KR830002462B1 - Flat display with beam guide - Google Patents

Abstract

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Description

Flat display with beam guide

1 is a partially cutaway perspective view of a flat display device according to the present invention.

FIG. 2 is a perspective view, partially cut away, of a form of the beam guide of the present invention that can be used in the display device of FIG.

3 is a partial cross sectional view of the beam guide shown in FIG.

4 is a longitudinal sectional view taken along line 4-4 of the beam guide shown in FIG.

5 is a partially cutaway perspective view of a modified form of the beam guide shown in FIGS. 2-4 that may be used in the display device of FIG.

6 is a partial cross sectional view of the beam guide shown in FIG.

FIG. 7 is a longitudinal cross-sectional view taken along line 7-7 of the beam guide shown in FIG. 6. FIG.

8 is a front view of an electrode that can be used in the beam guide shown in FIG.

FIG. 9 is a front view of a variant of the grid plate which can be used with the electrode shown in FIG. 8 in the beamguide shown in FIG.

10 is a cross-sectional view of a beam guide of another form of the present invention.

11 is a longitudinal sectional view taken along line 11-11 of FIG.

12 is a partially cutaway perspective view of a beam guide of another type of the present invention that can be used in the display device shown in FIG.

FIG. 13 is a partial cross-sectional view of the beam guide shown in FIG. 12. FIG.

14 is a longitudinal sectional view taken along line 14-14 shown in FIG.

FIG. 15 is a partial cutaway perspective view of a variant of the beam guide shown in FIGS. 12-14 that may be used in the beam guide shown in FIG.

FIG. 16 is a longitudinal sectional view taken along a portion of the beam path in the beam guide shown in FIG. 15; FIG.

FIG. 17 is a cross-sectional view taken along the line 17-17 of FIG. 16. FIG.

FIG. 18 is a longitudinal section cut along the line 18-18 of FIG.

19 is a longitudinal sectional view of another variant of the connection beam guide shown in FIGS. 12-18.

The present invention relates to a flat image display device including an apparatus for scanning a deficit beam on an image screen, and more particularly, to a structure for restricting and guiding an electronic beam to selectively deflect the image screen. Attempts have been made to reduce the depth of the receiving tube by providing a flat display for a long time. The structure of these devices is a thin box-shaped envelope with large sides that make up a faceplate with fluorescent screens. (envelope). The electron gun directs the electrons across the tube along a path that is actually parallel to the screen. There is also provided a deflection element for selectively deflecting the continuous point of the screen to scan the electron beam as expected. This type of water tube was named W Electronic on March 8, 1960. egg. US Patent No. 2,928,014 to Mr. Akin.

The problem with fabricating flat displays with large screens (approximately 75 cm x 100 cm) using this technique is the destruction of the vacuum tube, which requires a new internal support wall to be installed. . A device with such an internal support wall was designated W 28 October 1958 under the name "cathode ray tube". L. Described in US Pat. No. 2,858,464 to Robert. However, in such a tube having an inner support wall, an even more serious problem has arisen because the electron beam must be limited and guided without colliding with the support wall. This is because when the electron beam is dissipated from the point of occurrence and gradually becomes larger, and the electrons are filled with the support, a part of the receiving tube is charged to prevent the function of the receiver.

Limiting the electron beam is accomplished by a beam guide that applies an electrostatic force to the electron beam to limit the electrons to a relatively small electron beam as the electron beam travels along a passage located across the envelope. In addition, the beam guide is provided with a deflection element for deflecting the electron beam to the outside of the beam guide to irradiate various fluorescent points on the fluorescent screener along the channel length. In order to simplify the structure of such a flat display device, a beam guide for assembling a minimum number of parts and performing an expected operation function is preferable.

