RU158341U1 - ELECTRIC LAMP - Google Patents

Abstract

1. An electric lamp containing a sealed flask filled with insulating gas with a socle for connecting to an electric network, made of optically transparent material, with 2n, where n is a natural number, LED matrices connected in pairs in series in n electrical circuits, and a support leg inside, having a hollow plug for pumping, a stand with a wire holder and two wire electrodes, the common point of connection of LED matrices n of electrical circuits at n = 1 is formed by connecting the corresponding output s of LED arrays through the holder or, if n> 1, common points of connection of the LED arrays of n electric circuits are connected through the holder or through the holder and additional buses so that the LED arrays additionally form an electrical connection in the form of a 2n-ray star, a driver installed inside the base , the driver input terminals are connected to the base terminals, and the output terminals are connected to the extreme terminals of the LED matrices of n electric circuits through the electrodes at n = 1 or, if n> 1, through the electrodes or through the electrodes Additional shiny.2. An electric lamp according to claim 1, characterized in that the LED matrices are made in the form of rulers with leads at the ends and with an installed circuit or chains of series-connected LED crystals on a metal substrate on one or both sides. An electric lamp according to claim 2, characterized in that one of the terminals of the LED arrays is electrically connected to the substrate. An electric lamp according to claim 2 or 3, characterized in that the LED matrix substrates are profiled from the side ends and have a variable width

Description

The utility model relates to lighting engineering and can be used in the design of new energy-efficient sources of optical radiation with increased service life, universal, designed for both indoor and outdoor lighting. The utility model aims to expand the scope of the electric lamp.

Known electric lamp containing a vacuum flask with a socle for connecting to an electrical network, made of optically transparent material, with a filament body and a support leg inside, having a hollow plug for pumping, a staff with a wire holder and two wire electrodes, the conclusions of the filament body are connected to the terminals the cap through the electrodes (Characteristics of incandescent lamps. Catalog / “GUP RM Lisma”, 2011, P. 32).

An external electrical network is used as a power source for a vacuum lamp related to incandescent lamps. Such a lamp has a fairly wide scope and can be used for indoor and outdoor lighting.

The disadvantages of a vacuum incandescent lamp is a relatively short service life, low energy efficiency, significant heating of parts of the structure during operation. A vacuum lamp is an explosive electrical product. The average life of a vacuum incandescent lamp, as a rule, does not exceed 1000 hours, and the light output is less than 10 lm / W. The noted disadvantages significantly narrow the scope of the known electric lighting lamp.

A known electric lamp containing a sealed flask filled with insulating gas with an external base for connecting to an electric network, made of optically transparent material, with a filament body and a support leg inside, having a hollow plug for pumping, a stand with two wire holders and two wire electrodes, leads glow bodies are connected to the terminals of the cap through electrodes (Spectrum. Catalog of lamps 2009/2010 / GE Lighting), 2009, p. 63).

Known lamp also refers to a type of incandescent lamp. However, it is a variety. This is the so-called gas-filled incandescent lamp.

As an insulating gas in gas-filled incandescent lamps, a certain mixture of gases is usually used (for various reasons), for example, containing from 84 to 86% nitrogen and from 14 to 16% argon at a pressure of from 0.5 to 0.8 bar for a temperature of 273 K .

Preference for incandescent lamps should be given to gases having a low coefficient of thermal conductivity and chemically inert, since such lamps operate at high operating temperatures of the filament body.

An external electrical network is also used as a power source of the known lamp.

The disadvantages of a gas-filled incandescent lamp is a short average life, low energy efficiency, significant heating of parts of the structure during operation. The average life of a gas-filled incandescent lamp usually does not exceed 2000 hours. The maximum light output of a known lamp is about 14 lm / W. These shortcomings narrow the scope of a gas-filled incandescent lamp.

A known electric lamp containing a sealed flask filled with insulating gas with an external base for connecting to an electrical network, made of optically transparent material, with four LED arrays connected in pairs in series into two electrical circuits, and a support leg inside, having a hollow plug for pumping, a staff with two insulated wire holders and four wire electrodes, as well as a driver installed inside the base, the driver input terminals are connected to the terminals the output terminals are connected to the extreme terminals of the LED matrices of two electric circuits through the electrodes, the common points of connection of the matrices of two electric circuits are formed by connecting the matrix leads through the respective holders, a mixture of nitrogen with argon with an argon content of 12 to 20 is used as an insulating gas %, the pressure of the insulating gas is set from 0.5 to 0.6 bar for an ambient temperature of 273 K (START lamps with a filament-like LED. Catalog of lamps / Start LLC, Novgorod, 2014).

