Abstract: In the present invention, a high-voltage side electrode constituent part includes a dielectric electrode and metal electrodes formed on the upper surface of the dielectric electrode. The dielectric electrode has a structure in which a film thickness is continuously changed along an X direction. That is, the film thickness of the right end of the dielectric electrode is set to a thickness dA1; and the film thickness of the left end is set to a thickness dB1 (>dA1), and is continuously increased from the right end to the left end along the X direction.

Abstract: An apparatus includes a laminated bus bar assembly with first and second bus bars and an intervening insulator layer. A surge arrestor (e.g., a metal oxide varistor) has a body mounted on the bus bar assembly and first and second terminals on first and second opposite sides of the body. In some embodiments, the body may be at least partially disposed in an opening in the first bus bar and the second terminal may be conductively bonded to a surface of the second bus bar that faces the insulator layer. In some embodiments, the second terminal may include a conductive stud passing through an opening in the second bus bar. The apparatus may include a spring clamp attached to the first bus bar and contacting the first side of the body to retain the body.

Abstract: A semiconductor device includes a substrate, a device layer, color filters and a passivation layer. The device overlies the substrate, and has a first surface and a second surface opposite to the first surface. The device layer includes a grid structure disposed on the second surface of the device layer, and the grid structure includes cavities. The first surface of the device layer is adjacent to the substrate. The color filters fill in the cavities. The passivation layer is disposed on the second surface of the device layer, and covers the grid structure and the color filters.

Abstract: An overcurrent protection device comprises a current input terminal; a central terminal for output of current overshoots; and a terminal for output of non-impulse currents connected to a voltage of the central terminal. An electrical conductor element is connected between the input and output terminals at a reduced self-induction when operating without current overshoots. When current overshoots are present at the input terminal, the conductor produces a high drop of induction voltage between the input and output terminals. The central terminal is arranged in the vicinity of the input terminal at a distance that may be regulated. When due to current overshoot, the inductive voltage drop between the input and the non-impulse current output terminals exceeds the dielectric strength of the material present between the input and central terminals, an arc is generated between the input and central terminals to prevent the flow of current overshoots through the conductor element.

Abstract: A neutral beam source has a plasma sheath-shaping neutralization grid that shapes a plasma sheath near a beam-forming slit of the neutralization grid in accordance with a desired entry angle of incoming ions in the slit.

Abstract: Provided is a dielectric barrier discharge-type electrode structure for generating plasma.

Abstract: A spark plug is disclosed and comprises: a metal tube which interiorly defines an axis and is externally-threaded for engine block engagement; an insulator having a portion which is disposed inside the tube and extends therebeyond; a positive electrode extending through the insulator and projecting beyond the extending portion of the insulator; and an annular ground electrode coupled to the tube. The electrodes are configured such that a spark gap defined therebetween comprises an elongate channel which opens axially and away from said insulator and is substantially unobstructed in the axial direction.

Abstract: This invention relates to dielectric barrier discharges devices. More particularly, it relates to dielectric barrier discharge apparatus which employ a dielectric barrier disposed within the discharge gap between spaced apart electrodes to generate a plasma when subjected to pulsed high voltages. The dielectric barrier material has a high thermal conductivity and is held in physical contact with a heat sink which aids in dissipation of thermal energy released in formation of the plasma.

Abstract: An electron emitting device includes a lower electrode, a surface electrode, an electron acceleration layer between the lower electrode and the surface electrode, and an electrode selecting unit. The electron acceleration layer is made of at least an insulating material. At least one of the lower electrode and the surface electrode is a stripe-pattern electrode including a plurality of unit electrodes that are regularly arranged. The electrode selecting unit sequentially selects, from among the plurality of unit electrodes, a unit electrode to which a voltage is to be applied. A voltage is applied between the lower electrode and the surface electrode to accelerate electrons between the lower electrode and the surface electrode, so that the electrons are emitted from the surface electrode.

Abstract: An insulation structure of high voltage electrodes includes an insulator having an exposed surface and a conductor portion, which includes a joint region in contact with the insulator, and a heat-resistant portion provided, along at least part of an edge of the joint region, in such a manner as to be adjacent to the exposed surface of the insulator. The heat-resistant portion is formed of an electrically conductive material whose melting point is higher than that of the conductor portion. The heat-resistant portion may be so provided as to have a gap between the insulator and the exposed surface.