In the display device of the type described above, the guide device includes a plurality of insulated conductors extending across the non-passage path on the opposite side of the screen line provided in the envelope of the display device. The grid plates are positioned parallel to each other in the non-passage. The grid plate is formed with a number of isolated openings along the non-passage path. The guide device includes devices extending along lines parallel to opposite sides of each beampath to generate electrostatic forces that laterally limit the beams to each beampath.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 1, one form of the flat display device of the present invention is shown by numeral 10. In FIG. This display device 10 includes a vacuum envelope 12 made of glass having a display portion 14 and an electron gun portion 16. The display portion 14 includes a rectangular front wall 18 supporting the screen 28 and a rectangular rear wall 20 parallel to the front wall 18. The size of the front wall 18 and the rear wall 20 is 75 cm x 100 cm, which is the preferred size of the screen, and the width of both sides is about 2.5 cm-7.5 cm.

A plurality of isolated parallel support walls 24 are fixedly seated between the front wall 18 and the back wall 20 and extend from the electron gun portion 16 to the counterfoot side wall 22. The support wall 24 provides the inner support of the vacuum envelope 12 against external atmospheric pressure and divides the indicator portion 14 into a plurality of channels 26. Fluorescent screens 28 are provided on the inner surface of the front wall 18. The fluorescent screens 28 may be screens of any type used in current black and white televisions or color television CRTs. The fluorescent screen 28 is provided with a metal film electrode 30.

The electron gun portion 16 extends along a set of the receiving end portions of the channel 26 as an extension of the display portion 14. The gun portion 16 takes a structure suitable for enclosing a special electron gun installed therein. The electron gun installed in the gun section 16 consists of a number of independent guns precincted at the distal ends of the channels 26 to fire separate electron beams along each channel 26. The gun structure is also designed to include a line cathode that extends along the gun portion 16 across the distal end of the channel 26 to suitably launch individual electron beams along the channel 26. Will be. This type of electron gun structure was called W cathode ray tube on October 28, 1958. L. Described in US Pat. No. 2,858,464 to Robert.

In each channel 26, a connection guide is provided for connecting beams, which are directly directed to the passages in the channels, to the beam. In addition, each guide has a deflection element that deflects the electron beam to the outside of the guide to irradiate various fluorescent points on the fluorescent screen 28 located along the length of the channel 26.

2, 3 and 4 show that a form of connection guide according to the invention is provided in the channel 26. As illustrated, four connection guides are provided in each channel 26, but the number of connection guides is not limited. The connection guide comprises a set of two conductors 34, 36 extending transversely across the channel 26 on the inner surface on the back wall 20. These conductors 34 and 36 are sets of strips of conductive material such as metal coated on the inner surface of the back wall 20. The conductors 34, 36 are alternately arranged in a set of strips parallel to each other along the entire length of the channel 26. Rather than fabricating the same size of the two conductors 34 and 36, the longitudinal length of the conductor 36 is longer than the longitudinal length of the conductor 34.

The first metal grid plate 38 is designed to extend laterally across the isolated channel 26 adjacent the back wall 20 to fit snugly in the groove on the support wall 24. The first metal grid plate 38 is a grid plate in which two members 38a and 38b are interlocked at right angles to each other. One intersecting member 38a of these two members 38a, 38b extends laterally across the channel 26 in parallel along each of the separate conductors 36. Although the width | variety of this cross member 38a can be manufactured in the same size as the width | variety of the conductor 36, Preferably it is narrower than the width | variety of the conductor 36. The other cross member 38b extends longitudinally parallel along the channel 26. These two intersecting members 38a and 38b cross each other longitudinally and laterally to form a plurality of rectangular openings 38c.

The plurality of connection electrodes 40 extend longitudinally in parallel with each other along the space of the channel 26 between the first metal grid plate 38 and the conductors 34 and 36. As shown, the connecting electrode 40 may have a diameter equal to the width of the cross member 38b extending longitudinally as a metal conductor having a circular cross section, but should not be larger.

