RU2661329C1 - Luminaire - Google Patents

Abstract

FIELD: lighting equipment.

SUBSTANCE: luminaire containing a set of known LEDs with different emission spectra lying in the range of about 400–800 nm, equipped with drivers, is characterized by the fact that the spectra composing a set of selected LEDs, overlap each other in different spectral regions of the range, preferably at 0.5 of the maximum amplitude, using two warm white and one green LEDs with a radiation power of 10 W each, blue, light blue, two full-spectrum LEDs and one LED each with a deep red and infrared LEDs with a radiation power of 3 W each.

EFFECT: invention provides the luminaire with an emission spectrum corresponding to sunlight, while minimizing the total number of LEDs used.

1 cl, 4 dwg

Description

The invention relates to lighting devices that provide illumination with light that most closely matches the spectrum of sunlight through the use of light-emitting diodes.

A known lamp containing a set of LEDs with different emission spectra equipped with drivers, the twelve red LEDs with a wavelength of 660 nm, six orange LEDs with a wavelength of 612 nm and one blue LED with a wavelength of 470 nm (see US No. 6921182) .

Also known is a luminaire containing a set of known LEDs with different emission spectra lying in the range of about 400-800 nm, equipped with drivers (see RU No. 2504143, 2014). At the same time, at least two types of LEDs are used in the luminaire, and it is preferable that the LEDs of the first type emit in the blue region with a wavelength of 400 nm to 500 nm, and the LEDs of the second type emit in the red region with a wavelength of 600 nm to 700 nm, moreover, the light emitted by the first group of LEDs consists of approximately 80-90% of red light and 10-20% of blue light.

All of these solutions were aimed at obtaining the optimal combination of wavelengths to enhance plant growth rates, as well as reducing energy consumption and increasing service life, with technical implementation in comparison with existing light-cultivating technologies, but they do not provide a radiation spectrum close to the spectrum of the sun. In addition, the combination of wavelengths chosen to enhance plant growth is unattractive for people observing an illuminated plant; this is also facilitated by the fact that the total spectrum of such a light source has a sharply uneven (wavy) character.

The problem to which the invention is directed is to provide the lamp with a radiation spectrum corresponding to sunlight.

The technical result, which is manifested in solving the problem, is expressed in providing the lamp with a radiation spectrum close to that of the sun, while minimizing the total number of LEDs used.

To solve this problem, a lamp containing a set of known LEDs with different emission spectra lying in the range of 400-800 nm, equipped with drivers, characterized in that the spectra that make up the set of selected LEDs overlap each other in different spectral parts of the range, preferably at a level of 0.5 of the maximum amplitude, moreover, two warm white and one green LEDs with a radiation power of 10 W each, blue, blue, two full-spectrum LEDs and one deep-level LED were used Cue the red and infrared LEDs with 3 watt light capacity each.

A comparative analysis of the features of the claimed solution with the features of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

Moreover, the set of features of the distinctive part of the claims provides the lamp with a radiation spectrum corresponding to sunlight, and the distinctive features of the distinctive part of the claims provide a solution to the following set of functional tasks:

The signs “spectra that make up the set of selected LEDs overlap in different spectral parts of the range” contribute to the alignment (reduction of waviness) of the total spectrum of the luminaire.

Signs indicating that the spectra that make up the set of selected LEDs overlap "preferably at a level of 0.5 of the maximum amplitude" also contribute to reducing the waviness of the total spectrum of the luminaire.

Signs indicating that “two warm white and one green LEDs with a radiation power of 10 W each, blue, blue, two full-spectrum LEDs and one deep red and infrared LEDs with a radiation power of 3 W each” were used, provide the formation of a spectrum lamp radiation close to sunlight.

In FIG. 1 shows table 1, which shows the emission spectra and characteristics of industrial LEDs; in FIG. 2 shows the spectra of individual industrial LEDs; in FIG. 3 shows the spectrum of the radiated power of a set of LEDs, measured by a TKA-Spectr spectrophotometer; in FIG. 4 shows the emission spectra of the sun and two types of matrix solar spectrum.

Currently, the industry produces various LEDs with a narrow and wide band of radiation, with a peak of radiation falling at one or more specific frequencies of light. It covers a wide range of light frequencies from UV radiation to far red and infrared light. In addition, there are white light-emitting diodes with different color temperatures (see table. 1).

The idea is this: there is a set of LEDs with different spectra. From them you can dial a line of LEDs with overlapping spectral curves at a level of about 0.4-0.6 and then they, summing up their energy parameters, can form a spectrum corresponding to sunlight (see Fig. 3). Thus, if the spectrum of solar radiation is known, then, selecting various LEDs with different spectra and different intensities, you can get a light source that is very similar in its spectrum to solar radiation.

