26 has a pair of parallel, spaced apart deflection electrodes 52. The deflection electrodes 52 are positioned between the accelerator plate 46 and a mask 32 over its entire length, channel 26. The deflection electrodes 52 are preferably applied to the surfaces of the supporting walls 24 or the side walls 22, which constitute the walls of the connection of each of the channels 23. On the surface of each support wall 24 or sidewall 22, between the deflection electrode 52 and the mask 32, there is a sampling electrode 54. Part 16 banks 12, in which the electron gun is located, the hay extends the comb. The pictorial section 14 and extends along one set of adjacent ends of channels 26. Section 16, in which the electron gun is located, has any shape suitable for containing an electron gun of a particular design. The electron gun may be of any known design suitable to selectively direct at least one electron beam along each of channels 23. The electron gun may include rap. multiple remote electron guns, each one infused at the end of one of the channels 26 in order to direct separate electron beams along each of the channels. In a colored image lairrap, such as that shown in Figs. 2 and 3, three beams of electrons are guided along each of the channels 26, with each beam routing along a different channel 38 to the base-shape 34. In a black and white lamp with Only one beam per channel is sufficient. An electron gun with a different usable design comprises a linear caltode extending along portions 16 banks 12, across the channels 26, and adapted to selectively route separate electron beams along the channels. Regarding the design of the electron gun to be used in the device, the electron gun should also include means for modulating the electron beams in accordance with the input video signal. As shown in Fig. 1, the terminal block 56 is drawn through the sidewall 22 of the banks 12. Terminal block 56 comprises a plurality of terminals through conductors through which the electron gun structure and other portions of the image lamp contained within the bank 12 can be electrically connected to properly operating circuits and Power sources outside banks 12. During operation of the image tube 10, an electron gun located in section 16 banks 12 produces and directs at least one beam of electrons to each of the channels 26. In a color image tube, each Channel 26 is preferably directed three beams of electrons. The electron beams are directed between the base-shapes 34 and 36, with each beam being directed along a different slot 38 in the base-shape 10 34. Base shapes 34 and 36 of the directing elements have the potential of the earth and wires 42 have a positive potential. This causes the electron beam to move along a wave path through the conductors 42 and between the base shapes 34 and 36 along the entire length of the channel 26. Due to the U-shaped cross-section of the well 38, each electron beam is subjected to electrostatic forces such as that the electron beam shifts between the conductors 42 20 and the base shape .34 in order to limit the area in which the electrons move to the space between the troughs of the wells. that each electron beam runs along a different trough. Thus, each of the electron bundles 25 runs along the first stage along the corresponding channel 26 and the electron gun part 16 to the side wall 22 of the bank 12 opposite the part 16. When the electron beams reach 30 the taken point on the length of the guiding elements are deflected from the first track towards the second track leading to the headwall 18 banks 12. The talcum effect can be obtained by switching the potential applied to the lead 35 near the side wall 22 to a negative value, or if the basal shape 34 is made of a multitude of parallel strips - by switching the potential applied to the strip near the side wall 22 to a negative value. The selected point of the steering elements, at which the bias is observed, is moved progressively along the steering elements to their end cooperating with the electron gun to perform foam scanning. 45 The deflected electron beam exits the guiding elements through adjacent holes 40 made in the base plate 36. The electron beams then pass through holes 48 50 in focus plate 44 and holes 50 in accelerator plate 46. A positive potential is applied to focus plate 44. the potential of the base plate 36 to provide focusing of the bundles as they pass through the holes 48. We apply to the accelerator plate 46 a potential also positive with respect to that of the base-shape 33, preferably having the same value. what the potential of the metal coating 30 to provide an acceleration of the flow of electrons as they pass through the holes 50. The electron beams flow towards the luminescent screen 28 by applying a positive potential to the metal coating 30 on the luminescent screen 28.114 561 7 Since between the accelerator plate 46 and the luminescent screen 28 the electron beams * run along the second tiers, the beams pass between the deflection electrodes 52. Initially, one of the deflection electrodes 52 in each of the channels 26 has a positive potential with respect to the potential on the metal surface 30 adjacent to the surface 30 The luiminescent eitorate 28 and the second deflection electrode 52 have a potential negative with respect to the potential applied to the metal shell 30. This causes the second path of the electron beam to bend towards the deflection electrode 52, which has a positive potential. The potentials applied to the deflection electrodes 52 have a taffeta value that the bending of the second electron beam paths is sufficient to cause the initial impact of the electron beam on the luminous screen 28 to take place in the immediate vicinity of the supporting wall 24 on which the positively charged electrode is located. deflection electrodes 52. The values of the potentials applied to the deflection electrodes 52 are changed in a conventional manner by applying specific deflection signals to these electrodes to force a horizontal scan with a bundle of screen portions of the corresponding channel width. Due to the similar deflection of the beams in each channel, transverse to these channels, a visible line is produced over the entire width of the luminescent screen 28 to achieve the selection of complete horizontal lines on the luminescent screen 28. Horizontal scanning is combined with vertical scanning for full screen illumination. By modulating the beams