The second metal grid plate 42 is designed to extend laterally along the space of the channel 26 between the first metal grid plate 38 and the front wall 18 to fit snugly in the groove on the support wall 24. As with the first metal grid plate 38, the second metal grid plate 42 also has a plurality of rectangular openings 44 formed by perpendicularly crossing each other horizontally and horizontally. The opening 44 is designed to face the opening 38c with the same size as the opening 38c of the first metal grid plate 38. The plurality of openings 44 are arranged in a vertical row along the channel 26 to be positioned between the pair of adjacent connection electrodes 40.

Looking at the size and position of the connection guide, the first metal grid plate 38 is located 1.02mm apart from the conductors 34, 36, the second metal grid plate 42 is the first metal grid plate 38 ) 0.25mm apart. The diameter of each connection electrode 40 is 0.25 mm, and is spaced 0.25 mm apart from the conductors 34 and 36, and the distance between both connection electrodes 40 is 3.56 mm. The width of the member 38a, which is laterally higher in the first metal grid plate 38, is 0.61 mm, the spacing between the members 38a is 1.52 mm, and the width of the member 38b that intersects the length is 0.25 mm. The spacing between both members 38b is 3.56 mm. The widths of the two conductors 34 and 36 are 0.61 mm and 0.41 mm, respectively.

During the initial operation of the display device 10, the high voltages of 125 V and 180 V are applied to the conductor 34 and the second metal grid plate 42, respectively, while the conductor 36 and the first metal grid plate 38 and the respective focusing are performed. A low voltage of about 56 V is applied to the electrode 40, respectively. The electron gun installed in the electron gun section 16 fires a plurality of electron beams and directs them to each channel 26. The direct electron beam proceeds in a straight path made of a pair of adjacent focusing electrodes 40 between the rear wall 20 and the first metal grid plate 38. In FIGS. 3 and 4 these electron beams are shown by the solid line 46.

As shown in FIG. 3, the potential difference between the focusing electrode 40 and the conductor 34 generates an electrostatic force as indicated by the arrow 48, and the first metal grid plate 38 and the second metal grid plate. The potential difference between 42 generates electrostatic force applied to the second metal grid plate 42 through the opening 38c of the cross member 38b as indicated by arrow 50. Such static electricity applies electrostatic force to the electron beam 46 to detect or limit the movement of electrons laterally in the guide as the beam moves along the guide.

As shown in FIG. 4, the potential difference between the conductor 34 and the conductor 36 generates an electrostatic force as indicated by arrow 52. The electrostatic force indicated by the arrow 53 is through the opening 38c in the first metal grid plate 38 between the cross member 38a of the first metal grid plate 38 and the second metal grid plate 42. Is extended.

As each electron beam moves between the first metal grid plate 38 and the conductors 34 and 36, an electrostatic field applies a periodic focusing force to the electrons to focus the electron beams periodically. The periodic focusing of these electronic beams was in 1954. Jay published by Van Northland Company. egg. It is described in detail in the book "Theory and Design of Electronic Beams" by Pierce. The periodic focusing and side-limiting of the electron beam continues until the electron beam is extracted through the health of the guide. Therefore, the connection guide includes the first and the second metal grid plates 38 and 42 extending laterally between the focusing electrodes 40, the conductors 34 and 36, and the pair of focusing electrodes 40.

A low pressure of -60V is applied to the conductor 34 to extract the electron beam 46 from the guide. When the electron beam reaches the conductor 34, the beam is attracted and deflected by the high pressure of the second metal grid plate 42 and the low pressure of the conductor 34, and then the first metal grid plate 38 and the second metal grid plate 42. After passing through the openings 38c and 44 of the sequential order, the fluorescent screen 28 is impacted by the high pressure applied to the metal film 30.

