RU183332U1 - LINEAR LED LAMP - Google Patents

Abstract

The utility model relates to lighting engineering and can be used in the design of new energy-efficient and universal semiconductor optical radiation sources based on light-emitting diodes or LED arrays, in particular, COB and MSW matrices, including those designed to directly replace gas-discharge linear luminescent (double-cap) low-pressure mercury lamps used for lighting and ultraviolet radiation. The claimed linear LED lamp contains a bulb, at least part of which is made of optically transparent material, with elements of an external current supply at the ends, with a driver and a light-emitting body based on LEDs inside, connected via a driver to elements of an external current supply. The outer surface of the bulb is the intersection of the surface of the cylinder and the plane parallel to the axis of the cylinder and spaced from the axis at a distance from 0 to 0.92 of the radius of the cylinder, and the light-emitting body is placed in the area of the flat part and is oriented in the direction of the part of the optically transparent material. In this case, the bulb can be made of two mechanically mating parts in the zone of intersection of the cylinder surface and the plane, and all contacts of each of the elements of the external current supply, as an option, are electrically closed through a circuit with low resistance. The lamp driver ensures operability with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage, and the lamp can be equipped with a means that limits the current through the elements of the external current supply when one of the elements is disconnected from the power circuit. The optically transparent part of the flask, as one of the options, is matted, and the elements of the external current supply have a means of mechanical fixation at the ends of the flask. The technical result is an increase in the manufacturability and manufacture of a linear LED lamp. 10 s.p. f-ly, 1 ill.

Description

The utility model relates to lighting engineering and can be used in the design of new energy-efficient and universal semiconductor optical radiation sources based on light-emitting diodes or LED arrays, in particular, COB and MSW matrices, including those designed to directly replace gas-discharge linear luminescent (double-cap) low-pressure mercury lamps used for lighting and ultraviolet radiation. The utility model is aimed at increasing the manufacturability and use of a linear LED lamp.

A linear LED lamp is known that contains a bulb in the form of a tube of optically transparent or heat-conducting material with a longitudinal window of optically transparent material, with external current supply elements at the ends, with a light-emitting body inside, consisting of several LEDs or LED arrays connected to external current supply elements ( P. 103673 of the Russian Federation, MKI H01L 33 \ 00. Linear LED lamp \ Silkin EM - Announcement 11/15/2010, Publish. 04/20/2011, Bull. No. 11).

A disadvantage of a linear LED lamp is the low manufacturability and application, which is due to its design, the absence of a power driver in the device structure, the need to change the design of serial lamps for linear gas-discharge fluorescent lamps with electromagnetic and electronic ballasts and to install a special external LED driver in the lamps (matrices ), the shortcomings of the cylindrical shape of the flask, hindering the orientation of the elements in the manufacture enii (process flow passage) and the orientation of the lamp when installed in the lamp, including, in low light conditions, low electrical safety can not be effectively used in installations for producing ultraviolet radiation.

A known linear LED lamp containing a bulb in the form of a semicylindrical tube of optically transparent material coated with a phosphor layer, with elements of an external current supply at the ends, with a light-emitting body inside, consisting of several LEDs or LED arrays connected to elements of an external current supply (P. 103671 of the Russian Federation , MKI H01L 33 \ 00. Linear LED lamp \ Silkin EM - Announcement 11/15/2010, Publish. 04/20/2011, Bull. No. 11).

A disadvantage of a linear LED lamp is the low manufacturability and application, which is due to its design, insufficient maximum radiation angle, making it impossible to effectively use in serial designs luminaires for linear low-pressure fluorescent lamps, the absence of a power supply driver in the structure, and the need to significantly change the serial and widespread luminaires for gas discharge fluorescent lamps with electromagnet with electronic and ballasts and the installation of special external LED driver power supplies for LEDs or LED matrices, low electrical safety, requiring complex and expensive additional measures, problems of applying a uniform phosphor layer to the surface of the bulb, and the inability to effectively use lamps in installations for ultraviolet radiation.

