RU21980U1 - ELECTRIC LAMP - Google Patents

Abstract

1. An electronic lamp containing a cathode, a grid, an anode and a vacuum-tight shell, characterized in that the grid is made wound with the ability to change the number of turns. 2. The lamp according to claim 1, characterized in that the anode is made of metal or graphite, the outer surface of which is coated with sintered titanium powder. The lamp according to claim 2, characterized in that the anode terminal is located in the lower base using an additional insulating element. The lamp according to claim 2, characterized in that the anode terminal is located in the dome of a vacuum-tight shell, while a ceramic ring is introduced between the glass shell and the metal upper base. A lamp according to any one of claims 1 to 4, characterized in that the lower base of the vacuum-tight shell is made of white glazed ceramic with rounded edges. A lamp according to any one of claims 1 to 5, characterized in that springing metal bridges connected to the mica plate are introduced to fix the reinforcement in the upper part of the vacuum-tight shell. A lamp according to any one of claims 1 to 6, characterized in that the vacuum-tight shell is made in a curved shape or a cylindrical shape, as close as possible to the reinforcement.

Description

The utility model relates to the field of electronic technology, namely, to the design and manufacture of adhesive vacuum tubes.

Known electronic lamp 1 with an additional anode grid made wound or rod. A linear electronic amplification device 2} is known with a grid made in the form of a microchannel plate. Known electron tubes described in book 3, containing: a source of eleurons - a heated direct-cathode cathode or podofevny; electron receiver - anode; vacuum tight shell; a grid that controls the electron flow from the cathode to the anode.

The G-811 ODO.Z31.039 TU 4 electronic lamp, which is selected as a prototype, has the same constructive construction. This is a generator triode with a gain of 160 and a dissipation power of up to 45 W, but which cannot be used in amplifiers.

The main disadvantage of existing electronic lamps is a cumbersome design and low mechanical strength, which does not meet modern requirements for the design of sound equipment.

The technical result, which is directed to a utility model, is to create a basic variable design that allows you to use the triode, depending on the manufacturing option, as an amplifier in kpasses A, AB, B, and as a generator for various thermal fuses on the anode. Moreover, the absence of microphone noise and good aesthetic qualities will make it possible to use the triode in amplifiers with high design requirements and get soft sound and high fidelity.

The goal set by the authors is achieved due to the fact that in an electronic lamp containing a cathode, grid, anode and vacuum a tight shell, the grid is made in the form of a spiral wound on traverses with a varying number of turns and different wire diameters for various versions. The number of turns is determined by the formula given in information source 3 and is confirmed empirically. In practice, the grid parameters are in the range: p 0.2 - 5 mm, d 0.05 0.35 mm.

Design differences (options) electronic lamp are in the implementation of its elements. In the proposed electronic lamp, the anode is made of metal or fafite, the outer surface of which is coated with sintered titanium powder. The output of the anode can be located in the lower base using an additional insulating element or in the dome of a vacuum tight shell, while between the glass shell and the metal

N01L1UOO

Electric lamp

a ceramic ring is introduced in the upper base. The lower base of the llama is made of white glazed ceramic with rounded edges. To fix the reinforcement (anode, mesh, fepp) in the upper part of the vacuum tight shell, springy metal jumpers connected to the mica plate are introduced. The vacuum tight shell is made in a curved or cylindrical shape, as close as possible to the reinforcement.

The essence, advantages and distinctive features will become clear from the description, which is accompanied by phafic material. In the drawing, Fig. 1 shows a lamp with a figured bulb and an anode terminal located in the dome of a vacuum tight shell and a diagram of the mutual arrangement of the reinforcement nodes. The drawing shows 1 - vacuum-tight shell (flask), 2 - lower base, 3 - upper base, 4 - ceramic ring, 5 - pins, 6 - key. In the drawing of FIG. 2 with a figured bulb and an anode terminal located in the lower base. In the drawing Fig.Z. presents a lamp with the output of the anode located in the dome of a vacuum tight shell having a cylindrical shape. In the drawing, Fig. 4 shows a lamp with anode output located in the lower base and with a cylindrical bulb shape.

This development allowed us to create a series of amplification lamps that provide high-quality sound at maximum power in the Hi-End class amplifiers.

The task of creating an original lamp is achieved in two ways; constructive solutions that provide the required output parameters and improve the appearance, ensuring the competitiveness of the lamp in the foreign market for creating equipment based on it with an original layout and design solution. Practically in the manufacture of the lamp can vary relative to the base model in a wide range of structural and parametric features, depending on the requirements of the equipment.

Depending on the mesh design, the lamp provides an average gain of 3, 10, 30, 160, respectively, which greatly expands the scope of triodes. The transfer of the output of the anode to the lower base with the use of an additional insulating element ensures the safety of the lamp in the base equipment and makes it possible to design amplifiers with an external arrangement of lamps, which corresponds to modern requirements for the design of sound equipment (Fig. Z, 4). The implementation of the base of the device from white glazed ceramics with rounded edges increases operational (mechanical and physical) characteristics, electrical strength, reduces electrical losses. Its appearance corresponds to more

HIGH aesthetic requirements compared to the widespread standard plastic base in brown or black. The upper mica plate for fastening and centering the reinforcement in the upper part of the bulb is equipped with metal spring jumpers, which can significantly reduce microphone noise, which improves sound quality. In addition, this design increases the mechanical strength of the instrument reinforcement, which allows it to be used with a horizontal geometric axis. By replacing the metal anode with a monolithic graphite anode, a 4-fold increase in the power dissipated by the anode is possible, while maintaining small dimensions. The increase in heat transfer from the anode is ensured by a coating of titanium powder on the outer surface of the anode, which, in turn, using a graphite anode made it possible to reduce the size of the lamp by a quarter due to the transition to the cylindrical shape of a vacuum tight shell (Fig. 3, 4). The titanium coating of the surface of the anode allows the absorption of gases emitted during lamp operation in a wide range due to the temperature gradient and makes it possible to refuse to use the getter as a separate element in the lamps. When placing the output of the anode in the dome of the bulb, a ceramic ring is provided to reduce the thermal and mechanical stresses on the anode, thereby increasing the reliability and mechanical strength of the lamp.

Used sources of information

1. RF patent No. 2034355 IPC: BUT 1J21 / 00. Published on 04/30/95

2. RF patent No. 2133066 IPC: BUT 1J21 / 10, published on 10.06.99

3. Tsarev B.M. Calculation and design of electronic tubes. M., Energy 1967, pp. 21-24, 94-95.

4. Technical conditions of ODO .331.039 TU Electronic lamp G-811.

Claims (7)

1. An electronic lamp containing a cathode, a grid, an anode and a vacuum-tight shell, characterized in that the grid is wound with the ability to change the number of turns.  2. The lamp according to claim 1, characterized in that the anode is made of metal or graphite, the outer surface of which is coated with sintered titanium powder.  3. The lamp according to claim 2, characterized in that the anode terminal is located in the lower base using an additional insulating element.  4. The lamp according to claim 2, characterized in that the anode terminal is located in the dome of a vacuum-tight shell, while a ceramic ring is introduced between the glass shell and the metal upper base.  5. A lamp according to any one of claims 1 to 4, characterized in that the lower base of the vacuum-tight shell is made of white glazed ceramic with rounded edges.  6. A lamp according to any one of claims 1 to 5, characterized in that spring metal bridges connected to the mica plate are introduced to secure the reinforcement in the upper part of the vacuum-tight shell. 7. The lamp according to any one of claims 1 to 6, characterized in that the vacuum-tight shell is made in a curved shape or a cylindrical shape, as close as possible to the reinforcement.