RU2378565C1 - Lighting device with extended luminous efficiency on light diode basis - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: invention related lighting engineering and can be used in lighting devices design. Lighting diodes in every i-chain to be chosen by to their straight voltage, according to ratio (1):

where

- real straight voltage value of j-lighting diode from i-chain at current I_p and predetermined temperature value (T_p); U_FM - straight U_F voltage maximum accepted value for light diodes type, used in lighting device, at current I_p and temperature T_p; ΔU_c - design value, real straight voltage value smaller then n·U_FM- not less than ΔU_c. All the stabilisers has maximum value of efficiency factor (EF) at output voltage value (U_out), satisfying correlation (2): U_out0 - ΔU_p ≤ U_out0 + ΔU_p, (2) , where U_out0 - stabiliser output voltage value, which equal to n·U_FM-ΔU_c; ΔU_p ,where ΔU_p predefined maximum accepted deviation real value U_out of stabiliser, at which it has maximum EF, from U_out0.

EFFECT: luminous efficiency increase of lighting device based on light diodes.

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Description

The invention relates to the field of lighting engineering and can be used in the design of lighting devices with increased light output based on LEDs.

Known light device [1], containing a light source, in which there are a number of parallel-connected LED circuits, each of which contains a series of LEDs connected in series, and a secondary power source (VIP), which includes one current stabilizer, to which all LEDs are connected chains. This stabilizer ensures the flow of a predetermined current value through a light device.

However, due to the variation in the magnitude of the geometric and electrophysical parameters, LEDs have different values of forward voltage when the same current flows through them (i.e., different resistances). Therefore, LED chains based on them will also have different resistances. Since in [1] there are no measures to ensure uniform distribution of current between parallel-connected LED circuits, when working in such a light device, a current of different magnitude will flow through them.

To create the required luminous flux by an LED, it is necessary that a current with a given value flow through it. When this current value is exceeded, the dependence of the light flux of the LED on the current flowing through it weakens. As a result of this, the ratio of the luminous flux of the LED to the magnitude of the current flowing through it decreases.

As a result of this, in order to provide the light fixture with the required luminous flux, the total current flowing through it must be increased. This will lead to an increase in the power consumed by the light fixture, i.e. reduce its light output.

A uniform current distribution between the LED circuits is achieved in a light device [2], which contains a light source in which there are N parallel-connected LED circuits (circuits), each of which consists of series-connected LEDs. In addition, the light device contains a secondary power source (VIP), in which there are N linear current stabilizers (stabilizers) of the same type, which stabilize the output current with a given current value (I _s ). In this light device, only one i-th chain is connected to each i-th stabilizer. Therefore, the current flowing through each chain has a predetermined value (I _s ) and remains constant during its operation. This allows the light device to provide the required luminous flux at a given value of the current flowing through it.

However, in [2] there are no requirements for LEDs in terms of forward voltage (U _F ), as a result of which the resistance values of the chains in such a light device can vary significantly. The value of electric losses in linear current stabilizers increases very much when the load resistance deviates from the optimal value. As a result of this, the magnitude of the electric losses in the stabilizers will be large, and the light output of the light device is low.

It is known that in pulsed current stabilizers the magnitude of losses depends less on load resistance than in linear stabilizers. Therefore, their use in a light device [2] instead of linear stabilizers will reduce electrical losses due to the spread in the resistance of the chains. When using pulsed current stabilizers in the light fixture, the inputs of all current stabilizers [3] are connected in parallel to the terminals of the light device to which power is supplied, and only one i-th circuit is connected to the output of each i-th current stabilizer.

The maximum possible value of the direct voltage on the circuit (U _M ) for given values of current (I _s ) and temperature (T _s ) will be determined from the relation (1)

where U _FM - the maximum allowable direct voltage of the LEDs of this type at specified values of current I _s and temperature T _s .

A typical forward voltage (U _FT ) of LEDs can be significantly lower than U _FM , so the actual value of the voltage across the circuit (U _f ) can be significantly lower than U _M.