The majority of lighting lamps with linear LED arrays for low currents have a similar design. The lamp refers to the type of so-called filament lamps that use in the matrix design series-connected low-power LEDs in the form of rulers (SOV or MSOV technology). A light-emitting body (a set of LED matrices) in such a lamp is isolated from the external environment and is not subject to its influence.

The disadvantages of the known electric lamp of the considered design is the relatively short service life, which is due to the increased heating of the LEDs and electronic elements and components of the device (which makes it difficult to use in closed lighting fixtures), technical and technological complexity (low manufacturability of the design, a large number of vacuum-tight solders, electrodes and holders), which reduces the reliability of the work and increases the price of the product. The lamp has a relatively low light output (about 100 lm / W), which is explained by an insufficiently efficient heat sink due to the used composition of the insulating gas. The disadvantages of the known electric lamp narrow the scope of its application.

A known electric lamp containing a sealed flask filled with insulating gas with a socle for connecting to an electric network, made of optically transparent material, with 2n, where n is a natural number, LED matrices connected in pairs in series in n electrical circuits, and a support leg inside having a hollow plug for pumping, a stand with a wire holder and two wire electrodes, as well as a driver installed inside the base, the driver input terminals are connected to the base terminals, and the output water are connected to the extreme terminals of the LED matrices of n electric circuits through the electrodes, the holder and electrodes are formed in the corresponding planes perpendicular to the axis of the legs, so that they form a shape in the form of the sign S or its mirror image, common points of connection of the LED matrices of n electric circuits are connected through the holder so that the LED arrays additionally form an electrical connection in the form of a 2n-ray star, using nitrogen or a mixture of nitrogen with neon as an insulating gas with Rye neon in a mixture of 4 to 96%, the pressure of the insulating gas is set from 0.3 to 3.3 bar for an ambient temperature of 273 K (P. according to the application for the payment order No. 2015104375 of 02/10/2015. Electric lighting lamp / E.M. Silkin // Decision on the grant of a patent dated 03/26/2015.

The considered LED electric lamp is the closest in technical essence to the utility model and is selected as a prototype.

A disadvantage of the known electric lamp is a relatively narrow scope. This is due to the limited design, which does not allow, in particular, to effectively increase the number of type designs to ensure the required manufacturability. As a result, electric lamps of a given type design can have a relatively high price. A known lamp may also have a relatively low luminous flux and not an optimal light intensity curve. The possibilities for increasing the luminous flux (by increasing the number of LED matrices), as well as improving the light intensity curve, are largely limited due to the limited design. The known lamp does not have a sufficiently high light output (about 110 lm / W) due to the increased heating of the matrix LEDs with an insufficiently efficient heat sink. The known lamp has, in addition, low reliability and low average life, also due to the increased heating of the LEDs of the matrices used in operating modes. Due to the limited working volume inside the base, it is also difficult to execute a driver with the required characteristics. As a result, the known electric lamp may have underestimated technical parameters.

The utility model is aimed at solving the problem of expanding the scope of the electric lamp, which is the purpose of the utility model.

The specified goal is achieved by the fact that:

1. an electric lamp containing a sealed flask filled with insulating gas with a socle for connecting to an electric network, made of optically transparent material, with 2n, where n is a natural number, LED matrices connected in pairs in series in n electrical circuits, and a support leg inside, having a hollow plug for pumping, a stand with a wire holder and two wire electrodes, the common point of connection of LED matrices n of electrical circuits at n = 1 is formed by connecting the corresponding output s of LED arrays through the holder or, if n> 1, common points of connection of the LED arrays of n electric circuits are connected through the holder or through the holder and additional buses so that the LED arrays additionally form an electrical connection in the form of a 2n-ray star, a driver installed inside the base , the driver input terminals are connected to the base terminals, and the output terminals are connected to the extreme terminals of the LED matrices of n electric circuits through the electrodes at n = 1 or, if n> 1, through the electrodes or through the electrodes additional buses;

2. according to claim 1, LED arrays are made in the form of rulers with leads at the ends and with an installed circuit or chains of series-connected LED crystals on a metal substrate on one or both sides;

3. according to claim 2, one of the terminals of the LED arrays is electrically connected to the substrate;

4. by item 2 or 3, the substrates of the LED arrays are profiled from the side ends and have a variable width, the width of the substrate being greater at the locations where the LED crystals are installed;

5. according to claim 1, the tires are in the form of a half ring or a straight line segment;

6. according to claim 1, the respective busbars are rigidly connected in pairs through dielectric inserts;

7. according to claim 1, the electrical connection in the form of a 2n-ray star is formed by directly connecting the common points of the connection of LED matrices n electrical circuits without using a holder and additional buses;

8. according to claim 1, the driver is made up of two parts, the parts are electrically connected, and the second part of the driver is installed inside the bulb.

