RU191120U1 - LINEAR LED PHYTOR LIGHT - Google Patents

Abstract

The invention relates to lighting technology, namely, LED lamps designed for artificial illumination of plants with a multi-spectral light field with the effect of photobiological action. The essence of the utility model is that in a linear LED phyto-lamp, which includes a housing with a printed circuit board in the form of a strip on which a number of LEDs of various emission spectra are located, arranged in groups with the same number of LEDs in each emission spectrum and in order their following in each group, according to a useful model, the groups of LEDs are located along the length of the board at a distance S from each other, the value of which is selected from the condition S = (1.8-2.2) L, where L is the length of the group of LEDs along the longitudinal axis of the board , including the sum of the linear dimensions of the LEDs in the group in the direction of the longitudinal axis of the board and the gap between the LEDs. The technical result achieved by the implementation of the claimed utility model is to minimize the spread of the spectral characteristics of radiation along the longitudinal lamp axis, which causes an increase in the spectral uniformity of the luminous flux emitted by them. 3 ill.

Description

The utility model relates to lighting engineering, namely to LED lamps designed for artificial lighting of plants with a multi-spectral light field with the effect of photobiological action.

At present, phyto-lighting fixtures are being actively developed, in which light emitting diodes of various colors are used that produce combined light with a spectrum optimized for photosynthesis and photostimulation of plant growth.

Known phyto-lamps made in the form of LED rulers fixed in the housing containing a group or several groups of LEDs of different colors with a selected sequence of their sequence in the group.

These linear luminaires are well adapted to match their sizes with the linear dimensions of the areas for growing plants, including areas in multi-tier greenhouses, which allows, by installing lamps in one or several rows, to achieve illumination of these areas over their entire area.

So, for example, a linear LED phyto-lamp [CN 103267235] is known, which contains a housing and a light source located in the housing, made in the form of an LED array comprising a plurality of adjacent groups of LEDs of different emission spectra containing a combination of white, blue and red LEDs, the number of which varies in the range (5-9): (1-4): (1-5). The specific number of LEDs of each spectral range and the sequence of their sequence in the group is selected depending on the problem being solved. So, in particular, in the case when the quantitative ratio of white, blue and red LEDs is 6: 2: 4, respectively, a luminous flux is emitted that is close in spectral composition to natural light, favorable for the growth of a wide range of plants, in the case when the specified quantitative the ratio is 5: 2: 5, respectively, the luminous flux intended for growing flowering plants is emitted, and in the case when the indicated quantitative ratio is 9: 2: 1, respectively, the luminous flux is emitted, Flailing the growth of plant roots and leaves.

Known linear LED phyto-lamp [CN 203549723], selected as the closest analogue.

This device comprises a housing with a printed circuit board having the form of a strip on which a series of LEDs of various emission spectra are located, arranged in four groups with the same number of LEDs of each emission spectrum and their sequence in each group. So, in each group five sequentially located LEDs were used, including a red LED, a blue LED, a red LED, a warm white light LED and a natural white light LED. These LEDs emit a combined light flux, which helps to accelerate growth and increase the yield of vegetable crops.

Moreover, all used LEDs are evenly distributed along the length of the printed circuit board, and there are no gaps between the groups of LEDs.

However, with the indicated arrangement of the LEDs, the spectral composition of the combined light flux emitted by this device along the length of the lamp is not uniform.

The problem, the solution of which is provided by the implementation of the utility model, is to increase the spectral uniformity of radiation.

The essence of the utility model lies in the fact that in a linear LED phyto-lamp, which includes a housing with a printed circuit board in it, in the form of a strip, on which a series of LEDs of various emission spectra are located, arranged in groups with the same number of LEDs of each emission spectrum and their sequence in each group, according to a useful model, the groups of LEDs are located along the board at a distance S from each other, the value of which is selected from the condition S = (1.8-2.2) L, where L is the length of the group of LEDs in ol longitudinal axis of the board, including the amount of linear dimensions in the group of LEDs in the direction of the longitudinal axis of the board, and the gap between the LEDs.

Due to the presence in the inventive device of groups of LEDs with a different spectrum of illumination and the placement of these groups of LEDs on a printed circuit board in the form of an extended strip, the claimed device is structurally a linear LED lamp emitting a combined light flux.

The spectral characteristics of LEDs with different emission spectra are selected from the conditions for obtaining a combined light flux lying in the PAR region, which has a photobiological effect.

As shown by experimental studies, at the same installation height of the inventive lamp, placing groups of LEDs on the circuit board at a distance from each other and varying this distance, you can influence the spread of the spectral characteristics of radiation along the longitudinal axis of the lamp.