The simulated range of photosynthetically active radiation of the solar spectrum, comprising about 400-800 nm, is implemented by a set of LEDs of the following composition: warm white with a radiation power of 10 W 2 pcs .; GR - green wavelength 520-525 nm and a radiation power of 10 W - 1 pc.; Blue - blue wavelength of 460 nm and a radiation power of 3 W - 1 pc.; Cyan - blue wavelength of 490 nm and a radiation power of 3 W - 1 pc.; FS - full spectrum wavelength of 380 and 840 nm and a radiation power of 3 W - 2 pcs.; IR730 - infrared wavelength of 730 nm and a radiation power of 3 W - 1 pc.; DR - deep red 640 nm with a radiation power of 3 W - 1 pc. Moreover, these LEDs overlap in different spectral parts of the range, preferably at the level of 0.5 of the maximum amplitude.

Spectral and energy parameters were taken for each type of LEDs, which made it possible to form the first approximation of the lamp to the solar spectrum. As an example, 7 types of LEDs with different spectra were selected, which overlapped each other in different spectral regions (Fig. 2). To select an acceptable radiation power, two lines were formed with separate current drivers:

- powered by a driver with a current of 300 mA WW - 2 pcs .; GR - 1 pc.; Blue - 1 pc.; Cyan - 1 pc.; DR - 1 pc.;

- power from the driver with a current of 600 mA FS - 2 pcs .; IR730 - 1 pc.

All LEDs in each line were connected in series, so the voltage at the ends of the first line was 40.8 V; at the ends of the second line of 8.9 V. Accordingly, the power consumption was equal to 12.24 watts and 5.34 watts. The total power consumption was 17.54 watts.

In FIG. Figure 3 shows a curve of the resulting radiated power of a set of LEDs, measured by a TKA-Spectr spectrophotometer device, which allows you to measure the frequency and energy characteristics of electromagnetic radiation in the frequency range 400-800 nm. The vertical ordinate shows the radiation power of each spectral component in units of measurement: mW / m ² . The measurements were carried out with a TKA-Spectr spectrophotometer at a distance of 400 mm from the center of the set of LEDs along their axis. In this case, the PAR illumination in the range of 400-800 nm was Ee (PAR) = 6.66 W / m ² .

As another example in FIG. Figure 4 shows the spectrum of the sun and two options for implementing the matrix of the solar spectrum.

In order for the spectrum of the resulting matrix not to have a wavy character, but to be uniform (as on the curve of the Solar matrix 2, Fig. 4), it is necessary that the spectra of individual LEDs be approximately the same shape (width) and intersect each other at level 0, 5 from the maximum. If, for example, at a frequency of 500 nm there are two LEDs that emit a maximum at 500 nm, and at a level of 0.5, the emission bandwidth of the first will be 50 nm and the second 150 nm, then when summing with other LEDs, unevenness will appear (wave-like, as on the curve of the solar matrix 1). The undulation leads to a difference from the spectrum of the sun, although on average the energy will be the same.

The emission level of light energy for all LEDs should be approximately the same, otherwise the resulting uniform spectrum will not work. For this, it is necessary to select the number of LEDs of the same color so that the total radiation level is equal to the radiation level of the most intense LED in the matrix. To adjust the power, you can also use not the total number of the same monochrome LEDs, but to regulate the strength of the current passing through one powerful LED, the power of which overlaps the power of the sum of weaker LEDs. But then the LED itself will not work at full strength and this will lead to a rise in the cost of the matrix. For example, there is a blue LED (maximum power at a frequency of 440 nm is 10 W / m ² ), green (maximum power at a frequency of 550 nm is 13 W / m ² ), red (maximum power at a frequency of 640 nm is 20 W / m ² ) Then in the matrix it is necessary to select the radiation power of all the LEDs so that at a frequency with a maximum radiation power, each of them emits 20 W / m ² . Those. in this example, to the green LED with a power of 13 W, add green LEDs of lower power with a total value of 7 watts. For the blue LED, you can take two identical 10 W each or one 10 W each and another ten 1 W each.

The industry produces LEDs in denominations of 1, 3, 5, 10, 20, 30, 50, 100, 150, 200, 300 W, so choosing the right number of LEDs so that everyone works at full power is not a problem. Moreover, each LED with its own rating will work with maximum efficiency.

Claims (1)

A luminaire containing a set of known LEDs with different emission spectra lying in the range of 400-800 nm, equipped with drivers, characterized in that the spectra comprising the set of selected LEDs overlap each other in different spectral regions of the range, preferably at a level of 0.5 from the maximum amplitude, moreover, two warm white and one green LEDs with a radiation power of 10 W each, blue, blue, two full-spectrum LEDs and one deep red and infrared LEDs are used Tododi with a radiation power of 3 W each.

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