A significant difference characterizing the utility model is the expansion of the field of application of an electric lamp by expanding the range of type designs while increasing the manufacturability of standard designs, ensuring the possibility of an effective increase in luminous flux and light output, increasing the reliability and average life, reducing prices in the manufacture of lamps of various types and design lamps for a given luminous flux, reducing the price of used LED arrays, lowering the heating temperature Tei lamps and to improve the operating conditions of the lamps contained light devices of limited volume, improving the performance of lamps (power factor, the factor of luminous flux pulsation factor of input current harmonics, light distribution in space). The expansion of the scope is due to new device principles, a new lamp design, a new LED matrix connection scheme, a driver device, new elements and connections, that is, the hallmarks of a utility model. Thus, the distinguishing features of the claimed electric lamp are essential.

The figure shows a typical design of a new electric lamp with a standard element of an external current supply (network socket class E27 or E14).

The electric lamp contains a sealed flask 1 filled with insulating gas 1 with a cap 2 for connecting to an electric network, made of optically transparent material, with 2n, where n is a natural number, LED matrices 3 connected in pairs in series in n electrical circuits, and a support leg inside, having a hollow rod-gel 4 for pumping, a staff with a wire holder 5 and two wire electrodes 6, the common point of connection of LED matrices n of electric circuits at n = 1 is formed by connecting the corresponding LED matrix arrays through the holder or, if n> 1, common points of connection of the LED matrices n of electrical circuits are connected through the holder or through the holder and additional buses 7 so that the LED arrays additionally form an electrical connection in the form of a 2n-ray star, driver 8 installed inside the base, the driver input terminals are connected to the base terminals, and the output terminals are connected to the extreme terminals of the LED matrices of n electric circuits through the electrodes at n = 1 or, if n> 1, through the electrodes or through the electric odes and additional buses.

LED matrixes, as an option, are made in the form of rulers with leads at the ends and with an installed circuit or chains of series-connected LED crystals on a metal substrate on one or both sides.

In this case, one of the conclusions of the LED matrices on a metal substrate is electrically connected to the substrate.

Also, the metal substrates of the LED arrays can be profiled from the side ends and have a variable width, and the width of the substrate is greater at the installation sites of the LED crystals.

Tires, mainly, have the form of a half ring or a straight line segment.

Corresponding tires in standard designs can be coupled rigidly through dielectric inserts 9.

An electrical connection in the form of a 2n-ray star can be formed by directly connecting common points of connection of LED matrices n electrical circuits without using a holder and additional buses.

The driver in the versions is made up of two parts, the parts are electrically connected, and the second part of the driver is installed inside the bulb.

