RU106799U1 - HYBRID INTEGRATED COMPACT LAMP - Google Patents

Abstract

 Hybrid integrated compact lamp containing a housing with a socket for connecting to the mains, a discharge bulb with a phosphor coating, filled with a working substance and fixed on the housing, an electronic ballast in the form of a printed circuit board assembly on a printed circuit board, including a rectifier and an inverter with a capacitor mounted inside case, inductor located in the immediate vicinity of the discharge bulb or covering part of the discharge bulb, the input terminals of the rectifier apparatus are electrically connected are connected to the base, and the output terminals of the inverter are connected to the terminals of the inductor of the discharge bulb through a capacitor that forms a resonant circuit, LEDs or LED matrix with the inductor, including at least two LEDs connected in opposite-parallel, mounted on a printed circuit board of a printed circuit assembly or on case in the electric circuit of the inductor.

Description

The utility model relates to lighting engineering and instrumentation and can be used in the design of new energy-efficient lighting devices. The utility model aims to expand the scope of the integrated compact lamp.

Known integrated compact lamp containing a housing with a base for connecting to the mains, a discharge flask with a phosphor coating, filled with a working substance and mounted on the housing, an electronic ballast in the form of a printed circuit board assembly on a printed circuit board, including a rectifier and an inverter with a capacitor and inductor, installed inside the housing, the input terminals of the rectifier of the device are electrically connected to the base, and the output terminals of the inverter are connected to the terminals of the electrodes of the discharge bulb through a donkey and a capacitor according to a resonant circuit (Light sources. Catalog. - OSRAM, 2009. - P.3.11).

The disadvantage of an integrated compact lamp is its narrow scope due to the non-optimal light intensity curve in the longitudinal direction, which is due to the design of the discharge bulb and the relatively long burn-up time associated with the establishment of the discharge mode and the need to preheat the internal volume of the discharge bulb and electrodes. The brightness distribution of the known lamp is such that the brightness is greatest in the direction perpendicular to the axis of the discharge bulb. The long time of ignition (setting the nominal luminous flux), especially when using amalgams as a part of the working substance, makes the lamp inconvenient in operation, for example, in applications where operational lighting is required.

Known integrated compact lamp containing a housing with a base for connecting to the mains, a discharge bulb with a phosphor coating, filled with a working substance and mounted on the housing, an electronic ballast in the form of a printed circuit assembly on a printed circuit board, including a rectifier and an inverter with a choke and a capacitor, installed inside the housing, the input terminals of the rectifier of the device are electrically connected to the base, and the output terminals of the inverter are connected to the terminals of the electrodes of the discharge bulb through resonance circuit and capacitor (Lamp catalog 2009/2010 - GE LIGHTING, 2009. - P.74).

The disadvantage of an integrated compact lamp is its narrow scope due to the non-optimal light intensity curve in the longitudinal direction, which is due to the design of the discharge bulb, and the relatively long burn-up time associated with the establishment of the discharge mode and the need to preheat the volume of the discharge bulb and electrodes. The brightness distribution of the known lamp is such that the brightness is greatest in the direction perpendicular to the axis of the discharge bulb. The long time of ignition (setting the nominal luminous flux), especially when using amalgams as a part of the working substance, makes the lamp inconvenient in operation, for example, in applications where operational lighting is required.

Known integrated compact lamp containing a housing with a base for connecting to the mains, a discharge bulb with a phosphor coating, filled with a working substance and mounted on the housing, an electronic ballast in the form of a printed circuit assembly on a printed circuit board, including a rectifier and an inverter with a choke and a capacitor, installed inside the housing, the input terminals of the rectifier of the device are electrically connected to the base, and the output terminals of the inverter are connected to the terminals of the electrodes of the discharge bulb through ossel and capacitor according to the resonant circuit (Energy-saving lamps. Catalog. - GENERAL, 2010. - P.4).

The disadvantage of an integrated compact lamp is its narrow scope due to the non-optimal light intensity curve in the longitudinal direction, which is due to the design of the discharge bulb and the relatively long burn-up time associated with the establishment of the discharge mode and the need to preheat the internal volume of the discharge bulb and electrodes. The brightness distribution of the known lamp is such that the brightness is greatest in the direction perpendicular to the axis of the discharge bulb. Design features are fundamental. The long time of ignition (setting the nominal luminous flux), primarily when using amalgam as a part of the working substance, makes the lamp inconvenient in operation, for example, in applications where operational lighting is required.

Known integrated compact lamp containing a housing with a base for connecting to the mains, a discharge bulb with a phosphor coating, filled with a working substance and mounted on the housing, an electronic ballast in the form of a printed circuit assembly on a printed circuit board, including a rectifier and an inverter with a capacitor mounted inside case, inductor, covering part of the discharge bulb, the input terminals of the rectifier apparatus are electrically connected to the base, and the output terminals of the inverter are connected to the terminals and duktora discharge tube via a capacitor forming a resonant circuit inductor (Induction lamp Catalog -.. UAB "Favorit-EK", 2010. - C.2).