Known linear LED lamp containing a bulb in the form of a semicylindrical or cylindrical tube of optically transparent material coated with a phosphor layer, with elements of an external current supply at the ends, with a driver and a light-emitting body inside, the light-emitting body consists of several LEDs or LED matrices connected via a driver elements of an external current supply (P. 108213 of the Russian Federation, MKI H01L 33 \ 00. Linear LED lamp \ Silkin EM - Application. 04/06/2011, Publish. 09/10/2011, Bull. No. 25).

A disadvantage of a linear LED lamp is the low manufacturability and application, which is due to its design, insufficient maximum radiation angle (with a bulb of a half-cylinder shape), which makes it impossible to use effectively in serial designs luminaires for gas discharge linear low-pressure fluorescent lamps, the need for a significant change in the design of serial lamps for gas discharge lamps with electromagnetic and electronic ballasts These are the disadvantages of the cylindrical shape of the bulb, which impede the orientation of the elements and the lamp itself with the cylindrical shape of the bulb in the manufacture (process steps) and the orientation of the lamp when installed in the lamp, including in low light conditions, low electrical safety, requiring special additional measures to protection against electric shock, the difficulty of obtaining a uniform phosphor layer on the surface of the bulb, the inability to use known lamps in installations for I produce ultraviolet radiation without significant design correction.

A linear LED lamp is known that contains a bulb, at least part of which is made of optically transparent material, with elements of an external current supply at the ends, with a driver and a light-emitting body based on LEDs inside, connected via a driver to elements of an external current supply (P. 152824 RF , MKI F21S 6/00. Linear LED lamp \ Silkin EM - Announcement 12.01.2015, Publish. 06.20.2015, Bull. No. 17).

The specified linear LED lamp is the closest in technical essence to a utility model and is selected as a prototype. The disadvantage of a linear LED lamp (prototype) is the low manufacturability and application, due to its design, the need for a significant change in the design of serial fixtures for gas discharge linear low-pressure fluorescent lamps with electromagnetic and electronic ballasts (the inability to use the technology of direct replacement of discharge lamps for LED ), the shortcomings of the cylindrical shape of the flask, hindering the orientation of the con the structure and the lamp itself with a cylindrical shape of the bulb during manufacture (undergoing technological operations in mass production) and the simple orientation of the lamp when installed in the lamp (in operating conditions), including in low light, low electrical safety, requiring special complex and expensive additional measures to protect against electric shock, the difficulty of ensuring the optimum angle of radiation of the lamp and high efficiency of the lamp.

The utility model is aimed at solving the problem of improving the design of a linear LED lamp, optimizing its technical and operational characteristics, including ensuring universality and ease of use, which is the purpose of the utility model.

The technical result is to increase the manufacturability and use of a linear LED lamp.

The specified goal and technical result is achieved by the fact that in a linear LED lamp:

1. Containing the flask, at least part of which is made of optically transparent material, with elements of an external current supply at the ends, with a driver and a light-emitting body based on LEDs inside, connected through the driver to elements of an external current supply, the outer surface of the flask is the intersection of the surface the cylinder and the plane parallel to the axis of the cylinder and spaced from the axis at a distance from 0 to 0.92 of the radius of the cylinder, the light-emitting body is placed in the area of the flat part and is oriented in the direction parts from optically transparent material;

2. According to claim 1, the flask is made of two mechanically mating parts in the zone of intersection of the cylinder surface and the plane;

3. According to p. 1 or 2, all the contacts of each of the elements of the external current supply are electrically closed through a circuit with low resistance;

4. According to p. 1 or 2, the driver ensures operability with the amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage;

5. According to p. 1 or 2, all the contacts of each of the elements of the external current supply are electrically closed through a circuit with low resistance, and the driver ensures operability with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage;

6. According to p. 1 or 2, the lamp is equipped with a tool that limits the current through the elements of the external current supply when disconnecting one of the elements from the power circuit;