Abstract: An igniter having at least two electrodes spaced from each other by an insulating member having a substantially continuous surface along a path between the electrodes. The electrodes extend substantially parallel to each other for a distance both above and below said surface. The insulating member has a channel (recess) for receiving at least a portion of a length of at least one of said electrodes below and to said surface of the insulating member. The surface of the insulating member may preferably be augmented with a conductivity enhancing agent. The insulating member and electrodes are configured so that an electric field between the electrodes at said surface does not have abrupt field intensity changes, whereby when a potential is applied to the electrodes sufficient to cause breakdown to occur between the electrodes, discharge occurs at said surface of the insulating member to define a plasma initiation region.

Abstract: A plasma generator has a dielectric with a through hole and has a first electrode and a second electrode provided in the dielectric. The first electrode surrounds the through hole when viewed in the penetrating direction of the through hole. The second electrode includes a downstream region which is positioned further toward one side of the through hole in the penetrating direction of the through hole than the first electrode. When viewed in the penetrating direction of the through hole, the downstream region surrounds the through hole and is further away toward the outer circumferential side from the inner circumferential surface of the through hole than the first electrode.

Abstract: An illuminating apparatus used for a display device includes a plurality of illuminating units, each of which includes a first feeding member, a second feeding member, and a cold-cathode tube lamp that is fed by a power supply apparatus via the first and second feeding members. An equivalent circuit of each illuminating unit is a series combination of negative resistor and a capacitor connected to an end of the negative resistor. The illuminating units are arranged such that the capacitors of the cold-cathode tube lamps are alternate in position. This can reduce the brightness gradient for the position in the tubular axis direction of the lamp.

Abstract: An illuminating device for a display device includes a tube lamp which can be driven in parallel by power supplied from a power supply device through a first power supply member and a second power supply member; the first power supply member; and the second power supply member. The illuminating device is provided with illuminating sections whose equivalent circuit is a serially connected body having capacitors connected to the both ends of a negative resistance. The illuminating sections are driven in parallel by separating them into two systems.

Abstract: An antistatic film installed in an airtight vessel containing an electron source of an electron-generating device such as a picture display unit has a structure comprising an image of conductor or semiconductor particles with particle diameters of 0.5 to 10 nm dispersed in a medium containing a nitride, an oxide or both; and thereby improves controllability for a resistivity value, stability and reproducibility, and the adequate temperature characteristics of resistance.

Abstract: An electron gun (1) includes an emitter (2), a tubular support (3) and an adaptor (4) for receiving the emitter. The adaptor includes a tapered plugging surface (7) and the tubular support includes a correspondingly tapered seating surface (9) for receiving the plugging surface. The plugging surface and seating surface have conical profiles which help to position the adaptor concentrically with the support.

Abstract: Method for manufacturing a high-energy, low-voltage ignition plug comprising a ceramic material between its electrodes: there is mixed, in a container containing a liquid, from 50 to 75% of a compound which is intended to form a conductive phase and from 25 to 50% of one or more materials which allow the formation of phases of yttrium garnet after thermal processing; operations are carried out for pulverizing, drying and sieving the admixture; the admixture is pressed or injected into a mould; sintering is carried out so as to obtain a ceramic material having porosity of between 0 and 30%; the ceramic material is used in order to constitute the material located between the electrodes of a high-energy, low-voltage ignition plug. Ignition plug manufactured in that manner.

Abstract: A cold cathode tube lamp is fed with power from a first conductive member and a second conductive member provided outside in a mounted state, and includes a glass tube, first and second internal electrodes provided inside the glass tube, a first external electrode provided outside the glass tube and connected to the first internal electrode, a second external electrode provided outside the glass tube and connected to the second internal electrode, a first insulating layer coated on the first external electrode, and a second insulating layer coated on the second external electrode. In a mounted state, the first conductive member and the first external electrode are capacitively coupled together, and the second conductive member and the second external electrode are capacitively coupled together. With such a structure, parallel lighting can be achieved by parallel driving.

Abstract: There is provided a new electron beam apparatus which improves the instability of an electron emission characteristic and provides a high efficient electron emission characteristic. The electron beam apparatus includes: an insulating member having a recess on its surface; a cathode having a protruding portion extending over the outer surface of the insulating member and the inner surface of the recess; a gate positioned at the outer surface of the insulating member in opposition to the protruding portion; and an anode positioned in opposition to the protruding portion through the gate.

Abstract: An electron emission device includes a base substrate, at least one isolation layer on the base substrate, the isolation layer having a first lateral side and a second lateral side opposite the first lateral side, first and second electrodes on the base substrate along the first and second lateral sides of the isolation layer, respectively, a first electron emission layer between the first electrode and the first lateral side of the isolation layer, and a second electron emission layer between the second electrode and the second lateral side of the isolation layer.