The operation of the display device 10 initially switches the low voltage to the conductor 34 adjacent to the side wall 22 located opposite to the electron gun portion 16, thereby all of the electron beams 46 in each channel 26. After passing through the respective guides by deflection in the adjacent portion of the side wall 22, they collide with the fluorescent screen 28 to perform a line scan. Subsequently, if the low potential of the conductor 34 is sequentially switched along the entire length of the channel, the beam is extracted out of the guide at various points along the guide length to perform a line by line scan to the screen. By performing this switching speed appropriately during each line syringe and modulating the beam in the electron gun, a visual indication is displayed on the fluorescent screen 28 attached on the front wall 18 of the envelope 12. . Optionally, the preliminary scanning starts in the vicinity of the electron gun portion 16 and starts sequentially toward the opposite side wall 22 or by sequentially switching low voltages applied to the various conductors 34. The expected line scan can be done.

5, 6, and 7 illustrate a modified form of the beam guide shown in FIGS. 2 through 4 that may be used in the display device 10 of FIG. The modified focusing guide is illustrated in FIGS. 2-4 except that the focusing electrode 40 is omitted and new conductors 134 and 136 are designed to perform the focusing operation according to the omission of the focusing electrode 40. It is actually designed exactly the same as the guide shown in the figure.

Conductors 134 and 136 were alternately disposed along the length of channel 26 with strips coated on back wall 20 with a conductive material such as metal. Each conductor 134 is composed of a plurality of rectangular first regions 134a disposed along a conductor across the channel 26 and narrow connection regions 134b connected adjacent to the first regions 134a. It is. The first region 134a is a region slightly smaller than the width of the opening 138c of the first metal grid plate 138 so as to be in line with each of the openings 138c, and the connecting region 134b extends laterally. It is placed on the opposite side of the cross member 138b extending longitudinally in an intermediate position of the cross member 138a. Each conductor 136 is parallel to the laterally extending cross member 138a of the first metal grid plate 138 and has the same length on both sides. Each conductor 136 has a projection 136a protruding in the space of the connection region 134b between two adjacent first regions 134a, each of which is opposite to each other. It is designed to have a width smaller than the width of the longitudinal axis cross member 138b of the one metal grid plate 138.

In the typical focusing guide described above, the first metal grid plate 138 is spaced about 0.76 mm apart from the conductors 134 and 136, and the second metal grid plate 142 is about 0.25 from the first metal grid plate 138. Located apart in mm intervals. The width of the horizontally intersecting members 138a of the first metal grid plate 138 is 0.51 mm, the spacing between the two members is 1.52 mm, and the width of the longitudinally intersecting members 138b is 0.25 mm, between the two members. The thickness of is 3.56mm. As described above, the sizes of the conductors 134 and 136 correspond to the diameters of the cross members 138a and 138b and the size of the opening 138c of the first metal grid plate 138.

The voltage and operation mode applied in the operation of the display device 10 including the focusing guide described above are the same as those described in the focusing guide illustrated in FIGS. 2 to 4. As shown in FIG. 7, each beam 146 is applied between conductors 134 and conductors 136 and between the first metal grid plate 138 and the second metal grid plate 142 as it passes through the guide. The electrons are periodically focused by the static electricity. As shown in FIG. 6, the lateral limitation of electrons constituting the beam 146 is between the first metal grid plate 138 and the second metal grid plate 142 and the first region 134a of the conductor 134. ) And the electrostatic force applied between the two outlet portions 136a of the conductor 136. Extraction of beam 146 in the beam guide takes place in the manner as described above, switching a low voltage of -60V to conductor 134. This lateral limitation is better done with a modified focusing guide using the newly designed conductors 134 and 136 than with the focusing electrode 40 used in FIGS. 2-4. Since the conductors 134 and 136 are metal films coated on the surface of the rear wall 20, a focusing electrode 40 is provided between the rear wall 20 and the first metal grid plate 38 as shown in FIG. Much better conductors are formed than forming the expected conductors.

In the modified focusing guide, field crowing occurs at the angular edges of the rectangular first region 134a of the conductor 134, thereby causing a defect in which the conductors are broken. It is desirable to correct. FIG. 8 is a modified form of the conductor consisting of elliptical first regions 234a that are lowered laterally across the channel 26 and narrow connection regions 234b connecting the regions 234a. The plate is shown.