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

The disadvantage of an integrated compact lamp is its narrow scope due to the not optimized luminous intensity curve due to the design of the discharge bulb and the relatively long burn-up time associated with the establishment of the discharge mode and the need to preheat the internal volume of the discharge bulb. The brightness distribution of the known lamp is such that the brightness is greatest in the direction perpendicular to the axis of the discharge bulb. Design features are fundamental. The long time of ignition (setting the nominal luminous flux), primarily when using amalgam as a part of the working substance, makes the lamp inconvenient in operation, for example, in applications where operational lighting is required.

The utility model is aimed at solving the problem of expanding the scope of application of an integrated compact lamp, which is the purpose of the utility model.

This goal is achieved by the fact that in a hybrid integrated compact lamp containing a housing with a socle for connecting to the mains, a phosphor-coated discharge flask filled with a working substance and fixed to the housing, an electronic ballast in the form of a printed circuit board assembly on a printed circuit board, including a rectifier and an inverter with a capacitor installed inside the housing, an inductor located in the immediate vicinity of the discharge bulb or covering part of the discharge bulb, input terminals the device’s finisher is electrically connected to the base, and the output terminals of the inverter are connected to the terminals of the discharge bulb inductor through a capacitor, which forms a resonant circuit, LEDs, or LED matrix with the inductor, including at least two LEDs connected in opposite parallel, mounted on the printed circuit board of the printed circuit assembly mounting or on the housing in the electric circuit of the inductor.

A significant difference characterizing the utility model is a wide scope. The new hybrid integrated compact lamp has an improved light intensity curve, which is achieved due to the adopted new hybrid principle of converting electric energy into light energy. Light energy is generated due to the low-pressure gas discharge in the discharge flask, excited by the induction method, and the energy generated by the LEDs of the LED matrix. LEDs are an effective source of directional radiation, which allows you to adjust the light intensity curve. Since the LEDs have low inertia, the inclusion of a new lamp occurs almost simultaneously with the supply voltage, that is, almost instantly. Both types of conversion of electrical energy into light energy optimally complement each other and allow you to create a hybrid integrated compact lamp with an optimal (given) light intensity curve and quick establishment of the nominal luminous flux. At the same time, the light efficiency of the new lamp is increased due to the hybrid principle of converting electrical energy into light energy, which allows it to be used in energy-saving light systems.

The expansion of the scope by improving the light intensity curve, reducing the burn-up time and increasing the light efficiency of the hybrid integrated compact lamp is the technical result due to the new principle of converting electric energy into light energy, the features of the new lamp design, new elements and electrical connections, i.e. , hallmarks of a utility model. Thus, the distinguishing features of the claimed hybrid integrated compact lamp are essential.

The figure shows an example of a typical design with fragments of a hybrid integrated compact lamp circuit.

Hybrid integrated compact lamp, contains a housing with a cap 1 for connecting to the mains, a discharge flask 2 with a phosphor coating, filled with a working substance and fixed on the housing, an electronic ballast 3 in the form of a printed circuit board assembly on a printed circuit board, including a rectifier and an inverter with a capacitor 4, installed inside the housing, an inductor 5, located in the immediate vicinity of the discharge bulb or covering part of the discharge bulb, the input terminals of the rectifier apparatus are electrically are dined with a base, and the output terminals of the inverter are connected to the terminals of the discharge bulb inductor through a capacitor forming a resonant circuit, LEDs 6 or LED matrix including at least two LEDs connected in opposite parallel, mounted on a printed circuit board of a printed circuit assembly or on the case in the electric circuit of the inductor.

Hybrid integrated compact lamp in steady state operates as follows. The lamp through the base 1 standard type is connected to a conventional AC mains. The housing is a supporting structure on which all other elements of the hybrid integrated compact lamp are mounted. During operation of the device, part of the energy is dissipated, which leads to heating of the elements. Heat removal is carried out, including by the housing. An electronic ballast 3 converts an alternating voltage of a low-frequency supply network into an alternating voltage of increased frequency, which is necessary for supplying a discharge bulb 2 and maintaining an electric discharge therein due to electromagnetic induction (transformer method), as well as for supplying LEDs of an LED matrix 6. The LEDs are connected in opposite directions - in parallel, which allows you to effectively electrically power the matrix 6 from an AC voltage source. When the device is operating, the electronic ballast 3 provides the required voltage conversion parameters (low ripple of the output voltage and current of the discharge bulb 2 and LED matrix 6, stabilized output current, high power factor and efficiency). The rectifier of the electronic control gear 3 rectifies the alternating voltage of the supply network, that is, converts it into an alternating (rectified) voltage, and the inverter inverts the rectified voltage into alternating voltage of a given frequency. Capacitor 4 and inductor 5 form a series resonant circuit, which provides ignition of the discharge in the discharge flask 2 due to voltage resonance and stabilization (limitation) of currents through the elements of the resonance circuit, discharge flask 2 and LED matrix 6. Counter-parallel connection of the LEDs of the LED matrix 6 provides their maximum load in power, which allows to increase light output and reliability of the entire device. When starting the lamp, the LEDs of the LED matrix 6 operate with a maximum luminous flux. After heating the internal volume of the discharge flask 2 and establishing a discharge in the discharge flask 2, the light flux of the LED matrix decreases slightly. An electric discharge in the discharge flask 2 emits light of certain wavelengths (ultraviolet range), which is converted by a phosphor coating phosphor deposited on its inner surface, restoring the missing parts of the spectrum in order to obtain "white light". The energy enters the volume of the discharge flask 2 due to electromagnetic induction from the current of the inductor 5. Electrons accelerated by the electromagnetic field of the inductor cause ionization of the atoms of the working substance of the discharge flask 2 and the formation of plasma. Plasma is a conductive medium. Eddy currents occur in the plasma of the discharge bulb 2, as a result of which the energy is transferred according to the principle of a transformer, the primary winding of which is the inductor 5. Accelerated plasma electrons also excite the atoms of the working substance of the discharge bulb 2. The transition of the atoms of the working substance from the excited to the normal state causes radiation light waves in the ultraviolet range. The discharge in the discharge flask 2 stabilizes the voltage in the electric circuit of the capacitor 4 and the inductor 5 and, accordingly, the current through the LEDs of the LED matrix 6. The LED matrix 6 is installed on the printed circuit board of the printed circuit assembly of the electronic ballast 3, or on the housing in the electric circuit of the inductor. The principle of operation of the lamp does not change. LEDs 6 are energy-efficient sources of directional radiation and allow you to optimally adjust the light intensity curve of a hybrid integrated compact lamp in a given direction. The installation of LED matrix 6 on the lamp housing allows to improve heat dissipation from the LEDs.