As a rule, the current stabilizer is adjusted so that it has a maximum value of the coefficient of performance (COP) (β _max ) with a maximum value of U _o (equal to U _M ).

However, since the magnitude of the electric losses in pulse current stabilizers at a given current value depends on the magnitude of their output voltage, for large values of the difference between U _M and U _f this will lead to an unacceptably large decrease in β when operating at the actual load, and therefore not enough high luminous efficiency of a light device in real conditions of its operation.

It should also be borne in mind that LEDs of the same type, having different values of forward voltage (U _F ), when an identical current flows through them, give the same luminous flux. Therefore, LEDs with lower U _F values have better light output.

Based on the foregoing, in order to increase the light output, a light device was developed, which is presented in figure 1. This light fixture consists of a light source (I) containing N parallel-connected LED circuits, each of which consists of n series-connected LEDs (1.1 ... Nn) and a secondary power supply (VIP) (II) containing N-current stabilizers (1 ... N) of the same type, connected in parallel to the terminals (a, b), to which the power supply of the light device with increased light output is supplied. At the same time, only one i-th circuit is connected to each i-th current stabilizer, and the LEDs in each i-th circuit are selected according to their direct voltages based on relation (2):

where U _Fij is the actual value of the direct voltage of the j-th LED of the i-th circuit at a current of I _s and temperature T _s ;

ΔU _c - a given value, not less than by which the actual value of the direct voltage on the chain is less than n · U _FM ,

at the same time, all stabilizers have maximum values of the coefficient of performance (COP) at the values of the output voltage (U _o ), satisfying the relation (3):

where U _vyh0 - output voltage regulator value equal to n · U _FM -ΔU _q;

ΔU _z - the set value of the maximum permissible deviation of the actual value of the value U _o stabilizer, at which it has a maximum value of efficiency, from the value U _o0 .

For experimental verification of the proposed solution, light devices were developed and manufactured. The light source in them was an LED circuit containing eight (n = 8) series-connected LEDs from Cree Inc. type XREWHT-L1-000-00001. For this type of LEDs, the U _FM value with a forward current of 350 mA and a temperature of 25 ° C is 3.9 V. With the same measurement modes, the U _FT value for LEDs of this type is 3.3 V.

The amount of permissible power that can be removed from the light device increases with increasing temperature of the LED crystal. However, this reduces the life of the LEDs. For the LEDs of the type used, a sufficient service life (at least 50 thousand hours) is achieved at a crystal temperature of 80 ° C [4]. Based on this, the light device was designed so that during its operation the temperature of the crystal was close, but did not exceed this value. Therefore, for the developed device, the value of the set temperature (T _s ) was assumed to be 80 ° C.

For LEDs of the type XREWHT-L1-000-00001, the forward voltage decreases by 4 · 10 ^-3 V with an increase in temperature by one degree Celsius. Therefore, for them, the values of U _FM and U _FT (at current values of I _s and temperature T _s ) will be 3.68 V and 3.08 V, respectively. With this in mind, the value ΔU _c for the light device developed on the basis of the proposed solution was determined from the relation (4):

In this case, the maximum value of the forward voltage on the LED circuit, in accordance with the proposed solution (U _M1 ), will be determined from the ratio

From relations (1) and (5), respectively, it follows that the value of U _m will be equal to 29.44 V, and the value of U _M1 is equal to 24.64 V.

With this in mind, two chains were made. In the first, LEDs were used without selection in terms of U _F. They had U _F values from 3.2 V to 3.9 V, and the U _f value for it (U _f1 ) was 28.8 V. In the second chain there were LEDs selected according to U _F so that U _f for her (U _f2 ) was 24.6 V.

Two types of current stabilizers were also developed and manufactured, in which the output current was equal to I _s and amounted to 350 mA. The value ΔU _{s was} taken equal to 1 V. It was determined primarily by the scatter of the nominal values of the parameters of the element base used in the manufacture of the current stabilizer, as well as by the conditions of its operation.