The rounded shape of the first region 234a not only minimizes the breakage of the conductor but also makes the limiting force more uniform around the electron beam. As the first region 234a of the conductor 234 is made round, the openings of the first metal grid plate must also be made round. FIG. 9 shows an elliptical design of the opening 234c of the first metal grid plate 238 in this embodiment to fit the elliptical shape of the first region 234a of the conductor 234.

10 and 11 illustrate a second modification type of the focusing guide that can be used in the display device 10. The second modification type of the focusing guide shown in FIGS. 2 to 4 is omitted except that the focusing electrode 40 and the second metal grid plate 42 installed in FIGS. 2 to 4 are omitted. It is identical in form and works in the same way. However, as shown in FIG. 10, the lateral limit of electrons constituting the beam 346 is defined by the electrostatic force applied between the longitudinal crossing member 338b of the grid plate 338 and the conductor 34, and the crossing member ( 338b) by electrostatic force applied to the metal film 30 coated on the fluorescent screen 28 surface. The metal film 30 is applied with a high voltage of 2000V-8000V corresponding to the cathode potential required to generate electrons in the electron gun portion 16, for example, between the metal film 30 and the grid plate 338. If the gap of is separated by 17.02mm, a high voltage of about 5000V should be applied. However, the wider this interval, the higher the high pressure. Conversely, the narrower the spacing, the lower the high pressure should be applied.

As shown in FIG. 11, the periodic connection of the beams as the electron beams 346 move along the guides intersects between the conductors 334 and 336 and the transverse members extending along the transverse axis of the grid plate 338. By the electrostatic force applied between the 338a and the metal film 30. As described above in the focusing guide of FIGS. 2-4, the extraction of the electron beam 346 in the guide is accomplished by applying a low voltage of -10V to the conductor 334. Therefore, the focusing guide operates in the same manner as the focusing guide shown in FIGS. This focusing guide has an advantage that the structure is more simplified since it consists of only one grid plate as compared to the focusing guides shown in FIGS.

The focusing guides shown in FIGS. 2 through 4 and the focusing guides shown in FIGS. 10 through 11 are connected to the conductors 34 and 36 in FIGS. In FIGS. 10 through 11, the same voltages of 125V may be applied to the conductors 334 and 336. When all conductors have the same voltage, the circuit for the guide is simplified. In addition, because each set of conductors is combined with other adjacent sets of conductors, the width of each conductor becomes wider, resulting in a relatively small number of conductors.The operating drawback of these devices is that the electrostatic focusing meter reduces the focusing force on the beam and the handling of the guide. Current capacity is reduced.

12 to 14 show yet another form of focusing guide of the present invention that can be used in the display device 10. Each channel 26 of the envelope 12 located between the two supporting walls 24 has a plurality of focusing guides (four focusing guides are shown in FIG. 12). A strip of conductor 62 coated with a conductive material such as metal on the inner surface of back wall 20 transversely across.

The first metal grid plate 64 is designed to be isolated adjacent to the back wall 20 and extend transversely across the channel 26 to fit snugly in the groove on the support wall 24. As described above, in the first metal grid plate 64, the two intersecting members 70 and 68 cross each other longitudinally and laterally to form a plurality of the rectangular openings 66. The openings 66 are arranged longitudinally and horizontally along the channel 26. The openings in each of the abscissas each rest on a separate conductor 62.

The second metal grid plate 72 is a grid plate in which two crossing members 76 and 78 cross each other in the longitudinal and horizontal axes to form a plurality of rectangular openings 74. It is adjacent to the first metal grid plate 64 between the front walls 18 and laterally extends along the channel 26. The openings 74 of the second metal grid plate 72 lie in line with the openings of the first metal grid plate 64, respectively.