in electron guns, an image can be displayed on the luminescent screen 28, which image can be viewed through the face 18 of the picture tube. Each time the second electron beam paths are deflected across the channels by means of deflection electrodes 52, at least one beam in each channel strikes at least one, if not both, sampling electrodes 54. When the electron beam strikes the sampling electrode 54, an electrical signal is generated on the electrode that can be detected. This signal can be used to determine the positions of the beams so as to obtain the appropriate alignment of the beams in each of the channels. This signal can also be used to determine the value of the beam current in order to ensure uniform brightness throughout the screen. Accordingly, the sampling electrodes 54 can be used to detect the position of the beams and / or their current intensity. This information can be used to control the value of the signals applied to the deflecting electrodes 52 for the proper alignment of all beams and / kb, while controlling the signals fed to the electron guns to ensure the correct value of the beam current and the correct positions of the rain points. Although an image lamp 10 has been described, in which, to obtain a color image, three beams of electrons are used in each of the channels 26, * in the image tube to reproduce black and white images it is necessary the use of only one electron beam directed by the guiding elements in each of the channels 26, and moreover, no mask 32 is needed. The imaging tube then operates in a manner similar to that previously described, with a single beam in each of the channels channels 10 26 is deflected beyond the first guide track along the guide elements at multiple points along the channel up to the second track guiding towards the luminescent screen 28. Since the electron beam passes between the deflection electrodes 52, it is deflected transversely with respect to the channel 26 to accomplish selecting lines on the luminescent screen 28. In the flat picture lamp according to the invention, many electron beams are directed through the channels along the first tracks. parallel to the luminescent screen on the face of the lamp. The beams are deflected from the first tracks to the second tracks extending towards the luminescent screen at a plurality of points on the first tracks at some distances from one another. While the element bundles pass along each of the second paths, each bundle is deflected in a plane crossing the first path of the M bundle and perpendicular to the first path of the talc that the bundle moves over that part of the luminescent screen that extends transversely along the parallel channel for realization. selecting a 'line- on a luminous screen. Claims 1. A picture lamp comprising a vacuum bank having flat front and rear faces placed close to each other, a luminescent screen carried on the inner face of the front face and containing a plurality of image elements, each element consisting of multiple areas of the phosphor, each of these areas of luimimofoTu is adapted to emit a different color in the barrel are parallel bearing walls that lie perpendicularly between the front wall and the back wall, which define many channels, and the bank has a part in which it is located an electron beam generator for producing an electron beam for each color and directing each beam with a separate first path, usually parallel and across a luminescent screen1, each of the said at least one electron beam being produced projected and directed along a specific, one of the channels and an electrode along the first beam path to the selective - deflecting the beam past the first track at selected points of the first track towards the second track towards the luirndence screen to cause the electron beam to be delivered to the luminous screen, characterized in that it includes deflection electrodes (52) positioned along the second track in each of the channels (26) and located interfaces114 561 9 (the first beam path and the luminescent screen (28) * taik, with the second tc with deflecting electrodes (52) for selecting the entire luminescent screen by the total number of electron beams, less than the total number of picture elements. 2. Lamp according to replacement. The method of claim 1, characterized in that each of the deflection electrodes (52) lies along a separate one of the side walls (22) or the support walls (24) forming the side walls of the banks (12) or channel (26). 3. Lamp according to display. ¦ 1, characterized in that each deflection electrode (52) is a metal layer. 34 40 \ 34 20 PL

Claims (3)

Claims 1. A picture lamp comprising a vacuum bank having flat front and rear faces placed close to each other, a luminescent screen on the inner face of the front face and comprising a plurality of image elements, each element consisting of a plurality of areas of the phosphor, each of these areas of luimimofo is adapted to emit a different color in the barrel are parallel bearing walls, lying perpendicularly between the front wall and the back wall, which define many channels, and the bank has a part in which is located An electron viewport for producing an electron beam for each color and directing each beam with a separate first path, usually parallel and across a luminescent screen, where each of the said at least one electron beam is produced and directed along a specific, one of the channels and an electrode along the first beam path to the selective - o deflecting the beam past the first track at selected points of the first track towards the second track running in the direction of the luirndence screen to cause the electron beam to be delivered to the luminescent screen, characterized by deflecting electrodes (52) positioned along the second track in each of the channels (26) and positioned interfaces114 561 9 (the first beam path and the luminescent screen (28) * taik, with the second tc with deflecting electrodes (52) to select the entire luminescent screen by the total number of electron beams, less than the total number of elements image. 2. Lamp according to replacement. The method of claim 1, characterized in that each of the deflection electrodes (52) lies along a separate one of the side walls (22) or the support walls (24) forming the side walls of the banks (12) or channel (26). 3. Lamp according to display. ¦ 1, characterized in that each deflection electrode (52) is a metal layer. 34 40 \ 34 20 PL