7. According to p. 1 or 2, all the contacts of each of the elements of the external current supply are electrically closed through a circuit with low resistance, the lamp is equipped with a tool that limits the current through the elements of the external current supply when disconnecting one of the elements from the power circuit;

8. According to p. 1 or 2, all the contacts of each of the elements of the external current supply are electrically closed through a circuit with a low resistance, the driver ensures operability with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage, the lamp is equipped with a limiting means current through the elements of an external current supply when disconnecting one of the elements from the power circuit;

9. According to claim 1 or 2, the optically transparent part of the flask is frosted;

10. According to claim 1 or 2, the elements of the external current supply have a means of mechanical fixation at the ends of the flask;

11. According to claim 1 or 2, the optically transparent part of the flask is frosted, and the elements of the external current supply have a means of mechanical fixation at the ends of the flask.

A significant difference characterizing the utility model is an increase in the manufacturability of the manufacture and use of a linear LED lamp, provided that the design of the linear LED lamp is improved, its technical and operational characteristics are optimized, including ensuring versatility and ease of use.

Improving the manufacturability and use of a linear LED lamp is the technical result due to the proposed device principle, design features, a set of properties and functional characteristics of the light source that provide electrical safety, versatility, the ability to directly replace gas-discharge linear low-pressure fluorescent lamps in any type of lamp with various types ballasts without structural correction, as well as joint Use in hybrid luminaires, ease of orientation of parts and the lamp itself during assembly during mass production and installation in a light fixture during operation, optimization of the radiation angle and efficiency of luminaires due to the distinguishing features of the utility model, including the special shape of the bulb, placement and orientation of the light-emitting body. Thus, the distinguishing features of the claimed linear LED lamp are significant.

The figure shows a typical design (version) of the inventive linear LED lamp.

The linear LED lamp contains a bulb 1, at least part of which is made of optically transparent material, with elements of an external current supply 2 at the ends, with a driver 3 and with a light-emitting body 4 based on LEDs inside, connected via a driver to elements of an external current supply, an external surface the bulb is the intersection of the surface of the cylinder and the plane parallel to the axis of the cylinder and spaced from the axis at a distance from 0 to 0.92 of the radius of the cylinder, the light-emitting body is placed in the area of the flat part oriented in the direction of the part of the optically transparent material, the bulb can be made of two mechanically mating parts in the zone of intersection of the surface of the cylinder and the plane, and all contacts of each of the elements of the external current supply, as an option, are electrically closed through a circuit with a low resistance, the lamp driver provides operability with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage, and the lamp can be equipped with a current limiting means through the elements of the external current supply when disconnecting one of the elements from the supply circuit, the optically transparent part of the bulb, as one of the options, is matted, and the elements of the external current supply have a means of mechanical fixation at the ends of the bulb.