Abstract: A barrier rib structure of plasma display panel is disclosed. The barrier rib structure includes a plurality of vertical barrier ribs arranged in parallel, a plurality of first horizontal barrier ribs connected to one side of the vertical barrier ribs, and a plurality of second horizontal barrier ribs connected to the other side of the vertical barrier ribs, in which the first horizontal barrier ribs are disposed alternately with corresponding second horizontal barrier ribs for forming a plurality of double blockade structures. Additionally, a gas passage and a plurality of electrical discharge spaces are formed between the double blockade structures.

Abstract: To allow an image display device which includes a plurality of distance holding members (spacers) which are arranged in the inside of a display region to acquire a prolonged lifetime, high brightness and high reliability while preventing charging of the spacers, a conductive film is arranged on a bottom surface of the spacer and the conductive film is covered with an adhesive material.

Abstract: To provide a resin composition for spacer useful for the formation of a pixel-patterned spacer on a substrate in a liquid crystal display device, a spacer using the composition, and a liquid crystal display device that can display high-quality images, a resin composition for spacer contains at least one resin selected from (1) an allyl-containing resin, (2) an allyl-and-hydroxyl-containing resin, and (3) a resin mixture of an allyl-containing resin and a hydroxyl-containing resin.

Abstract: A high intensity discharge lamp includes a dielectric substrate, a first electrode near the dielectric substrate, a second electrode spaced from the first electrode and near the dielectric substrate, with a discharge gas contained and enclosed by a shaped reflector and window. The reflector shapes are adapted to the particular process. The lamp to be used in volumetric chambers with high reflectivity walls and in arrangements of multiple lamps for high processing rates and long penetration lengths. Erosion of the dielectric is controlled by the use of high-pressure gases, and filtration and the use of electric fields reduce lamp contamination. The dielectric and electrodes are gas cooled on the outside and through the use of perforated electrodes. A small diameter tubular dielectric is used to increase light emission, improve re-imaging capability and increase the electrical impedance.

Abstract: An image-forming apparatus with good yield and high reliability is provided by devising and improving the shape of a supporting member. Therefore, a flat type image-forming apparatus has at least a rear plate, a face plate arranged oppositely to the rear plate, and a supporting member arranged between the rear plate and the face plate and holding the distance between the rear plate and the face plate in an outer circumferential edge portion. In this flat type image-forming apparatus, the shape of a nook portion of the supporting member is set to an arc shape on the inner or outer side of a container.

Abstract: To provide a light emitting device having a highly definite pixel portion. An anode (102) and a bank (104) orthogonal to the anode (102) are formed on an insulator (101). A portion of the bank (104) (controlling bank 104b) is made of a metal film. By applying a voltage thereto, an electric field is formed, and a track of an EL material that is charged with an electric charge can be controlled. Thus, it becomes possible to control a film deposition position of an EL layer with precision by utilizing the above method.

Abstract: In one embodiment of the present invention, the ion optics for use with an ion source have first and second electrically conductive grids having mutually aligned respective pluralities of apertures through which ions may be accelerated and wherein each has an integral peripheral portion. There is also a support member. There are first and second series of seats around the respective peripheral portions of the first and second grids. A plurality of first spherical insulators are distributed between seats of the first and second series, thereby establishing a predetermined distance between the grids while still enabling radial movement between their peripheral portions. There are third and fourth series of seats around the support member and the peripheral portion of the second grid, respectively, with seats of the fourth series displaced from those of the second series in the same grid.

Abstract: In the present invention, it is possible to implement a small size and light PDP apparatus by integrally forming a panel unit and a driving circuit unit on a single substrate. A panel unit(discharge cells) of the PDP is formed on one surface of a flat metallic substrate, and a driving circuit unit is formed on the other surface of the same. Namely, in the PDP apparatus having a panel unit formed of a plurality of discharge cells, and a driving circuit unit for supplying a power and signal to the panel unit, the PDP apparatus includes a metallic lower substrate, a first insulation layer formed on an upper surface of one side of the metallic lower substrate, an upper substrate formed opposite to the one side of the metallic lower substrate, a plurality of barriers formed between the metallic lower substrate and the upper substrate for defining a plurality of discharge spaces, and a second insulation layer formed on another surface of the metallic lower substrate and including the driving circuit unit thereon.