The discharge flask 2 can be made without a phosphor coating, for example, in ultraviolet lamps. The working substance of the discharge flask 2 may contain an inert gas and mercury in a free or bound state, for example, in the form of an amalgam, or a new lamp may relate to devices that do not contain mercury. When using an amalgam, the time for establishing the discharge parameters increases, however, due to the operation of the LEDs of the matrix 6, the lamp begins to emit light energy simultaneously with the supply voltage, that is, almost instantly. The principle of operation of the hybrid integrated compact lamp is also not changed.

Compared with the prototype, the scope of the new lamp is expanding significantly. The luminous intensity curve of the hybrid integrated compact lamp in the longitudinal direction is improved. Electric energy is converted into light energy through two channels: from eddy currents excited by electromagnetic induction in a discharge flask (in a gas discharge) and from currents through LEDs. Thus, the new lamp is a hybrid light fixture. LEDs are a directional radiation source, as a result, the light intensity curve can be effectively adjusted in any given direction, including in the longitudinal one. Due to the operation of the LEDs, the time required to establish a given luminous flux of the lamp is reduced. At the same time, the light efficiency of the hybrid device is increased. The LEDs in the new lamp are electrically powered by quasi-sinusoidal current pulses. The LED matrix thus works from an AC voltage source. The energy characteristics of the electronic ballast with this power supply of the LED matrix does not deteriorate. The LEDs themselves provide high light output. As a result, in comparison with the prototype, the light output (luminous efficiency) of the new device can increase up to 100 ÷ 110 lm / W, which is 30 ÷ 40% higher than in the well-known integrated compact lamps.

Compared with the prototype, the design can be significantly optimized and the price of the claimed hybrid integrated compact lamp (with a given light flux) can be reduced by 5–7%. This is achieved by reducing power losses in the elements and reducing their current load, therefore, due to the possibility of using the elements at a lower installed power and with a lower price.

Compared with the prototype, the overall dimensions of the inventive lamp for a given luminous flux (up to 5%) can be reduced by optimizing the design and the hybrid principle of the device. The decrease in weight and size indicators is associated with a decrease in the power of the electronic ballast when the lamp is executed for a given light flux.

Due to the fact that the LEDs belong to light devices with almost instantaneous ignition, the total time of ignition (ignition) and the readiness of a new lamp for operation is reduced, compared with the prototype, which is important for lighting systems with frequent switching on.

The reduction in weight and size indicators and the ability to work effectively in lighting systems with frequent inclusions also significantly expands the scope of the hybrid integrated compact lamp compared to the prototype.

The application of the new hybrid principle allows, in comparison with the prototype, to improve the spectral composition of the radiation of a hybrid integrated compact lamp due to the superposition of the luminescence spectra of the discharge bulb and the radiation of the LED matrix. The color rendering index of a new lamp may be higher.

Claims (1)

Hybrid integrated compact lamp containing a housing with a socket for connecting to the mains, a discharge bulb with a phosphor coating, filled with a working substance and fixed on the housing, an electronic ballast in the form of a printed circuit board assembly on a printed circuit board, including a rectifier and an inverter with a capacitor mounted inside case, inductor located in the immediate vicinity of the discharge bulb or covering part of the discharge bulb, the input terminals of the rectifier apparatus are electrically connected are connected to the base, and the output terminals of the inverter are connected to the terminals of the inductor of the discharge bulb through a capacitor that forms a resonant circuit, LEDs or LED matrix with the inductor, including at least two LEDs connected in opposite-parallel, mounted on a printed circuit board of a printed circuit assembly or on case in the electric circuit of the inductor.