A linear LED lamp in steady state operates as follows. The lamp through elements of an external current supply 2 (caps) of a standard type is connected to a conventional AC mains directly or through an appropriate ballast (in the case of direct replacement of gas discharge linear low-pressure fluorescent lamps). The elements of the current supply 2 may contain one or more contacts (multi-pin socles), in particular, two contacts (socles of the standard type G5, G13 and others). Driver 3 provides the conversion of the AC mains voltage or the voltage from the output of electromagnetic or electronic ballasts to the voltage necessary (and sufficient) to power the LEDs or LED matrices of the light-emitting body 4 (for this it must ensure operability with an amplitude value of the supply voltage from 0, 35 to 1.15 of the amplitude value of the rated supply voltage). When the device is operating, driver 3, in particular, provides low ripple of the supply voltage and current of light emitting diodes (LED arrays) of light emitting body 4, and a stable output current. The driver 3 of the linear LED lamp, in general, remains in good condition and performs its functions with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage of the lamp itself or the light fixture in which it is installed, which increases manufacturability and universality of application. The bulb 1 of the LED lamp is hermetically sealed and protects the internal elements from touching, adverse effects (dust, moisture, radiation) of the external environment, and also performs the functions of the supporting structure and, as an option, including redirection and scattering of the light flux of the light-emitting body 4. In the General case, the part of the flask 1, which is made of an optically transparent material, may be coated with a layer of phosphor (or be made of material with particles of a phosphor or a mixture of phosphors introduced into the volume). The placement of the light-emitting body 4 in the area of the flat part of the bulb 1 and the orientation in the direction of the part of the optically transparent material provide sufficient heat dissipation from the driver elements 3 and the LEDs (light-emitting diodes) of the light-emitting body 4 installed inside the bulb 1, as well as the effective output of the lamp light from minimum losses and maximum efficiency. The thermal mode of operation of the elements of the device improves, which contributes to an increase in luminous efficiency and a decrease in the degradation of characteristics, and, therefore, to ensure the required lamp life. The presence of the flat part of the bulb 1 and its size (position relative to the axis in the direction of the radius of the generatrix of the cylinder at a distance from 0 to 0.92 of the radius of the cylinder) can improve the lamp assembly technology, including strictly orienting the parts and the lamp itself during technological operations in manufacturing process (as well as application), optimally adjust (set) the angle of radiation depending on the design of the light-emitting body 4 (and driver 3). In particular, elements of external current supply 2 (cap) can be easily oriented relative to bulb 1 during lamp manufacture, and the lamp itself - when it is installed in lamps (application technology), which is important, for example, in low light conditions when the lamp fails and (or) its replacement.

The LEDs of the light-emitting body 4 generate light of certain wavelengths, which is converted by phosphors, restoring the missing parts of the spectrum in order to obtain high-quality "white" light. LEDs can have, in particular, blue, blue, green glow. In this case, phosphors when exposed to the initial (primary) radiation of LEDs emits energy in the missing spectral regions (yellow-green or green and red parts of the spectrum of visible light). When mixing the radiation of LEDs and phosphor, “white” (or close to it) light is formed with high color rendering quality. LEDs are semiconductor devices with a p-n junction, operating with direct inclusion and converting the energy of an electric current directly into light radiation due to the phenomenon of electroluminescence. The LEDs of the light emitting body 4 can also generate radiation in the ultraviolet (or infrared) range. In this case, the radiation is used directly (in particular, in ultraviolet installations) or is converted into visible light using a mixture of phosphors. It is also possible to obtain a “white” glow by mixing the emissions of LEDs with different colors of radiation (including without the use of phosphors), for example, red, blue and green.

As components of the light emitting body 4, COB or MCB matrices, for example filamentous (LED filaments), can be used. Their application provides the greatest luminous efficiency of a linear LED lamp. Filament matrices (MSWs) have a light output of up to 150 ... 170 lm / W, operate at relatively low operating currents and slightly heat up.

The design of the matrices of the light-emitting body 4 of the lamp, in principle, can be any, including standard. It is possible to use 4 lamps as a light-emitting body and a set of discrete LEDs mounted on substrates (printed circuit boards), for example, using surface mounting technology. The principle of operation of a linear LED lamp does not change. However, the efficiency of lamps with discrete (high-current) LEDs may be lower.

During operation of the device, part of the supplied energy is dissipated, which leads to heating of the elements, including the driver electronic unit 3 and the LEDs (matrices) of the light-emitting body 4 (as well as their phosphor layers, if phosphors are used). The best heat removal is carried out, first of all, due to the uniform distribution of the LEDs or LED matrices (4) in the direction of the axis of the bulb 1 and, as noted, the placement of the light-emitting body 4 (and driver 3) in the region of the flat part of the bulb 1.

