RU169962U1 - Low pressure sodium lamp - Google Patents

Abstract

The utility model is aimed at expanding the scope of the optical radiation source. The low-pressure sodium lamp contains a vacuum flask 1 made of an optically transparent material, equipped with elements of an external current supply 2, with a sealed discharge tube 3 installed inside, made of an optically transparent material in the form of a spiral, the outer diameter of which is consistent with the internal dimensions of the bulb, with electrodes 4 at the ends having conclusions 5, filled with a working substance with sodium vapor at low pressure, the conclusions of the electrodes of the discharge tube are electrically connected to the corresponding contacts of current supply elements. Sintered electrodes may be used in the construction of the discharge tube. 1 s.p. f-ly, 1 ill.

Description

The utility model relates to lighting engineering and can be used in the design of new environmentally friendly and energy-efficient light sources, including those intended for direct replacement of arc mercury lamps. The utility model is aimed at expanding the field of application of a low-pressure sodium lamp by increasing light output (ratio of light flux to total power consumption, lm / W), manufacturability, reliability, average life, operating life, reducing the size of the luminous body, expanding the range and reducing cost.

Known low-pressure sodium lamp containing a vacuum flask made of optically transparent material, equipped with elements of an external current lead, installed inside a sealed discharge tube made of optically transparent material in the form of a ruler with bulges uniformly distributed along the length, the external determining size of which is consistent with the internal the size of the flask, with electrodes at the ends having leads filled with a working substance with sodium vapors at low pressure; of the electrodes of the discharge tube are electrically connected to the corresponding contacts of the current supply elements (Development of a low pressure sodium lamp / Electrical light sources. Proceedings of VNIIS. - Saransk, 1972. - No. 4. - P. 94-104).

A disadvantage of the known low-pressure sodium lamp is a narrow field of application due to the relatively low light output, which is due to the design, the large length of the discharge tube, and the difficulties of ensuring optimal thermal operation. To increase light output due to the "insulation" of the discharge tube, a special coating of the outer bulb reflecting infrared radiation is used, or a second outer bulb is used, which makes the design even more expensive. The light output of low pressure sodium lamps with linear discharge tubes does not exceed 90 lm / W, which is a low value for this type of light source. The large size of the luminous body does not allow the use of standard designs of lighting devices, which narrows the scope. The design of the discharge tubes with bulges distributed along the length is not technologically advanced. An analog lamp also has low reliability, low average service life (2 ÷ 3 thousand hours) and operational life. The number of types of lamps with linear discharge tubes is largely limited.

с равномерно распределенными по длине выпуклостями, внешний определяющий размер которой согласован с внутренними размерами колбы, с электродами на концах, имеющих выводы, заполненной рабочим веществом с парами натрия при низком давлении, выводы электродов разрядной трубки электрически соединены с соответствующими контактами элементов токоподвода (Источники света. Лампы SOX. Каталог Osram / Osram. - 2010. - С. 5.28).Known low-pressure sodium lamp containing a vacuum flask made of optically transparent material, equipped with elements of an external current supply, with a sealed discharge tube installed inside, made of optically transparent material in the form of a sign

with bulges uniformly distributed along the length, the external determining size of which is consistent with the internal dimensions of the bulb, with electrodes at the ends having leads filled with a working substance with sodium vapor at low pressure, the terminals of the electrodes of the discharge tube are electrically connected to the corresponding contacts of the current supply elements (Light sources. SOX lamps. Catalog Osram / Osram. - 2010 .-- S. 5.28).

In a well-known lamp, the light output is brought to a value of 180 lm / W. However, the discharge tube remains low-tech in manufacture. The dimensions of the luminous body are relatively large (for example, with a power of 185 W, the length of the lamp is 1120 mm). Problems remain with ensuring the thermal regime of the discharge tube, and the use of lamps of this type in standard lighting devices is limited. The lamp also has low reliability, has a relatively small average life (12 ÷ 18 thousand hours) and operational life and high cost. Thus, the known low-pressure sodium lamp is also characterized by a disadvantage in a narrow scope. The number of manufactured types of lamps with and the volume of their production is limited.

разрядной трубкой) является наиболее близкой по технической сущности к полезной модели и выбрана в качестве прототипа.Low pressure sodium lamp (s

discharge tube) is the closest in technical essence to a utility model and is selected as a prototype.

The disadvantage of the prototype, as noted above, is a relatively narrow scope.

The utility model is aimed at solving the problem of expanding the field of application of a low-pressure sodium lamp, which is the purpose of the utility model.