Looking at the size and location of this type of focusing guide, the longitudinal length of the conductor 62 is 1.25mm is disposed between the conductors 62, 64 at 0.25mm intervals. The first metal grid plate 64 is located about 0.25 mm away from the conductor 62 and the second metal grid plate 72 is located about 0.76 mm away from the first metal grid plate 64. The sizes of the openings 66 and 74 of the first and second metal grid plates 64 and 72 are rectangular openings having a horizontal length of 0.30 mm and a vertical length of 0.91 mm. The openings 66, 74 of each of these grid plates 64, 72 are located 1.78 mm horizontally 0.61 mm apart from the channel 26.

In operation of the display device having the focusing guide, a high voltage of 200 V is applied to each of the conductors 62 and a low voltage of 50 V is applied to the first and second metal grid plates 64 and 72, respectively. First metal grid plate 64 and second metal grid plate 72 to impinge upon fluorescent screen 28 through openings 66, 74 of two metal grid plates 64, 72 arranged in a phase. Direct to the focusing guide in between.

As shown in FIG. 13, the potential difference between the first metal grid plate 64 and the conductor 62 is the cross member 68 of the first metal grid plate 64 as indicated by arrow 82. An electrostatic force is generated between and the conductor 62. The electrostatic force meter indicated by the arrow 84 is a fluorescent screen with the longitudinal crossing member 76 of the second metal grid plate 72 due to the potential difference between the second metal grid plate 72 and the metal film 30. It is formed between the metal film 30 on 28. As described above with respect to the focusing guides shown in FIGS. 10 and 11, the metal film 30 is generally supplied with a high voltage of about 2000-8000 V, which is required to generate electrons in the cathode of the electron layer. The high pressure is applied differently depending on the distance between the metal film 30 and the second grid plate 72.

As shown in FIG. 14, the potential difference between the first metal grid plate 64 and the conductor 62 is equal to the lateral cross member 68 of the first metal grid plate 64 as indicated by the arrow 86. The electrostatic force is generated between the conductors 62. The potential difference between the metal film 30 of the second metal grid plate 72 is defined between the lateral crossing member 76 of the second metal grid plate 72 and the metal film 30 as indicated by the arrow 88. Generate power. The electrostatic force periodically focuses the electron beam by applying electrostatic force to the electron beam 80 when the electron beam proceeds along a straight path between the first metal grid plate 64 and the second metal grid plate 72. By all the electrostatic forces through the focusing guide of all the electrostatic force applied to the electrons of each electron beam 80 to limit the electrons forming the beam along the entire length of the non-pass passage. As in the form of the focusing guide described above, the extraction of the electron beam in this focusing guide is accomplished by switching the potential applied to the conductor 62 to a negative potential of -100V.

This focusing guide does not need to install a special conductor or focusing electrode to laterally limit the electrons forming the beam as in the focusing guide shown in FIGS. 5 to 6, so that the focusing guide shown in FIGS. It has the advantage of being simpler than the structure. In addition, all the conductors except the one switched to the negative potential to extract the beam are kept at the same potential to simplify the operation circuit and minimize the power loss. Although the focusing guide is complicated in structure because there is one more grid plate than the focusing guides shown in FIGS. 10 to 11, the focusing guide has the advantage that all conductors are maintained at the same potential. Although the focusing guides shown in FIGS. 10 and 11 operate with all conductors held at the same potential as described above, this connection guide has a long focusing force on the beam.

15 to 18 show a modified form of the focusing guide shown in FIGS. 12 to 14. This focusing guide has a plurality of conductors 162 extending transversely across the channel 26 and parallelly spaced on the rear wall 20, like the focusing guides shown in FIGS. 12-14; It includes first and second metal grid plates 164, 172 that extend laterally across the space of the channel 26 and fit snugly in grooves on the support wall 24. The first metal grid plate 164 has two sets of rectangular openings 166a and 166b, which are arranged along the channel 26 in horizontal rows, respectively. The row of openings 166b is designed to be located in the center of the row of openings 166a and the row of openings 166b between the row of openings 1662.