Abstract: A color two substrate alternating plasma display panel. The panel includes two tiles joined together so as to be opposite each other and defining a space therebetween. The space is filled with gas. One of the tiles has column electrodes which are approximately parallel, separated by a spacing and covered with at least one phosphor region. The other tile has at least one row electrode. The phosphor regions are provided with at least one recess placed at the intersection of a column electrode with the row electrode. A color pixel is formed by neighboring recesses lying within the same row electrode in adjacent phosphor regions. In order to obtain better light efficiency, the distance separating two adjacent recesses lying within adjacent phosphor regions and belonging to the same pixel is greater than the spacing so that space has a thickness greater than that required when two recesses are separated by approximately the spacing.

Abstract: Barrier in a color plasma display panel (PDP) and a method for manufacturing the same are disclosed; the partion of the color plasma display panel (PDP) including a barrier formed of frit glass between upper and lower substrates each having electrodes of a regular interval for making a cell; and the method including the steps of coating a frit glass paste of a predetermined thickness on the lower substrate, drying and baking the coated frit glass paste to form a frit glass, defining unnecessary portions on a surface of the frit glass, and removing the unnecessary portions of the frit glass to form frit glass barriers spaced regular intervals apart from one another.

Abstract: An image forming apparatus includes a substrate, an electron-emitting device, a wiring electrode for applying an input signal to the electron-emitting device, and an image forming member to which an electron emitted from the electron-emitting device is irradiated. An acceleration electrode is provided opposite to the substrate, and a potential defining electrode is provided between the acceleration electrode and the substrate. A second support member connects the potential defining electrode and the acceleration electrode, and a first support member connects the wiring electrode and the potential defining electrode. The second support member has a semiconductive material surface, and the first support member has a resistance greater than that of the second support member by ten times or more.

Abstract: The present invention provides image display panels, spacers and spacer units for the same and methods for making and using the same. The spacer units include an assembly having a first layer of generally parallel fibers positioned to form intersections with generally parallel fibers of a second layer. At least one fiber of the first and/or second layer includes a bonding agent at the corresponding intersection. The intersections form passageways which permit the passage of energy therethrough between the emitter and the display of an image display panel. A sealing frame is positioned about and engages the periphery of the spacer, the emitter and the display. The sealing frame has a deformable sealing material for providing an essentially sealed region between the spacer, emitter and display. Methods of making and using such spacers in image display panels and spacers including a fiber protectorant are also included in the present invention.

Abstract: The present invention provides image display panels, spacer units for the same and methods for making and using the same. The spacer units include an assembly having at least one layer of generally parallel fibers which form passageways which permit the passage of energy therethrough between the emitter and the display of an image display panel. A sealing frame has a support which is positioned about and engages the periphery or side of the spacer, the emitter and the display. The sealing frame has a sealing material for providing an essentially sealed region between the spacer, emitter and display. Methods of making and using such spacer units in image display panels are also included in the present invention.

Abstract: A spacer (200) for a field emission display (201) is disclosed. The spacer (200) includes a lower resistive region (220) and an upper insulative region (222). The spacer (200) has a member (210) which is coated with a resistive coating (212) extending between the lower end of the member and a height (h.sub.2) less than the total height (h.sub.1) of the spacer (200). An insulative coating (218) is formed on the member (210) and extends between the upper end of the resistive coating (212) and the upper end of the member (210). The resistive coating (212) has a secondary electron yield less than 2 over the lower resistive region (220) of the spacer (200). The insulative coating (218) has a secondary electron yield between 0.75-2 over the upper insulative region (222) of the spacer (200).

Abstract: A plasma display panel comprising mutually opposing substrates and barrier ribs formed between adjacent pixels of a display between the substrates, wherein the barrier ribs are made of a fired product of a glass ceramic composition consisting essentially of a glass powder of P.sub.2 O.sub.5 type glass and a low expansion ceramic powder.

Abstract: A plasma display panel is provided which includes (a) a first substrate, (b) a second substrate, (c) a plurality of sets of electrode pairs extending in a direction A, (d) a partition wall structure formed overlapping the sets of electrode pairs, the partition wall structure including first partition walls extending in a direction B perpendicular to the direction A and second partition walls extending in parallel with the direction A, each of the first and second partition walls defining a cell therein, and (e) third partition walls extending in the direction B. The sets of electrode pairs, the partition wall structure and the third partition walls are arranged in this order between the first and second substrates. The first partition walls have a width W.sub.H greater than a width W.sub.D of the third partition walls.