The specified goal is achieved by the fact that:

1) the low-pressure sodium lamp contains a vacuum flask made of optically transparent material, equipped with elements of an external current supply, with a sealed discharge tube installed inside, made of optically transparent material in the form of a spiral, the outer diameter of which is consistent with the internal dimensions of the bulb, with electrodes at the ends having leads filled with a working substance with sodium vapor at low pressure, the leads of the electrodes of the discharge tube are electrically connected to the corresponding con acts current supply elements;

2) a low-pressure sodium lamp according to claim 1, characterized in that sintered electrodes are used in the construction of the discharge tube.

A significant difference characterizing the utility model is the expansion of the scope by increasing the light output of a low-pressure sodium lamp by 15-20% and the reliability of operation (improving the operational characteristics of the light source), increased average life and service life and low cost, due to new principles devices and manufacturability of the design. The execution of the discharge tube in the form of a spiral optimizes the thermal regime of the lamp, reduces the size of the luminous body, and prevents the phenomenon of sodium migration. The use of sintered electrodes increases the reliability and service life, reduces energy losses, reduces the ignition voltage of the lamp. The power range and range of low-pressure sodium lamps can be greatly expanded. At the same time, new lamps can be used without restrictions in common types of lighting fixtures.

The expansion of the scope of the low-pressure sodium lamp is a technical result due to new principles of the device, features of a new design and new elements and connections, that is, the hallmarks of the utility model. Thus, the distinguishing features of the inventive low-pressure sodium lamp are significant.

The drawing shows a typical design of a sodium (single-ended) low-pressure lamp with a standard mains socket (type E27).

The low-pressure sodium lamp contains a vacuum flask 1 made of an optically transparent material, equipped with elements of an external current supply 2, with a sealed discharge tube 3 installed inside, made of an optically transparent material in the form of a spiral, the outer diameter of which is consistent with the internal dimensions of the bulb, with electrodes 4 at the ends having conclusions 5, filled with a working substance with sodium vapor at low pressure, the conclusions of the electrodes of the discharge tube are electrically connected to the corresponding contacts of current supply elements. Sintered electrodes may be used in the construction of the discharge tube.

The steady state low pressure sodium lamp uses sintered electrodes.

The low-pressure sodium lamp in steady state operates as follows. Through the cap 2 (external current supply elements) of a standard type (E14, E27, E40, B22, BY22d) the lamp is connected to the AC mains supply (source) through a special electromagnetic or electronic ballast. It is also possible to connect a low-pressure sodium lamp to a direct current source through an electronic ballast. In general, a sodium discharge lamp is an electric light source, the luminous body of which is a low-pressure gas discharge (or high, in high-pressure sodium lamps) in sodium vapor. Therefore, sodium resonance radiation prevails in the spectrum of sodium lamps (lamps give a bright orange-yellow light, lines 589 and 589.6 nm in low-pressure sodium lamps, self-reversed strongly broadened D-lines of sodium in high-pressure sodium lamps, and intense lines in the blue-green part of the spectrum). Monochromatic radiation is a specific feature of low-pressure sodium lamps. As a working substance in such lamps, a mixture of sodium vapor and an inert gas (or a mixture of inert gases, such as neon and argon) is used. Low-pressure sodium lamps also differ in a number of other features that significantly complicate both their production and operation. Firstly, sodium vapor at high temperature aggressively acts on the material of the discharge tube (3), destroying it. Because of this, the discharge tubes (3) of low-pressure sodium lamps are usually made of special glasses (such as SL53-1 or overhead - chemically resistant soda-lime glass with a thin coating of borate glass) that are resistant to sodium vapor at high temperature. Secondly, the efficiency of low pressure sodium lamps is highly dependent on the ambient temperature. The maximum radiation is achieved at a vapor pressure of 0.2 ÷ 1 Pa and a temperature of 270 ÷ 300 ° C. To ensure an acceptable temperature regime of the discharge tube (3), the latter is placed in an external (glass) flask (1), which plays the role of a kind of “thermos”. The outer flask (1) is evacuated to reduce heat loss (pressure not higher than 0.01 Pa). An external evacuated (light-scattering) bulb 1 made of optically transparent material is an important part of the lamp design, which performs the bearing, protective, light-scattering, and "warming" functions. The flask 1, made of an optically transparent material, in the General case, can be made in a transparent, opaque, opal or milk versions. Matting provides a uniform distribution of brightness on the surface of a light-scattering evacuated bulb 1, eliminates the glare effect. The matting of the outer bulb 1 also slightly reduces the light output of the lamp (therefore, it is not currently used in low-pressure sodium lamps of known designs due to the large size of the luminous body). The external light-scattering bulb 1 is rigidly mechanically connected (paired) with the elements of the external current supply (base) 2. The bulb 1 is equipped with soldered conductive elements intended for the electrical connection of the light-emitting discharge tube 3 with elements of the external current supply 2 and an external electric circuit (power source or supply network) . The bulb 1 (as well as the discharge tube 3) can also be, with the aim of improving the thermal regime of the discharge tube 3, made with an infrared coating (reflecting infrared radiation and transmitting visible resonant radiation). For ignition and development of the discharge, an inert gas is introduced into the discharge tube 3 (in particular, neon at a pressure of 1.0 ÷ 1.5 kPa with the addition of 0.5 ÷ 1.0 argon to reduce the ignition voltage - Penning mixture). To supply electric energy to the discharge, the discharge tube is equipped with electrodes 4 at the ends having leads 5. The terminals 5 of the electrodes (4) of the discharge tube 3 are electrically connected to the corresponding contacts of the current supply elements (cap) 2. The electrodes 4 can be self-heating oxide, in particular triangular structures (in the form of a bifilar) or similar used in linear low pressure fluorescent lamps. The use of a sintered (sintered) electrode 4, due to the placement of the oxide activator in the volume of the electrode (4), and not on its surface (as with traditionally used spiral electrodes), allows to increase the amount of activator by approximately 10-15 times. The high thermal conductivity of the structure of the synthesized electrode (4) provides a low (by 30 ÷ 400 ° C) temperature of the electrodes of the 4 lamps (compared to the traditional spiral) and, as a result, a significant decrease in the evaporation rate of the activator and the electron work function. Active evaporation of the activator is also prevented by an inert gas filling the discharge tube. As a result, the stability and reliability of the low-pressure sodium lamp significantly increases in the conditions of frequent switching on (turning off) and under conditions of exceeding the supply voltage. Due to all of the above, the lamp life increases (by 30 ÷ 50%) and the decrease in the luminous flux during operation of the lamp and the lighting device based on it is significantly reduced. "Warming" of the discharge tube 3, having the shape of a spiral, is the most effective and high quality. The effect of sodium migration in this form of the discharge tube 3 is eliminated naturally. The inventive design of the discharge flask 3 in the form of a spiral is quite technologically advanced (more technologically advanced than the known structures). A low pressure sodium lamp can be made with a relatively small size of the luminous body.