The distance between the LED groups S = (1.8-2.2) L, where L is the length of the LED group along the longitudinal axis of the board, including the sum of the linear dimensions of the LEDs included in the group in the direction of the longitudinal axis of the board and the gap values between the LEDs, was selected the authors experimentally from the condition of minimizing the spread of the spectral characteristics of radiation along the longitudinal axis of the lamp (the spread in the spectral composition of the radiation does not exceed 12%).

Thus, the technical result achieved by the implementation of the claimed utility model is to minimize the spread of the spectral characteristics of radiation along the longitudinal axis of the lamp, which leads to an increase in the spectral uniformity of the light flux emitted by it.

In FIG. 1 presents a General view of the inventive device; in FIG. 2 shows a graph of the distribution along the longitudinal axis of the combined luminous flux emitted by the claimed device; in FIG. 3 shows a graph of the distribution along the longitudinal axis of the combined luminous flux emitted by an analog device.

The device comprises a printed circuit board 1, made in the form of a strip, and groups of LEDs located on it with different emission spectra, with the same number of indicated LEDs in the group and the sequence from each group.

In particular, each group contains red light emitting diode 2, blue light emitting diode 3, red light emitting diode 2, white light emitting diode 4 and red light emitting diode 2 (5 in total) arranged in series along the longitudinal axis of the circuit board 1.

The groups of LEDs are located at a distance S from each other, the value of which is selected from the condition S = (1.8-2.2) L, where L is the length of the group of LEDs along the longitudinal axis of the board, including the sum of the linear dimensions of the group of LEDs in the direction of the longitudinal the axis of the board and the gap between the LEDs.

LEDs 2,3,4, in particular, are coated with lenses.

In particular, 5 groups of LEDs 2,3,4 were used, each of which contains 5 pieces of OSRAM LEDs in the 3535 SMD package, having a linear size in the direction of the longitudinal axis of the lamp (L1) equal to 3.5 mm. In particular, the gap (L2) between the LEDs is chosen equal to 0.3 L1, and is 1.05 mm. In particular, the distance S is selected 2 L = 2 ((5 × L1) + (4 × L2)) = 43.4 mm.

The device comprises (not shown) a long aluminum case, provided with ribs oriented along the longitudinal axis of the case with a developed cooling surface, and holders located in the lower part of the case, with the aid of which a printed circuit board 1 with LEDs 2,3,4 is fixed in the case. The board 1 with LEDs 2,3,4 is flooded with a protective coating, in particular a moisture-proof silicone coating containing

fluorescent additives (UV indicator) to ensure quality control of the application of the specified coating.

The device also contains (not shown) a system for regulating the light flux of LEDs 2,3,4, made, in particular, in the form of a control controller, and a power supply, placed, in particular, outside the housing.

The device operates as follows.

Place the device above the surface of the site with the plants to be grown, installing it at a selected height, in particular, place the device across the beds with plants grown in closed ground, placing it at a height of more than 50 cm.

When power is supplied to the LEDs 2,3,4, they emit red, blue, and white light spectrum, respectively, when mixed, a combined light flux is produced with photobiological activity.

In FIG. 2 presents a normalized (relative to the maximum value) graph of the distribution of radiation intensity (in μmol / m ² s) of the claimed device relative to its longitudinal axis (in mm). As follows from FIG. 2, almost all surface areas with growing plants in the direction of the longitudinal axis of the device are illuminated by a light flux containing spectral components emitted by all five LEDs 2,3,4, while the mutual ratio of these components is practically preserved, which indicates a high spectral uniformity of radiation.

For comparison, in FIG. Figure 3 shows a normalized (relative to the maximum value) graph of the distribution of radiation intensity (in μmol / m ² s) of an analog device relative to its longitudinal axis (in mm). In this case, a device placed at the same height relative to the illuminated plants, containing the same number of LEDs 2,3,4 with the same sequence, but having a uniform distribution of these LEDs along the length of the circuit board 1 without gaps between the groups, was used as an analog device . As follows from FIG. 3, a luminous flux is created in the analog device, in which, in the direction of its longitudinal axis, the spectral components emitted by the five LEDs 2,3,4 are not aligned in the same way, while in some parts of the illuminated surface some component may have a minimum, and on in some areas, the maximum value relative to other components. This indicates a significant spectral heterogeneity created by the analog device of the light flux.

Claims (1)

A linear LED phyto-lamp, which includes a housing with a printed circuit board in the form of a strip, on which a series of LEDs of different emission spectra are located, arranged in groups with the same number of LEDs in each emission spectrum and their sequence in each group, characterized in that the LED groups are located along the length of the board at a distance S from each other, the value of which is selected from the condition S = (1.8-2.2) L, where L is the length of the group of LEDs along the longitudinal axis of the board, including the sum of linear p zmerov included in the group of LEDs in the direction of the longitudinal axis of the board, and the gap between the LEDs.

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