With this in mind, in the first of them the maximum value of efficiency was achieved at

U _o1 = 30 V and amounted to 91%. This corresponds to any type of LED XREWHT-L1-000-00001.

The second of them had a similar maximum value of efficiency of 91% at U _o2 = 24.6 V, which corresponds to the proposed solution.

The dependence of β on U _out at a current of 350 mA for them is shown in figure 2.

From these dependencies it is seen that for a value of U _o in the range (20 ÷ 26) V, which corresponds to the proposed solution, the value of β for the second source is (3 ÷ 4)% higher than that of the first.

Using these light sources and current stabilizers, two light devices were manufactured. In the first, the first chain and the first current stabilizer were used, and in the second - the second chain and the second current stabilizer. The input (consumed by the light device) power was measured on these devices. For the first, at U _f1 = 28.8 V, it amounted to

while, as can be seen from fig.2β _1, equal to 0.905.

For the second at U _f2 = 24.6 V, it was

while, as can be seen from figure 2 β ₂ was equal to 0.910.

Luminous fluxes were also measured, which amounted to Φ ₁ = 880 lm for the first light fixture and Φ ₂ = 876 lm for the second light, taking into account this light output from the first light fixture

составила 78,99 лм/Вт, а у второго

amounted to 78.99 lm / W, while the second

составила 92,60 лм/Вт.

amounted to 92.60 lm / W.

To assess the increase in light output of a light device only by optimizing the design of the current stabilizer, a light device was assembled in which a second chain and a first current stabilizer were used. The value of the efficiency of this current stabilizer at U _f = 24.6 V was 87.5%, the input power of such a light device was 9.84 W, and its light output was 89.02 lm / W.

From the results it follows that the use of the proposed solution allowed for almost the same luminous flux in light devices

(Ф ₁ and Ф ₂ ) to increase the light output of the light device by 17.2% by reducing the power loss in the current stabilizer and LEDs. Moreover, only due to the optimization of the design of the current stabilizer, the light output increased by 3.9%. Which indicates the high efficiency of the proposed solution.

Literature

1. Patent, United States, 5661645, 7 // Peter A. Power supply for light emitting diode array. - Date of Patent 08.26.1997.

2. Patent, United States, 6621235 B2 // Chin Chang. Integrated LED driving device with current sharing for multiple LED strings. - Date of Patent 09.16.2003.

3. Electronic components. Semiconductor lighting // PROSOFT product catalog. - Issue 3, 08. - 2007.

4.www.cree.com/xlamp

Claims (1)

A light device with increased light output (light device), consisting of a light source containing N parallel-connected LED circuits and light fixtures, which includes a secondary power source (VIP) containing N current stabilizers (stabilizers) of the same type, providing output stabilization current with a predetermined value (i _s), wherein outputs of all regulators are connected in parallel to the terminals of a light appliance to which power is supplied, and to each i-th stabilizer is connected only to one-quarter i-I chain, characterized in that, in order to increase its luminous efficiency, light-emitting diodes in each i-th chain chosen from the values of their forward voltages based on the relation (I):

where U _Fij is the actual value of the direct voltage of the j-th LED of the i-th circuit at a current of I _s and a given temperature (T _s );
U _FM - the maximum permissible value of the forward voltage U _F for the type of LEDs used in the light device, at a current of I _s and temperature (T _s );
ΔU _c - a given value not less than by which the actual value of the direct voltage on the chain is less than n · U _FM ,
at the same time, all stabilizers have maximum values of the coefficient of performance (COP) at the values of the output voltage (U _o ), satisfying the relation (2):

where U _vyh0 - output voltage regulator value equal to n · U _FM -ΔU _q;
ΔU _z - the set value of the maximum permissible deviation of the actual value of the value U _o stabilizer, at which it has a maximum value of efficiency, from the value U _o0 .

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