RU104381U1 - HYBRID INTEGRATED LINEAR LUMINESCENT LAMP - Google Patents

Abstract

 Hybrid integrated linear fluorescent lamp containing a diffuser bulb in the form of a tube of optically transparent material with socles at the ends for connection to a power source, on the part of the surface of which a reflective layer is applied, and on the other part of the surface of which is a phosphor layer with a protective layer in the inner volume which contains a ballast with an inductive element and a discharge flask in the form of a tube of optically transparent material filled with a working substance, with an electric rows at the ends connected through the ballast with caps, the inductive element is formed of at least two parts in the form of coils with cores of ferromagnetic material, placed at the ends of the discharge bulb.

Description

The utility model relates to lighting engineering and instrumentation and can be used in the design of new energy-efficient highly reliable luminescent gas-discharge light sources. The utility model is aimed at increasing the service life of a linear fluorescent lamp.

Known linear fluorescent lamp containing a discharge bulb in the form of a tube of optically transparent material, filled with a working substance, with electrodes at the ends connected to the socles for connection to a power source, the surface of which is coated with a phosphor layer (Light sources. Catalog. - OSRAM, 2009 . - C.4.12).

The disadvantage of a linear fluorescent lamp is its short service life, which is due to the relatively rapid degradation of the material of the discharge bulb and phosphor due to their contamination with products generated in the electric discharge during operation, insufficient efficiency applied in the lamp, and the principle of converting electrical energy from conduction current to light energy characterized by increased wear and aging of the elements and parts of the device, diffusion of the light flux, which requires an increase in power lamps and increased electric loading of its elements and parts.

A linear fluorescent lamp is known that contains a discharge bulb in the form of a tube made of an optically transparent material filled with a working substance, with electrodes at the ends connected to socles for connection to a power source, on the surface of which a phosphor layer is applied (Lamp catalog 2009/2010 - GE LIGHTING, 2009 .-- P.44).

The disadvantage of a linear fluorescent lamp is its short service life, which is due to the relatively rapid degradation of the material of the discharge bulb and phosphor due to their contamination with products generated in the electric discharge during operation, insufficient efficiency applied in the lamp, and the principle of converting electrical energy from conduction current to light energy characterized by increased wear and aging of the elements and parts of the device, diffusion of the light flux, which requires an increase in power lamps and increased electric loading of its elements and parts.

Known linear fluorescent lamp containing a discharge bulb in the form of a tube of optically transparent material filled with a working substance, with electrodes at the ends connected to the socles for connection to a power source, the surface of which is coated with a phosphor layer (Catalog of light sources. - State Unitary Enterprise RM NIIIS named after A.N. Lodygin ", 2009. - P. 5).

The specified linear fluorescent lamp is the closest in technical essence to a utility model and is selected as a prototype.

The disadvantage of a linear fluorescent lamp is its short service life, which is due to the relatively rapid degradation of the material of the discharge bulb and phosphor due to their contamination with products generated in the electric discharge during operation, insufficient efficiency applied in the lamp, and the principle of converting electrical energy from conduction current to light energy characterized by increased wear and aging of the elements and parts of the device, diffusion of the light flux, which requires an increase in power lamps and increased electric loading of its elements and parts.

The utility model is aimed at solving the problem of increasing the service life of a linear fluorescent lamp, which is the purpose of the utility model.

This goal is achieved by the fact that in a hybrid integrated linear fluorescent lamp containing a diffusing bulb in the form of a tube made of an optically transparent material with socles at the ends for connection to a power source, on the part of the surface of which a reflective layer is applied, and on the other part of the surface of which a phosphor layer is applied with a protective layer, in the internal volume of which there is a ballast with an inductive element and a discharge bulb in the form of a tube of optically transparent material, olnennaya working medium, with the electrodes at the ends connected through the ballast with caps, the inductive element is formed of at least two parts in the form of coils with cores of ferromagnetic material, placed at the ends of the discharge bulb.

A significant difference characterizing the utility model is an increase in the service life of a linear fluorescent lamp, which is achieved due to the adopted new hybrid principle of converting electrical energy into light energy. Light energy is generated due to the efficient use of radiation energy from a discharge bulb, which is converted by a removed phosphor layer into visible light. This conversion is optimal and allows you to create a fluorescent discharge lamp with a long service life, which is due to a significant slowdown in the degradation of the material of the discharge bulb and phosphor when contaminated with products formed in an electric discharge during operation. The phosphor is protected from contamination by products formed in the volume of the electric discharge, thus, by moving it outside the discharge zone. The service life of the phosphor layer also increases due to the optimization of its temperature regime. For additional protection against adverse environmental influences, the phosphor layer is also protected by a special protective layer, which significantly reduces its degradation rate and increases the overall service life of a linear fluorescent lamp. The use of a reflective layer allows to reduce the dispersion of the light flux and redirect it in an optimal way, which allows to reduce the power and, consequently, the electrical load of the elements and parts of the device and thereby increase the service life. The increase in the service life of a linear fluorescent lamp is achieved by applying the hybrid principle of converting electrical energy into light energy. Light energy in a new lamp is generated by using the energy of the conduction current and the energy of eddy currents in a discharge bulb. Both types of energy conversion complement each other and allow you to create a fluorescent gas discharge lamp with the longest possible life, due to a significant reduction in the wear rate of the electrodes.