The electric lamp in steady state operates as follows. Through the base 2 of a standard type (for example, E27 or E14), an electric lighting lamp is connected directly to a conventional power supply AC electric network (external power supply) or to a special DC network (source). Bulb 1 from an optically transparent material is the main part of the design of the electric lamp, which has a bearing, protective, light-scattering function and the sealing function of the working space in which the LED arrays are placed 3. Bulb 1 is rigidly mechanically connected (paired) with the cap 2. The terminals of the cap 2 are connected to driver 8 input terminals, the output terminals of which through electrodes 6 soldered into the leg are connected to the extreme terminals of the LED matrices 3 connected in pairs in series into one or more (n) elec chain-empirical. The LED arrays 3 are additionally electrically connected (via a common holder 5 or via a common holder and additional buses 7) by common points (common terminals) of the connection to a two- or multi-beam (2n) star. It is also possible to directly connect the common conclusions of the matrices 3 (without using the holder 5 and additional buses 7) into a 2n-ray star. The latter is more technological. The principle of operation of the lamp does not change. Tires 7 allow to spread LED matrix 3 in the workspace. The whole structure is placed inside the bulb 1 and is isolated from the environment. The number (2n) of matrices 3 is selected from the condition for obtaining a given luminous flux of an electric lamp. For simplicity, the figure shows the option of installing two LED matrices 3 in the lamp, which corresponds to one electric circuit (n = 1). If 3 matrices are more than two, they are installed in the same way. The electrical connection of the matrices 3 in the form of a 2n-ray star increases the reliability of the device. In particular, when one of the matrices 3 of the electric circuit fails (for n> 1), the second matrix remains in an operable state. The ability to connect several electrical circuits of the LED matrix 3 is provided, in particular, by molding the holder 5 and electrodes 6 in the respective planes perpendicular to the axis of the legs. Perhaps, as already noted, the use of additional tires 7. Designs have a fairly high adaptability and are used for certain types of lamps. Driver 8 converts the voltage (energy) of an external power source (mains) into a voltage (current) of a given level and frequency, which is necessary to power the matrix LEDs 3. The matrix LEDs 3 can be powered from driver 8 both on direct and alternating current. When powered by alternating current, the electrical circuit for connecting the electrical circuits of the matrices of 3 LEDs differs from the direct current circuit (n> 1). AC power can be more energy efficient. The number of stages of energy conversion is reduced, which, in General, increases the reliability of the driver 8 and the light output of the lamp. The average life of the electric lamp is also increasing. Driver 8 can also be made up of two parts. In this case, the second part of driver 8 is located inside the bulb. Running driver 8 in two parts improves lamp performance. The lamp, in particular (with the appropriate driver 8), will have higher performance in terms of power factors, ripple of the light flux, harmonics of the consumed current and the distribution of the light flux in space. When placing the driver 8 in the base 2 of the working volume, as a rule, it is not enough to ensure high quality products. Flask 1 is filled with insulating (buffer) gas. Pumping and filling of the internal volume of the flask 1 is carried out through the stem 4 of the support leg, which is hollow. After filling the flask 1 with insulating gas, the plug 4 is sealed off. As a buffer gas, for example, a mixture containing more than 90% neon and less than 10% nitrogen at a pressure of 3.3 bar is used (for a temperature of 273 K). This provides a good heat dissipation from the LEDs of the matrices 3, therefore, their high reliability and high light output of the lamp. When using only nitrogen, the heat sink deteriorates, but for low power lamps this is acceptable. In any case, the composition of the insulating gas and its pressure should provide the best heat dissipation from the elements and components of the electric lamp installed inside the bulb 1, and sufficient electric strength. For better heat dissipation, it is necessary to use an insulating gas (or gas mixture), which has increased thermal conductivity, and increase its pressure in bulb 1. Therefore, it is not practical to set the pressure of insulating gas in bulb 1 below 0.3 bar for the inventive lamp. In practice, the absolute pressure for most modifications of LED lamps of the claimed design should be in the range from 0.3 to 3.3 bar (which is the most technologically advanced). The volume of flask 1 and its shape should also be optimized in order to improve heat dissipation. Close to optimal are the standard shapes and sizes of flasks (1) used for serial incandescent lamps. In this case, the LED matrix 3 should be placed (if possible) at a minimum distance from the walls of the flasks (1). When an electric current passes through the LEDs of the matrices 3, they emit light waves, in particular, visible light. It is also possible, for example, radiation in the ultraviolet region of the spectrum, which is provided by the type of matrices 3 used in LED lamps.

The need for gas mixtures is dictated by the requirements for the electrical strength of the insulating filling, as well as economic reasons. Dielectric strength increases with increasing pressure. The price of the gases and gas mixtures used is of exceptional importance, since it affects the final price of the product in mass production. In this regard, it is promising to use in the inventive electric lighting lamp gas mixtures of nitrogen with neon. Neon provides a relatively good heat dissipation from structural elements and sufficient lamp reliability. The thermal conductivity of nitrogen is approximately two times lower than the thermal conductivity of neon.

LED matrix 3, as an option, is made in the form of lines with leads at the ends and with an installed circuit or chains of series-connected LED crystals on a metal substrate on one or both sides. The implementation of the substrate of metal can increase the mechanical strength of the LED matrix 3 and significantly improve the heat sink from the LED crystals.

In this case, one of the terminals of the LED arrays 3 on a metal substrate is electrically connected to the substrate. This makes the design of matrices 3 more technological and reduces their price.