Closing the contacts of the elements of external current supply 2 through circuits with low electrical resistance (short circuit) allows us to provide universality (manufacturability) of the lamp when directly replacing gas-discharge linear low-pressure fluorescent lamps in luminaires with electromagnetic and electronic ballasts that have different electrical circuits. At the same time, a new linear LED lamp should be able to supply voltage through the sockets (2) installed on the opposite ends of the bulb 1. The contacts (pins) of the elements of the external current supply 2 can be electrically closed both by the design of the element (base) and by the design, for example, driver panels 3 and light emitting body 4.

Connection of the socles (2) to the internal elements of the lamp, as an option, is carried out due to the “clamping” contact, for example, simultaneously with their mechanical fixation at the ends of the bulb 1.

To increase manufacturability, the elements of external current supply 2 have a means of mechanical fixing at the ends of the bulb 1. The fixing means can be of any design, for example, when the flat parts of the cap (2) and bulb 1 are equipped with a mating: convex element and, accordingly, a groove (the method of "snap").

To increase the manufacturability of the application (to ensure electrical safety and protection against electric shock without using other "external" methods and techniques), the linear LED lamp is equipped with a tool that limits to a safe level (or eliminates) the current through the elements of external current supply 2 when disconnecting one of the power supply circuit elements (2). The principles of the possible arrangement of LED lamps (without the use of special techniques) do not allow to exclude the ingress of high electric potential to the second element of the external current supply (2) when another element is connected to the power supply circuit (2). The indicated potential may present a risk of electric shock when the lamp is installed in the lamp. When disconnecting one of the elements (2) from the power supply circuit 2, the current through the elements of external current supply 2 can be limited to a safe level (or completely eliminated) by a special tool using any of the known methods of limitation (mechanical switch that opens the circuit, breaking electrical contacts to full installing the lamp in the lamp, using sliding bushings, insulating pins of the sockets (2) before installation, the delay in turning on the driver 3 of the lamp due to the electronic circuit or electronic switch of Tell and other means).

To reduce the blinding effect (eliminating the need to use additional diffusers in the light device and, therefore, increase the manufacturability of the application), the optically transparent part of the bulb 1 of a linear LED lamp is made of frosted (opal, milk).

The bulb 1 of a linear LED lamp, as an option, can be made of two mechanically mating parts in the zone of intersection of the surface of the cylinder and the plane. Such a design significantly increases the manufacturability of the product as a result of the simplification (and quality improvement) of the installation of the driver 3 and the light-emitting body 4. The manufacturing process of a linear LED lamp is also more automated (or mechanized).

Compared with the prototype, the manufacturability and use of a linear LED lamp is significantly increased. This is achieved through a more efficient product design. The proposed bulb shape of the new linear LED lamp makes it possible to provide the necessary orientation of the parts and the lamp itself during the assembly process and during installation (use) of the lamp in the luminaires, simplifies the manufacturing technology, including the supply and fixing of elements of the external current supply, driver and light-emitting body , ensures the achievement of effective heat removal from structural elements, optimizes naturally set radiation angles and increases a simpler and more qualitative installing the light efficiency of the device with the light source.

The manufacturability of manufacturing a linear LED lamp increases significantly due to the possibility of the simplest and most effective installation (assembly) of the main structural elements when using flasks made of two mechanically mating parts in the zone of intersection of the cylinder surface and the plane, as well as means of mechanical fixation (snapping-in) of the external current supply elements at the ends of the flask.

The process of mass (serial) production of lamps of the presented design can be better automated (mechanized) in all technological operations of assembly and testing.

Due to the limitation of the current through the elements of the external current supply when one of the elements is disconnected from the power circuit, there is no need to use additional means to protect against electric shock during the installation and replacement of radiation sources in the fixtures. The manufacturability of using a linear LED lamp is also increased due to its versatility (the ability to install in any type of lighting devices for mercury gas-discharge linear low-pressure fluorescent lamps, including when used in hybrid lighting devices with both electromagnetic and electronic ballasts or external power supplies of direct and alternating current). The universal use of the lamp is achieved by implementing the driver and by electrically closing the contacts of the elements of the external current supply (sockets) through circuits with low electrical resistance (short-circuited).