The openings 166b of each column extend laterally across portions of the openings 166a of each adjacent column. By overlapping the openings 166a and 166b in this manner, the ends of the openings overlap so that each opening is in such two longitudinal rows, and a plurality of longitudinal rows are formed.

The second metal grid plate 172 is also arranged with two sets of rectangular openings 174a and 174b which are arranged along the channel 26 in longitudinal and lateral rows, respectively, wherein the rows of openings 174b are formed of the openings 174a. The center row of rows and the row of openings 174b are designed to be located between the row of openings 174a. Since the openings 174b of each column extend laterally across portions of the openings 174a of each adjacent column, the ends of the openings 174a and 174b overlap so that each opening is in such two columns. To form heat storage.

Each horizontal heat storage of the opening 174a in the second metal grid plate 172 is directly above the horizontal heat storage of the opening 166a in the first metal grid plate 164, and corresponds to the second metal grid plate 172. The abscissa of the opening 174b is directly above each of the abscissas of the opening 166b in the first metal grid plate 164. However, each of the openings 174a in each row of the openings 174a of the second metal grid plate 172 extends between two openings 166a in the row of openings 166a of the first metal grid plate 164. It extends laterally across. Each opening 174b in each row of dogs 174b in the second metal grid plate 172 is also between two openings 166b in the row of openings 166b in the first metal grid plate 164. Extend laterally across;

When the display device 10 having the connection guide is operated, a high voltage of about 200 V is applied to each conductor 162, and a low pressure of about 50 V is applied to the first and second metal grid plates 164 and 172, respectively. The electron beam 180 is directed toward the connection guide between the first and second metal grid plates 164 and 172. Each electron beam 180 runs in a straight path extending along a vertical row overlapping the distal end of the opening in the grid plate.

As shown in FIGS. 16, 17, and 18, the potential difference between the first metal grid plate 164 and the conductor 162 is represented by the arrow 182. Forming a electrostatic force meter extending through the openings 166a and 166b of the circuit, and the potential difference between the second metal grid plate 172 and the conductor 162 is indicated by an arrow 184. To form an electrostatic force meter extending through the openings 166a, 166b. The above-described potential difference between the second metal grid plate 172 and the metal film 30 due to the high pressure is through openings 174a and 174b in the second metal grid plate 172 as indicated by arrow 185. The potential difference between the first metal grid plate 164 and the metal film 30 is formed by forming an elongated electrometer, and the openings 174a and 174b in the second metal grid plate 172 as indicated by arrows 186. Form a constant power meter extending through. The predeployment thus formed limits the electrons that make up the beam by applying electrostatic force to the electron beam 180 and surrounding the electron beam 180 as the beam travels along the guide passage. Extracting the electron beam from the focusing guide as in the other type of focusing guide described above is achieved by switching the potential applied to the conductor 162 to a negative potential.

This focusing guide has the advantage of providing a larger number of guides per side thickness of the envelope than the focusing guides shown in FIGS. 12-14. That is, in the apparatus shown in Figs. 12 to 14, only one beam guide is installed along each column of the grid plate opening, but in this embodiment, the beam path is provided along the side plate and each side end of the opening. If the two devices have the same side thickness and the size of the grid plate openings, then more than twice as many guides can be installed than the devices shown in Figs. The greater the number of connection guides, the greater the number of electronic beams that can be included in the display device.

FIG. 19 illustrates another modified form of focusing guide that may be used in the display device 10. This focusing guide includes a plurality of insulated and parallel conductors 262 extending transversely across the channel on the rear wall 20, such as the focusing guides shown in FIGS. 12-14 and 15-15. And first and gold second grid plates 264 and 272 extending laterally across the channel. A plurality of rectangular openings 266 are formed in the first metal grid plate 264, and a plurality of rectangular openings 274 are formed in the second metal grid plate 272.

