RU110867U1 - LOW PRESSURE LUMINESCENT DISCHARGE LAMP - Google Patents

Abstract

 A low pressure fluorescent discharge lamp containing means for initiating and maintaining an electric discharge and a flask of optically transparent material filled with a working substance and an inert gas or a mixture of inert gases, on the outer surface or on a part of the surface of which a polymer film with a filler of a luminescent substance is deposited.

Description

The utility model relates to lighting engineering and instrumentation and can be used in the design of new safe energy-efficient and highly reliable gas-discharge light sources. The utility model is aimed at improving safety in the production and operation of a low pressure fluorescent discharge lamp.

Known low-pressure fluorescent discharge lamp containing means for initiating and maintaining an electric discharge and a flask of optically transparent material filled with a working substance and an inert gas, on the inner surface of which a layer of a luminescent substance is applied (Light sources. Catalog. - OSRAM, 2009. - S.4.12).

Means for initiating and maintaining an electric discharge are, inter alia, electrodes with special oxide layers or inductors (in electrodeless induction and hybrid lamps). The low pressure fluorescent discharge lamp has standard caps for connection to an electrical power source.

The disadvantage of a low pressure fluorescent discharge lamp is the increased danger during production and operation, which is due to the design (glass bulb) and the use of hazardous substances (mercury, cadmium, lead). The lamp uses mercury as a working substance. A glass flask is highly fragile. If the bulb is destroyed, it is likely that mercury will enter the surrounding area. Parts of the destroyed flask have sharp cutting edges, which is not safe during production and operation. To ensure the required mechanical strength, it is necessary to increase the wall thickness of the flask, leading to increased consumption of materials, deterioration of characteristics and, consequently, to additional environmental pollution in the production of low-pressure fluorescent discharge lamps and an increase in environmental hazard during disposal. The interaction of the luminescent and working substances during lamp operation complicates the disposal technology, which also reduces safety during its production and operation.

Known linear low-pressure fluorescent discharge lamp containing means for initiating and maintaining an electric discharge and a flask of optically transparent material filled with a working substance and an inert gas, on the inner surface of which a layer of a luminescent substance is deposited (Lamp catalog 2009-2010 - GE LIGHTING , 2009. - P.44).

A disadvantage of the known low pressure fluorescent discharge lamp is the increased danger during production and operation, which is due to the design (glass bulb) and the use of hazardous substances (mercury, lead). The lamp uses mercury in the form of an amalgam as a working substance. A glass flask is highly fragile. If the discharge bulb is destroyed, there is a high probability that mercury will enter the environment. Parts of the destroyed flask have sharp cutting edges, which is not safe during production and operation. To ensure the required mechanical strength, it is necessary to increase the wall thickness of the flask, leading to increased consumption of materials, deterioration of characteristics and, consequently, to additional environmental pollution in the production of low-pressure fluorescent discharge lamps and an increase in environmental hazard during disposal. The interaction of the luminescent and working substances during lamp operation complicates the disposal technology, which also reduces safety during its production and operation. The design of the lamp relates to electrode structures. The electrodes of the device have special oxide layers on the outer surface.

Known low-pressure fluorescent discharge lamp containing means for initiating and maintaining an electric discharge and a flask of optically transparent material filled with a working substance and an inert gas (Catalog of light sources. - State Unitary Enterprise RM NIIIS named after AN Lodygin, 2009. - C.5).

The specified low-pressure fluorescent discharge lamp is the closest in technical essence to the utility model and is selected as a prototype.

A disadvantage of the known low pressure fluorescent discharge lamp is the increased danger during production and operation, which is due to the design (glass bulb) and the use of hazardous substances (mercury, lead). The lamp uses mercury as a working substance. The device has an increased proportion of hazardous ultraviolet radiation in the output spectrum. Glass bulb is highly fragile. If the discharge bulb is destroyed, there is a high probability that mercury will enter the environment. Parts of the destroyed flask have sharp cutting edges, which is not safe during production and operation. To ensure the required mechanical strength, it is necessary to increase the wall thickness of the flask, leading to increased consumption of materials, deterioration of characteristics and, consequently, to additional environmental pollution in the production of low-pressure fluorescent discharge lamps and an increase in environmental hazard during disposal. The interaction of the luminescent and working substances during lamp operation complicates the disposal technology, which also reduces safety during its production and operation. The design of the lamp relates to electrode structures. The electrodes of the device have special emitting oxide layers on the outer surface.