Manufacturability of application is also increased as a result of matting of parts of the flask from an optically transparent material, since it allows to reduce the general requirements for the design of lighting devices. Matting helps to equalize brightness along the length of the lamp, eliminate (reduce) the glare caused by the use of point light sources, eliminates the use of additional tools for these purposes when selling lamps, and the effective orientation of the light-emitting body (lamp) and the regulation (setting) of the radiation angle, in general , provide reduction of unproductive losses of energy of radiation of light-emitting diodes (matrixes) and, accordingly, the general electric expenses of light devices. Thus, in addition to improving manufacturability, in addition, in comparison with the prototype, due to the alignment of brightness along the length and elimination of glare effects, the scope of application of a linear LED lamp is also significantly expanded.

By increasing manufacturability, saving labor costs and, in general, the resources used, compared to the prototype, the price of a new linear LED lamp can be reduced by 10 ... 20%. Price reduction also expands the scope of the lamp of the claimed design.

The new linear LED lamp has a wider scope due to its versatility, the possibility of using it for the complete direct replacement of mercury gas-discharge linear low-pressure fluorescent lamps in any, including hybrid luminaires with various types of installed lamps and ballasts or external drivers, and can be used not only for lighting, but also in lighting fixtures for various technological purposes (in particular, with special designs, ultraviolet and other rakrasnyh light emitter).

Claims (11)

1. A linear LED lamp containing a bulb, at least part of which is made of optically transparent material, with elements of an external current supply at the ends, with a driver and a light-emitting body based on LEDs inside, connected via a driver to elements of an external current supply, characterized in that the outer surface of the bulb is the intersection of the surface of the cylinder and the plane parallel to the axis of the cylinder and spaced from the axis at a distance from 0 to 0.92 of the radius of the cylinder, the light-emitting body is placed in the area of the flat part and oriented in the direction of the part of the optically transparent material. 2. The linear LED lamp according to claim 1, characterized in that the bulb is made of two mechanically mating parts in the zone of intersection of the cylinder surface and the plane. 3. The linear LED lamp according to claim 1 or 2, characterized in that all the contacts of each of the elements of the external current supply are electrically closed through a circuit with a low resistance. 4. The linear LED lamp according to claim 1 or 2, characterized in that the driver ensures operability with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal supply voltage. 5. The linear LED lamp according to claim 1 or 2, characterized in that all the contacts of each of the elements of the external current supply are electrically closed through a circuit with a low resistance, and the driver ensures operability with an amplitude value of the supply voltage from 0.35 to 1.15 amplitude values rated supply voltage. 6. The linear LED lamp according to claim 1 or 2, characterized in that it is equipped with a means limiting the current through the elements of the external current supply when disconnecting one of the elements from the power circuit. 7. The linear LED lamp according to claim 1 or 2, characterized in that all the contacts of each of the elements of the external current supply are electrically closed through a circuit with a low resistance, the lamp is equipped with a means that limits the current through the elements of the external current supply when one of the elements is disconnected from the power circuit. 8. The linear LED lamp according to claim 1 or 2, characterized in that all the contacts of each of the elements of the external current supply are electrically closed through a circuit with a low resistance, the driver ensures operability with an amplitude value of the supply voltage from 0.35 to 1.15 of the amplitude value of the nominal voltage supply, the lamp is equipped with a tool that limits the current through the elements of the external current supply when disconnecting one of the elements from the power circuit. 9. The linear LED lamp according to claim 1 or 2, characterized in that the optically transparent part of the bulb is frosted. 10. The linear LED lamp according to claim 1 or 2, characterized in that the elements of the external current supply have a means of mechanical fixation at the ends of the bulb. 11. The linear LED lamp according to claim 1 or 2, characterized in that the optically transparent part of the bulb is frosted, and the elements of the external current supply have a means of mechanical fixation at the ends of the bulb.

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