Also, the metal substrate of the LED matrix 3 can be profiled from the side ends and have a variable width, and the width of the substrate is greater at the installation sites of the LED crystals. When applying the phosphor, the distribution of the light flux of the matrices 3 in space in this case is improved.

Tires 7, mainly, have the form of a half ring or a straight line segment. Tires 7 provide a spacing of the matrices 3 in the working space of the bulb 1.

Corresponding buses 7 in standard designs (connected to the holder 5 and, respectively, to the electrodes 6) can be coupled rigidly symmetrically through special dielectric inserts 9. This makes it possible to increase the manufacturability of the structure and improve the design of the electric lamp. The product (unit with matrices 3) acquires more accurate dimensions. Provides repeatability in the manufacture of individual lamps.

Compared with the prototype, the scope of the electric lamp is significantly expanded.

Indeed, the new lamp can be used more efficiently for both indoor and outdoor lighting, as well as in indoor luminaires of limited volume.

The range of types of lamp designs is expanding significantly. Each type design can be an optimal design and a fairly technological product, which reduces the price.

The new design of the electric lamp is generally more technologically advanced, which makes it possible to manufacture devices with large luminous fluxes using unified LED arrays for minimum power, as well as arrays on metal substrates. In the prototype lamp, the luminous flux can be increased only to a limited extent due to the use of LED arrays of increased power. However, the light efficiency of the prototype lamp will decrease due to the deterioration of the thermal regime of the LEDs. In the new lamp, the decrease in light output with increasing power and luminous flux is much less pronounced. The heat sink from the LED crystals in the new lamp is higher, which increases reliability. The ability to produce lamps without a holder reduces the number of technological operations and also reduces the price of products in serial production.

Due to the lower operating temperature of the LEDs, the light output of the lamp is significantly increased (when executed at a given light flux).

Simplified and cheaper maintenance of lighting systems with the claimed lamps.

The new lamp design allows the development and application of direct (or alternating) current drivers with much higher technical characteristics than in the prototype lamp. It also, in general, improves reliability and increases the average life of the electric lamp.

Reducing prices and increasing service life, as well as higher light output, expand the scope of the claimed electric lamp.

The luminous efficiency of the inventive lamp can be 10 ... 15% higher than the luminous efficiency of the prototype lamp.

The service life of a new electric lighting lamp (according to expert evaluation) exceeds the service life of a prototype lamp by 1.2 ... 1.4 times (due to improved working conditions of LED arrays, as well as the driver).

Claims (8)

1. An electric lamp containing a sealed flask filled with insulating gas with a socle for connecting to an electric network, made of optically transparent material, with 2n, where n is a natural number, LED matrices connected in pairs in series in n electrical circuits, and a support leg inside, having a hollow plug for pumping, a stand with a wire holder and two wire electrodes, the common point of connection of LED matrices n of electrical circuits at n = 1 is formed by connecting the corresponding output s of LED arrays through the holder or, if n> 1, common points of connection of the LED arrays of n electric circuits are connected through the holder or through the holder and additional buses so that the LED arrays additionally form an electrical connection in the form of a 2n-ray star, a driver installed inside the base , the driver input terminals are connected to the base terminals, and the output terminals are connected to the extreme terminals of the LED matrices of n electric circuits through the electrodes at n = 1 or, if n> 1, through the electrodes or through the electrodes additional buses. 2. An electric lamp according to claim 1, characterized in that the LED matrices are made in the form of lines with leads at the ends and with an installed circuit or chains of series-connected LED crystals on a metal substrate on one or both sides. 3. An electric lamp according to claim 2, characterized in that one of the terminals of the LED arrays is electrically connected to the substrate. 4. An electric lamp according to claim 2 or 3, characterized in that the substrates of the LED arrays are profiled from the side ends and have a variable width, the width of the substrate being greater at the locations where the LED crystals are installed. 5. The electric lamp according to claim 1, characterized in that the tires are in the form of a half ring or a straight line segment. 6. The electric lamp according to claim 1, characterized in that the respective busbars are rigidly connected in pairs through dielectric inserts. 7. The electric lamp according to claim 1, characterized in that the electrical connection in the form of a 2n-ray star is formed by directly connecting the common points of the connection of the LED arrays of n electrical circuits without using a holder and additional buses. 8. The electric lamp according to claim 1, characterized in that the driver is made up of two parts, the parts are electrically connected, and the second part of the driver is installed inside the bulb.

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