Abstract: A plurality of filaments are stretched in parallel on a rear plate, and an insulating plate is provided so as to cover the filaments. In the insulating plate, a plurality of through-holes are formed along the longitudinal direction of the respective filaments for exposing parts thereof. Each through-hole and phosphor layers, which are provided on the insulating layer adjacent to the through-hole, constitute one unit picture element. The respective phosphor layers in the respective picture element are installed in a plurality of cavities formed in a rib provided on a lower surface of the insulating plate, whereby separated from the neighboring phosphor layers. The respective cavities function as a discharge room, with a light-transmissive front plate, formed on the rib, as a lid and a portion of the insulating plate corresponding to the phosphor layer as a bottom. The respective discharge rooms overlap the through-hole at one end in the longitudinal direction thereof.

Abstract: A flat panel device contains a faceplate, a backplate, a light-emitting mechanism, and a spacer. The faceplate is connected to the backplate to form a sealed enclosure. The spacer is situated within the enclosure and supports the two plates against forces acting towards the enclosure. The spacer can take various forms and can be constituted with various materials. In one embodiment, the spacer includes a spacer wall formed with multiple sheets of laminated material consisting of ceramic, glass-ceramic, ceramic reinforced glass, devitrifying glass, or metal coated with electrical insulation. In another embodiment, the spacer includes a spacer wall having a surface that follows a non-straight path adjacent the faceplate. In yet another embodiment, the spacer is a spacer structure through which a plurality of holes extends. The light-emitting mechanism is typically implemented with an electron-emitting cathode and light-emissive material situated over the faceplate.

Abstract: An optical device contains first and second plates (302 and 303), a pattern of ridges (314) situated over the first plate, light-emissive regions (313) situated in spaces between the ridges, electron-emissive elements (309) situated over the second plate, and supporting structure (308) that maintains a desired spacing between the plates. The electron-emissive elements emit electrons that strike the light-emissive regions, causing them to produce light of various colors. The ridges, which extend further away from the first plate than the light-emissive regions, are substantially non-emissive of light when hit by electrons. Each ridge includes a dark region formed with metal, ceramic, semiconductor, or/and carbide. The ridges thereby form a raised black matrix that improves contrast and color purity.

Abstract: A plasma processing apparatus capable of widening a distance of a narrow gap formed along peripheral portions of the opposed electrodes without deterioration of the efficiency. In the apparatus, two electrodes are provided in parallel to each other within a vacuum processing chamber, and a surface of a wafer supported by either one of these electrodes is processed by reactive gas plasma produced between the electrodes by applying high frequency power to one of the electrodes, a narrow gap portion whose gap distance is narrower than that of an opposite space sandwiched between central portions of the two electrodes is formed along peripheral portions of the two electrodes, an ground shield made of conductive material is provided via an insulating member so as to cover the outer side surface of one electrode, the ground shield covers an outer surface of the electrode, and an annular extension portion which extends into the narrow gap portion is provided inside an edge portion of the ground shield.

Abstract: A light-emitting structure (306) contains a main section (302), a pattern of ridges (314) situated along the main section, and a plurality of light-emissive regions (313) situated in spaces between the ridges. The light-emissive regions produce light of various colors upon being hit by electrons. The ridges, which extend further away from the main section than the light-emissive regions, are substantially non-emissive of light when hit by electrons. Each ridge includes a dark region. The ridges thereby form a raised black matrix that improves contrast and color purity. The dark region of each ridge may be formed with metal, ceramic, semiconductor, or carbide. Each ridge may include an additional region (314b) of different chemical composition than the dark region.

Abstract: A spacer 40 for use in a field emission device includes a comb-like structure having a plurality of elongated filaments 42 joined to a support member 44. The filaments 42, which may be glass, are positioned longitudinally in a single layer between the facing surfaces of the anode structure 10 and the electron emitting: structure 12. Support member 44 is positioned entirely outside the active regions of anode structure 10 and emitting structure 12. Spacer 40 provides voltage isolation between the anode structure 10 and the cathode structure 12, and also provides standoff of the mechanical forces of vacuum within the assembly. In a second embodiment, spacer 50 includes elongated filaments 52 joined at each end to a support member 54 a and 54b, the additional support facilitating handling, fabrication and assembly.

Abstract: In a flat display device, for example, a luminescent display a spacer structure (5) is provided between two substrates (1, 3). To this end a mask (9, 15) consisting, if necessary, of a plurality of layers is incorporated in a photosensitive material (8, 13). After exposure, development and removal of the mask, the desired spacer structure is obtained.