The utility model is aimed at solving the problem of improving safety in the production and operation of a low pressure fluorescent discharge lamp, which is the purpose of the utility model.

This goal is achieved by the fact that in a low pressure fluorescent discharge lamp containing means for initiating and maintaining an electric discharge and a flask of optically transparent material filled with a working substance and an inert gas or a mixture of inert gases, a polymer film is applied to the external surface or to a part of the surface filler from a luminescent substance.

A significant difference characterizing the utility model is an increase in safety during the production and operation of a low-pressure fluorescent discharge lamp, which is achieved due to the adopted new principle of converting electrical energy into light energy and a new design. The risk of destruction of the lamp discharge bulb and the entry of hazardous substances into the surrounding area is reduced. Increases the mechanical strength of the structure. The output radiation spectrum improves due to the action of the luminescent substance. Poisoning of the luminescent substance by electric discharge products is excluded. The material consumption is reduced and the safety of production and disposal technologies during marriage, failure, destruction of the flask and at the end of its life is increased. Light energy is generated due to the efficient use of radiation energy from a discharge flask, which is converted by an external layer of a luminescent substance of a polymer film into visible light. This energy conversion is the most optimal and allows you to create a low pressure fluorescent discharge lamp with the longest service life, which is due to a significant slowdown in the degradation (poisoning) of the luminescent substance when contaminated with products formed in an electric discharge during operation. The luminescent substance is protected from contamination by products formed in the volume of the electric discharge by moving it outside the discharge zone, as well as from poisoning as a result of chemical reactions of interaction with the glass of the discharge bulb. The service life of the luminescent filler also increases due to the optimization of its temperature regime. To protect against adverse environmental influences, the luminescent filler is placed in a polymer base, which significantly reduces the rate of its degradation and increases the overall service life of the fluorescent discharge lamp. In addition, the luminous efficiency of the structure is increased, which allows to optimize the production technology and reduce the adverse environmental impact of production.

Improving the safety in the production and operation of a low pressure fluorescent discharge lamp is the technical result due to the new principle of energy conversion, the features of the new design of the lamp and its elements, the presence of new elements in the device, the removal of the luminescent substance, the presence of a protective layer of a polymer film, that is, hallmarks of a utility model. Thus, the distinguishing features of the claimed low-pressure fluorescent discharge lamp are significant.

The figure shows an example of a typical design of a low-pressure fluorescent discharge lamp.

The presented lamp design refers to the so-called electrode structures. Similar designs of induction, electrode-induction and hybrid lamps with discharge flasks of various shapes (linear, ball, prismatic and others) are also possible.

The low pressure fluorescent discharge lamp contains means 1 for initiating and maintaining an electric discharge and a flask 2 of optically transparent material filled with a working substance and an inert gas or a mixture of inert gases 3, on the outer surface or on a part of the surface of which a polymer film 4 with a filler 5 of luminescent substance.

The low-pressure fluorescent discharge lamp in the steady state operates as follows. The lamp through the socles 1 of a standard type (for example, G13, E27 and others), installed at its ends and connected to electrodes (means for initiating and maintaining an electric discharge), is connected to a special AC mains supply (power source). The discharge bulb 2 is a supporting structure on which all other elements of the fluorescent discharge lamp are installed (socles 1 for connection to a power source, polymer film 4), and the main working element of the device limiting the discharge volume. The flask 2 is filled with a working substance and an inert gas or a mixture of inert gases 3. During operation of the device, part of the energy is dissipated, which leads to heating of the lamp elements. Heat is removed, including a discharge bulb 2 and a light-scattering polymer film 4 with a luminescent filler 5. The power source of the low-pressure fluorescent discharge lamp is in the form of a special electronic ballast. An electronic ballast converts an alternating voltage of a low-frequency supply network to an alternating voltage, for example, of an increased frequency, necessary to supply a discharge bulb 2 and maintain an electric discharge therein by transferring energy from the conduction current flowing through the electrodes 1 of bulb 2 and the plasma of the bulb’s electric discharge 2. When the device is in operation, the electronic ballast provides the required parameters for converting the supply voltage (low output voltage ripple Ia and lamp current, the output current is stabilized, high power factor and efficiency). An electric discharge in the bulb 2 emits light of certain wavelengths, which is converted by a luminescent substance 5 introduced into the volume of the polymer film 4. A polymer film 4 with a filler of luminescent substance 5 is deposited on the outer surface of the discharge bulb 2 from an optically transparent material. The luminescent substance 5 restores the missing parts of the spectrum of the discharge radiation (working substance and inert gas or a mixture of inert gases 3) in order to obtain “white light”. To protect the luminescent substance 5 from contamination by products formed in the volume of the electric discharge and temperature effects, it is moved outside the volume (region) of the discharge of the discharge flask 2. For additional protection of the luminescent substance 5 from adverse environmental influences (moisture, aggressive gases, dust ) a polymer film 4 is used. At the same time, a polymer film 4 has increased mechanical strength and elasticity. On the one hand, it “insulates” the discharge region, and on the other hand, it prevents the parts of the discharge flask and working substance from getting into the surrounding space. Energy, as noted above, enters the volume of the discharge flask 2 from the conduction current flowing through the electrodes connected to the socles 1 for connection to an electronic ballast (power supply). The electrons emitted from the electrodes (1) of the discharge bulb 2, accelerated by the electric field, cause ionization of the atoms of the working substance of the discharge bulb 2 and the formation of plasma. Plasma is a conductive medium. The electric circuit is closed through the electrodes (1) of the discharge bulb 2, as a result of which a conduction current flows, supporting the electric discharge in the bulb 2. Accelerated plasma electrons excite the atoms of the working substance of the discharge bulb 2. The transition of the working substance atoms to the normal state causes the emission of light waves , including in the ultraviolet range. Ultraviolet radiation from the discharge flask 2 acts on the luminescent substance 5 of the polymer film 4, which causes the conversion of the discharge radiation into visible (white) light.