The increase in the service life of a linear fluorescent lamp is a technical result due to the new hybrid principle of converting electrical energy into light energy by using energy from the conduction current and eddy currents in a discharge bulb, the features of the new design of a linear fluorescent lamp and its elements, the presence of new elements in the device the removal of the phosphor layer from the volume of the electric discharge, the presence of the protective layer of the phosphor and the reflective layer, inclusion in Tav device control gear, that is, the hallmarks of a utility model. Thus, the distinguishing features of the claimed hybrid integrated linear fluorescent lamp are essential.

The figure shows an example of a typical design of a hybrid integrated linear fluorescent lamp.

The hybrid integrated linear fluorescent lamp contains a diffuser bulb 1 in the form of a tube of optically transparent material with socles 2 at the ends for connection to a power source, on the surface part of which a reflective layer 3 is applied, and on the other part of the surface a phosphor layer 4 with a protective layer 5 is applied , in the internal volume of which are placed a ballast 6 with an inductive element and a discharge flask 7 in the form of a tube of optically transparent material filled with a working substance, with electric By electrodes 8 at the ends connected through a ballast to the bases, the inductive element is made of at least two parts in the form of coils 9 with cores 10 of ferromagnetic material placed at the ends of the discharge bulb.

Hybrid integrated linear fluorescent lamp in steady state operates as follows. The lamp through the socles 2 of a standard type (for example, G13) installed at its ends is connected to the AC mains supply (power source). A light-scattering bulb 1 in the form of a tube made of an optically transparent material is a supporting structure on which, or in its internal volume, all other elements of a hybrid integrated linear fluorescent lamp are installed (including socles 2 for connecting to a power source, ballast 6, discharge bulb 7 with electrodes 8, coils 9 with cores 10), and one of the main working elements of the device. A reflective layer 3 and a phosphor layer 4 with a protective layer 5 are applied on its surface. During operation of the device, part of the energy is dissipated, which leads to heating of the elements. Heat is removed, including a light-diffusing bulb 1 and a discharge bulb 7. The power supply unit of the hybrid integrated linear fluorescent lamp is made in the form of a special ballast 6. The ballast converts the alternating voltage of the low-frequency supply network into alternating voltage, for example, of increased frequency, necessary to power the discharge bulb 7 and maintain an electric discharge in it by transferring energy from the conduction current flowing through the discharge electrodes 8 olby 7 and the electric discharge plasma discharge tube 7, made in the form of a tube of optically transparent material filled with the working medium. At the same time, the energy in the plasma of the electric discharge comes from eddy currents arising due to electromagnetic induction (inductors in the form of coils 9 with cores 10) in the plasma of the electric discharge of the discharge bulb 7. When the device is operating, the control gear provides the required parameters for converting the supply voltage (low ripple output voltage and lamp current, stabilized output current, high power factor and efficiency). An electric discharge in the discharge bulb 7 emits light of certain wavelengths, which is converted by a phosphor layer 4 deposited on the surface of the diffuser bulb 1 of an optically transparent material, restoring the missing parts of the spectrum in order to obtain "white light". To protect the phosphor 4 from pollution by the products formed in the volume of the electric discharge and temperature effects, it has been removed from the discharge bulb 7. For additional protection of the phosphor layer 4 from adverse environmental influences (moisture, aggressive gases, dust), a special protective layer 5 is used . Energy, as noted above, enters the volume of the discharge bulb 7 from the conduction current flowing through the electrodes 8 connected to the socles 2 for connecting to a power source through a ballast 6 , and eddy currents excited by electromagnetic induction. Inductors (inductive element) 9 with cores 10 are the working elements of the ballast and act as a restrictive inductor. Electrons emitted from the electrodes 8 of the discharge bulb 7, as well as electrons arising from the ionization of the atoms of the working substance of the discharge bulb 7 by an electromagnetic field, accelerated by the electric field, cause avalanche ionization of the atoms of the working substance of the discharge bulb 7 and the formation of plasma. Plasma is a conductive medium. The electric circuit is closed through the electrodes 8 of the discharge flask 7, as a result of which the conduction current flows, supporting the discharge. The plasma electrons accelerated by the field excite the atoms of the working substance of the discharge bulb 7. The transition of the atoms of the working substance to a normal state causes the emission of light waves, including in the ultraviolet range. Ultraviolet radiation from the discharge bulb 7 acts on the phosphor layer 4, which causes the generation of visible light. The plasma in the discharge flask 7 performs the function of a secondary winding of an equivalent transformer, the primary winding of which is an inductive element (9, 10). The cores 10 of the ferromagnetic material of the inductive element localize the magnetic flux of coils (inductors) 9 in the volume. The scattering flows of the inductors 9 are closed through the parts of the discharge flask 7, which causes the formation of eddy currents in its volume. The inductive element (9. 10) ensures the operability of the control gear 6 and the limitation of the conduction current through the electrodes 8 of the discharge bulb 7. The discharge bulb 7 is included in the electrical circuit of the device (a lamp with a control gear 6), for example, according to the well-known resonant circuit through the electrodes 8 on it ends.