Abstract: A planar discharge plasma display device which can be easily manufactured and has low optical loss includes a front and a rear plate, a plurality of anode signal lines and cathode signal lines arranged in an X-Y matrix on the rear plate and insulated so as not to be exposed to a discharge space. Anodes and cathodes protrude from the anode signal lines and cathode signal lines, respectively, near the intersections of the anode signal lines and the cathode signal lines. Barrier ribs are stacked on the anode signal lines and lodged between the anode signal lines and the front plate.

Abstract: There is disclosed a display apparatus including a rear electrode unit, electron beam generating sources, a front electrode unit including a plurality of electron beam control electrodes laminated together with insulating spacers therebetween, and a face plate formed with a fluorescent screen. The front electrode is coupled together by first metallic coupling pins fixed on the electron beam control electrode arranged to confront the fluorescent screen. The rear electrode unit is coupled with the electrode unit by second metallic coupling pins fixed to one of the electron beam control electrodes other than the electron beam control electrode confronting the fluorescent screen.

Abstract: Fabrication of spacer supports for use in field emitter displays through a process which involves 1) forming a mold for the spacers in a substrate through the use of micro-saw technology, 2) filling the mold with a material that is selectively etchable with respect to the mold, 3) optionally, planarizing the excess material to the level of the mold using chemical mechanical planarization, 4) attaching the filled mold to one of the electrode plates of the field emitter display, and 5) etching away (removing) the mold, after which 6) the plate can be aligned with its complementary electrode plate, and 7) a vacuum formed.

Abstract: A grid assembly for ion beam sources includes grid structures that are etched from a semiconductor wafer using microelectronic fabrication techniques with the grid structures constrained in an aligned manner by a ceramic carrier having embedded electrically conductive pads for effecting electrical contact with the grid structures. The grid structures are fabricated by creating oxide and photoresist layers on a starting silicon wafer and exposing the photoresist through a mask carrying the aperture pattern. After the photoresist is developed, the oxide layer is etched to form openings therethrough and the silicon wafer is anisotropically etched from both sides with the etching proceeding anisotropically so that the {111} planes are etched to form the apertures in which the {111} planes face each other across the aperture with opposite {111} planes at a 90.degree. angle relative to one another to provide a plurality of apertures each defining a volume in the form of an inverted truncated 4-sided pyramid.

Abstract: The invention is directed to a high-voltage lead-through arrangement for introducing a high voltage into an enclosure wherein a vacuum is maintained such as for particle-beam apparatus. The arrangement includes: a high-voltage electrode for carrying a high potential; an insulator enclosing the high-voltage electrode and having a surface defining a boundary with the vacuum; and, an outer low-voltage electrode surrounding the insulator for carrying a low potential. The electrodes are spaced from each other by an electrode spacing measured along the surface of the insulator. The high-voltage electrode and the insulator conjointly define a first region wherein the high potential is present to a good approximation; and the first region is bounded by the insulator surface for a first distance of up to approximately 1/10 of the electrode spacing.

Abstract: A matrix addressed flat panel display, is disclosed herein and includes a lower planar array of spaced apart, parallel, electrically conductive leads and a matrix array of field emission cathodes connected to and extending up from the lower planar array of electrically conductive leads. An upper matrix array of spaced-apart parallel electrically conductive leads is located above and spaced from the lower array of leads and from the cathodes, such that the upper leads extend normal to the lower leads, crossing the latter immediately above the cathodes, and such that those segments of the upper leads that actually cross over the lower leads are positioned in a plane closer to the lower leads than the rest of the upper leads. The upper and lower planar arrays of leads are electrically insulated from one another by means of a pair of separately formed layers of dielectric material disposed therebetween.

Abstract: The disclosure concerns electron tubes. A tube such as a cathode-ray tube consists of several parts, namely the stem, the neck, the cone and the screen of the front face. To build a tube such as this more compactly while, at the same time, improving the quality of the fabrication, a new construction of the neck is proposed. In the prior art, the neck is a glass tube to which there is soldered a glass stem through which pass the connection terminals towards the various electrodes, internal to the tube. Here, the neck is built in the form of a stack of alternating metallic rings and ceramic rings. The metallic rings are used for the supporting of and electrical connection to the internal electrodes. The ceramic rings are used to insulate the metallic rings. The brazings between metallic rings and ceramic rings provide for vacuum tightness. The base of the tube is a ceramic washer without drillings other than lateral ones for the connections to pass through.