Compared with the prototype, the scope of application of a low-pressure sodium lamp is significantly expanded.

The new sodium lamp can be effectively used in indoor and outdoor (without protective glass) luminaires for indoor and outdoor lighting of traditional (developed) structures, at low temperatures (up to -60 ° C), under conditions of shaking and limited shocks (lighting of warehouses, freight stations , industrial facilities, freeways tunnels, offshore platforms, architectural objects). Due to the quasi-monochromatic yellow light, which provides excellent visibility and resolution of the organs of vision, including at low light levels, and good transmission in fog and in dusty atmospheres, sodium lamps of the proposed design can be widely used in light-signal systems (installations).

The light output of a low-pressure sodium lamp is increased while maintaining all its known advantages. This is achieved by reducing energy losses as a result of improving the thermal regime of the discharge tube and losses while maintaining an electric discharge (reducing the work function of the electrons, decreasing the potential at the electrodes), making full use of the energy of the components of the radiation spectrum, and reducing heat transfer from structural elements. The light output of a new low-pressure sodium lamp can be increased to 250 lm / W. Increased light output expands the scope.

Additionally, in comparison with the prototype, by reducing the size of the luminous body, significantly lowering the temperature of the external parts of the structure, the possibility of equalizing the brightness on the surface of the light-scattering bulb and eliminating the glare effect (matting at small sizes of the luminous body), the field of application of the low-pressure sodium lamp is also expanding.

The new sodium lamp has increased reliability, increased average life and long service life due to improved operation of the electrode system and the conditions of the discharge tube. Improved performance expands the scope of the sodium lamp.

The proposed design of a low-pressure sodium lamp provides high technology, allows you to expand the range of operating capacities and the range of manufactured types of lamps, significantly reduces the final cost of products. The scope of lamps due to the possible increase in the range and lower cost is also expanding.

Claims (2)

1. A low-pressure sodium lamp containing a vacuum flask made of optically transparent material, equipped with elements of an external current supply, with a sealed discharge tube installed inside, made of optically transparent material in the form of a spiral, the outer diameter of which is consistent with the internal dimensions of the bulb, with electrodes on the ends having leads filled with a working substance with sodium vapor at low pressure, the terminals of the electrodes of the discharge tube are electrically connected to the corresponding ontacts of current lead elements. 2. The low-pressure sodium lamp according to claim 1, characterized in that sintered electrodes are used in the construction of the discharge tube.

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