Inductors (9, 10) of a lamp can consist, in general, of one or more parts, depending on the design of the discharge bulb 7. The electrodes 8 of the discharge bulb 8, in the general case, may not have an additional special (oxide) coating that increases their emission properties. The light-scattering bulb 1 can be made without phosphor 4, for example, in ultraviolet radiation lamps, including amalgam ones. The principle of operation of the hybrid integrated linear fluorescent lamp is not changed.

The discharge flask 7 may be made of quartz glass, or other optically transparent material that transmits visible and ultraviolet radiation. The light-diffusing flask 1 is made of ordinary glass or an optically transparent polymeric material (for example, polycarbonate), which allows the application of a layer of phosphor 4, protective 5 and reflective 3 layers. The control gear 6 is implemented according to any of the known schemes providing a given conversion frequency. Plinths 2 have a standard design, for example, a two-pin type G13.

As a result of the removal of the phosphor layer beyond the limits of the volume of the discharge and the discharge bulb, effective protection, elimination of adverse thermal effects, its service life increases, which, in general, increases the service life and reliability of the inventive hybrid integrated linear fluorescent lamp. Reducing the effect of intensive atomization of the electrodes of the discharge bulb on the phosphor layer provides an increase in the service life and a decrease in the rate of degradation of the phosphor and the material of the discharge bulb caused by their contamination with products formed in the volume of the electric discharge. The phosphor is protected by an additional special protective layer. As a result of a significant reduction in the electrical load on the electrodes, their wear is reduced, in particular, spraying of the oxide coating, if applied, which increases the service life and reliability of the inventive lamp. By eliminating the scattering of the light flux, the electric load on the elements and parts of the device can be significantly reduced, which increases the overall service life. The service life of the new hybrid integrated linear fluorescent lamp can be increased by at least 100% (up to 40 ÷ 50 thousand hours). The MTBF of the inventive lamp increases, in comparison with the prototype, by at least 80 ÷ 90%.

Compared with the prototype, the efficiency of the hybrid integrated linear fluorescent lamp is also increased, including during long-term operation due to a smaller decrease in luminous flux. As a result, in common lighting systems, lamps with a lower margin in luminous flux and lower power can be used. Electric energy is converted into light energy through two channels: from the conduction current and from eddy currents due to electromagnetic induction. As a result, each element of the lamp is optimal and can be performed with minimal energy loss. The lamp control gear (due to the use of the new hybrid principle) operates at the optimum frequency with low losses. The efficiency of the lamp increases by 15 ÷ 18%.

Additionally, the new linear fluorescent lamp provides higher light output (60 ÷ 90%) due to a more efficient hybrid method of converting electrical energy into light energy. Compared with the prototype, light output can increase to 130 ÷ 160 lm / W. 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 design can be greatly simplified and the price (3–5%) of the claimed lamp can be reduced. This is achieved due to the possibility of using the elements of the device at a lower installed capacity and with a lower price, reducing the consumption of expensive materials. With comparable technical characteristics, the price of the kit (lamp and ballast) is higher than the price of a hybrid integrated linear fluorescent lamp with a built-in ballast.

Compared with the prototype, the field of application of a linear fluorescent lamp can be expanded by performing it in an integrated form, improving and improving the reliability of starting conditions. The inventive lamp can operate effectively in a wider range of operating temperatures (up to -20 ° C), due to improved starting conditions and operating conditions of the discharge bulb. Due to the application of the new hybrid principle of converting electric energy into light, the range of lamp powers can be expanded towards higher powers.

Claims (1)

Hybrid integrated linear fluorescent lamp containing a diffuser bulb in the form of a tube of optically transparent material with socles at the ends for connection to a power source, on the part of the surface of which a reflective layer is applied, and on the other part of the surface of which is a phosphor layer with a protective layer in the inner volume which contains a ballast with an inductive element and a discharge flask in the form of a tube of optically transparent material filled with a working substance, with an electric rows at the ends connected through the ballast with caps, the inductive element is formed of at least two parts in the form of coils with cores of ferromagnetic material, placed at the ends of the discharge bulb.