The discharge flask 2 may be made of quartz glass, or other optically transparent material that transmits visible and ultraviolet radiation. The polymer film 5 is made, in particular, of an optically transparent fluoropolymer or other flexible optically transparent polymer material that is resistant to discharge radiation.

Compared with the prototype, the safety during the production and operation of a low-pressure fluorescent discharge lamp is increased, which is achieved due to the adopted new principle of converting electric energy into light energy and a new lamp design. The risk of destruction of the lamp discharge bulb and the entry of hazardous substances into the surrounding area is reduced. Increases the mechanical strength of the structure. The output radiation spectrum improves due to the action of the luminescent substance. Poisoning of the luminescent substance by electric discharge products is excluded. The material consumption is reduced and the safety of production and disposal technologies during marriage, failure, destruction of the flask and at the end of its life is increased.

As a result of the removal of the luminescent filler layer beyond the limits of the discharge volume and the internal volume of the discharge bulb, effective protection, elimination of adverse thermal effects, its service life is increased, which, in general, increases the service life and reliability of the inventive luminescent discharge lamp. Reducing the effect of intensive atomization of the electrodes of the discharge flask on the luminescent substance provides an increase in the service life and a decrease in the rate of degradation (poisoning) of the phosphor and the material of the discharge flask caused by their contamination with products formed in the volume of the electric discharge. The luminescent substance is reliably protected from contamination by the protective layer of the polymer film and the material of the discharge flask. The service life of the new low-pressure fluorescent discharge lamp, in comparison with the prototype, can be increased by at least 25% (up to 20 ÷ 25 thousand hours).

Additionally, the new low-pressure fluorescent discharge lamp provides higher light output. Compared with the prototype, light output can increase up to 90 ÷ 100 lm / W, which is 5-7% higher than in the prototype and other well-known lamps using low-pressure electric discharge. The total amount of mercury can also be reduced when the lamp is run at a given power and light output.

Compared with the prototype, the overall dimensions of the inventive luminescent discharge lamp can be reduced (up to 3 ÷ 5%) due to the optimization of the design and the possibility of using new materials, as well as the possibility of reducing material consumption. The inventive lamp can effectively operate in a wider range of operating temperatures (up to -20 ° C), due to improved operating conditions of the discharge bulb. The new fluorescent discharge lamp can be used as an optimal node for prospective linear integrated (with built-in electronic ballasts) fluorescent lamps.

Improving safety during production and operation, reducing weight and size indicators and expanding the temperature range for reliable operation of a low-pressure fluorescent discharge lamp significantly expands its scope. The expansion of the scope of the claimed lamp, compared with the prototype, is an important new consumer quality of the claimed device

Claims (1)

A low pressure fluorescent discharge lamp containing means for initiating and maintaining an electric discharge and a flask of optically transparent material filled with a working substance and an inert gas or a mixture of inert gases, on the outer surface or on a part of the surface of which a polymer film with a filler of a luminescent substance is deposited.