The openings 266 and 274 of the first and second metal grid plates 264 and 272 are arranged in a zigzag manner as shown in Figs. 12 to 14, or as shown in Figs. 15 to 18. However, in this focusing guide, each row of openings 274 of the second metal grid plate 272 is not located directly above the row of openings 266 of the first metal grid plate 272, but the first metal grid plate opening 266. Longitudinally offset slightly) This offset towards the end injuries along the electron beam moving direction.

This focusing guide operates in the same manner as the focusing guides shown in FIGS. 12-14, 15-15, 18, depending on the arrangement of the grid plate openings, but with respect to the second metal grid plate opening 266. The longitudinal offset of the metal grid plate openings 274 generates electrostatic force around the electron beam 280 causing it to travel in wave form as the beam travels along a straight path between the grid plates.

As shown in FIG. 19, the electrostatic force applied to the electron beam 280 is directed toward the first grid plate 264 as the beam runs longitudinally across each opening 266 in the first metal grid plate 264. It should be slightly deflected and slightly deflected toward the second metal grid plate 272 as it progresses longitudinally across each opening 274 in the second metal grid plate 272. In order to extract the electron beam 280 from the focusing guide 260, the potential applied to the limiting conductor (for example, the conductor 262a) of the conductor is switched to a negative potential, thereby applying an electrostatic force to the electron beam, and thus the second beam After deflecting through the adjacent opening 274a of the metal grid plate 272, it exits from the focusing guide toward the fluorescent screen 28 as shown in FIG. Since the electrostatic force required to advance the electron beam 280 to the second metal grid plate opening 274a portion using the above-described wave type passage is less required than when not using the wave type passage, FIG. The electron beam may be extracted at a voltage lower than the voltage required to extract the electron beam from the focusing guide shown in FIGS. 14 and 15 to 18.

In the focusing guide shown in FIGS. 10 to 11 composed of a single metal grid plate 338, the electron beam 346 can be moved in a wave form with respect to the conductor 334 according to the propagation direction of the beam 346. This is possible by slightly moving the position of the opening 338c in the longitudinal axis.

Although the display device 10 is shown as having a support wall 24 between the rear wall 20 and the front wall 18 to prevent destruction of the vacuum envelope 12, the support wall 24 is shown. Any support, such as a support column, may be used instead of the support wall. However, whatever type of support 24 is used between the front wall 18 and the rear wall 20, it provides a channel 26 that extends from the gun portion 16 to the side wall 22 opposite the gun portion. It must be designed. In addition, although the display device 10 is designed as a plurality of independent grid plates that extend laterally across each channel and fit into grooves on the support wall, each grid plate may also be manufactured as a single plate that extends across all channels. Can be. The display device 10 has an additional grid that focuses or accelerates the electron beam when the electron beam progresses from the focusing guide toward the fluorescent screen 28 between the metal film 30 and the focusing guide on the fluorescent screen 28. Can be provided. In the good function of the display device shown in Figs. 10-19, which utilizes the potential difference between the metal film 30 and one of the grid plates to provide part of the focusing force to the electron beam, such an additional Including the grid, the potential difference between the grid plate of the focusing guide and the adjacent grid plate sore can be used to provide the expected part of the limiting force.

Claims (1)

A vacuum envelope 12, a fluorescent screen 28 in the envelope, an electron gun portion 16 in the envelope which generates electrons and directs along a plurality of straight paths parallel and isolated to the fluorescent screen, In a display device (10) consisting of a guide device for focusing electrons along a straight path into a beam and deflecting the focused beam toward a fluorescent screen at a selected point along the straight path, the guide device is the opposite side of the fluorescent screen. A plurality of insulated conductors 34, 36; 134, 136; 234, 236; 334, 336; 62; 162; 262, which are located at and extending laterally each beam passage; Metal grid plates (38, 42; 138, 142; 238; 338; 64, 72; 164, 172; 264, 272) isolated in parallel to the non-pass passages and generate static power to laterally limit the beams in each of the non-pass passages. Parallel to both opposing sides of each beam path And a device (38b, 40; 136a, 138a; 338b; 68, 76; 164, 172; 264, 272) extending along the lines.

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