RU142791U1 - ENERGY SAVING LED PHYTOOLITTER - Google Patents

Abstract

1. Energy-saving LED phytoradiator containing light elements, consisting of groups of LEDs with different emission spectra, and a transparent cylindrical ceiling, characterized in that the light elements are fixed on the outer flat faces of the hollow heat-sink profile, representing a regular polygon in cross section, coaxially placed in a transparent cylindrical a plafond and fixed in it with long spring-loaded reflective elements located between the ribs of the heat-removing profile and inside the surface of the transparent cylindrical ceiling, the cross-sectional shape of each springy reflective element depending on the cross-sectional shape of the used heat-conducting profile is selected from the condition of ensuring maximum uniformity of the light flux distribution from the light elements through the transparent cylindrical ceiling to the surrounding space, and the gaps between the heat-conducting profile and the cylindrical ceiling at their ends they are protected by end caps against moisture entering the area of the light elements. 2. Phyto-irradiator according to claim 1, characterized in that the cross-section of the hollow heat-sink profile is square. The phyto-irradiator according to claim 1, characterized in that the light elements are made of a three-color RGB LED strip, the maximum emission of the LEDs of which lie in the blue (400 ... 500 nm), green (500 ... 600 nm) and red (600 ... 700 nm) spectral areas.

Description

The utility model relates to agriculture, to growing plants in a protected ground, in particular to photoculture, and can be used in the field of environment-improving phytotechnologies for the formation of plant lighting environment, in lighting design.

When using optical radiation (OI) in light culture, a prerequisite is energy conservation. This is due to large losses occurring at various stages of energy conversion, in particular, during the spatial distribution of the OI flux. Losses at this stage are associated with the unevenness of the generated irradiation.

A device for irradiating plants is known, consisting of groups of individual light emitting diodes (LEDs) with a different emission spectrum located on one side of flat boards, with the boards placed in a transparent cylindrical shade so that the maximum luminous flux of the LED groups is directed in one direction [Pat . RF №2369086 "LED phytoprojector" / Markov V.N. Application 2008100312/12, 01/15/2008].

The disadvantages of the known technical solutions are as follows. Uneven spatial distribution of the radiation flux of the phytoprojector leads to an uneven distribution of the flux over the irradiated surface. To ensure the required level of irradiation at the least irradiated point, it is necessary to increase the installed power, which leads to additional energy costs and does not allow energy efficiency of the use of LED sources.

The closest technical solution is the LED phytoradiator, consisting of groups of individual LEDs with a different emission spectrum, located on the outside of the flexible semi-cylindrical boards, while the boards are connected in pairs by canopies and placed in a transparent cylindrical shade [Pat. RF №2454066 "LED phytoradiator" / Popova S.A., Suprun M.A. Application 2010109963/13, 03.16.2010].

In the known technical solution, the placement of flat light elements on the floor of cylindrical boards does not allow the required heat sink, which leads to overheating of the LED sources and reduce their service life. The use of a fan for these purposes reduces the reliability and energy efficiency of the device as a whole.

The objective of the claimed utility model is the creation of an irradiator on LED sources, which provides energy saving when applied in light culture.

The technical result is to increase the energy efficiency of phytoradiator by forming a uniform spatial distribution of the flow of OI.

The technical result is achieved due to the fact that the energy-saving LED phytoradiator contains light elements, consisting of groups of LEDs with different emission spectra, a transparent cylindrical shade, while the light elements are mounted on the outer flat faces of a hollow heat-sink profile, representing in section a regular polygon coaxially placed in a transparent cylindrical shade and fixed in it with long spring-loaded reflective elements located between the ribs the heat-conducting profile and the inner surface of the transparent cylindrical shade, the cross-sectional shape of each spring reflecting element depending on the cross-sectional shape of the used heat-conducting profile is selected from the condition of ensuring maximum uniformity of the light flux distribution from the light elements through the transparent cylindrical shade into the surrounding space, and the gaps between the heat-conducting profile and cylindrical shade at their ends are protected by end caps from getting into region of the light elements of moisture.

Significant new features: light elements are mounted on the outer flat faces of a hollow heat-sink profile, representing a regular polygon in cross section, coaxially placed in a transparent cylindrical shade and fixed in it by long spring-loaded reflective elements located between the edges of the heat-shrink profile and the inner surface of the transparent cylindrical shade, while sectional shape of each springy retro-reflecting element depending on the sectional shape used the heat-conducting profile is selected from the condition of ensuring the maximum uniformity of the distribution of the light flux from the light elements through a transparent cylindrical ceiling into the surrounding space, and the gaps between the heat-conducting profile and the cylindrical ceiling at their ends are protected by end caps from moisture entering the region of the light elements.

The listed new essential features in conjunction with the known ones allow to obtain a technical result in all cases to which the requested amount of legal protection applies.

Signs characterizing the utility model in specific forms of execution:

- the cross section of the hollow heat sink profile is a square;

- the light elements are made of a three-color LED RGB tape, the maximum emission of the LEDs of which lie in the blue (400 ... 500 nm), green (500 ... 600 nm) and red (600 ... 700 nm) spectral regions.

Thus, the proposed phyto-irradiator differs from the known ones by the presence of additionally introduced nodes and corresponding functional connections, which provide an increase in energy efficiency when it is used in light culture, which is achieved by ensuring uniform spatial distribution of the OI flux with its given spectral composition and the law of change over time.

The possibility of using the proposed device in agriculture, the popularity of the means and methods by which it is possible to implement a utility model in the described form, the possibility of realizing the indicated purpose in the case of implementing a utility model according to any one of the claims allows us to conclude that it meets the criterion of "industrial applicability".

The analysis of the prior art did not reveal a tool of the same purpose as the utility model, which is characterized by all the essential features given in the independent clause of the utility model formula, which indicates that the proposed technical solution meets the criterion of "novelty."

Figure 1 shows the design of an energy-saving LED phyto-irradiator: 1 - light elements, 2 - hollow heat-sink profile, 3 - transparent cylindrical ceiling, 4 - springy reflective elements, 5 - upper and lower covers. The arrows indicate the direction of the natural circulation of air passing through the lamp along the inner surface of the hollow heat sink profile.

Figure 2 shows the quantities characterizing the radiation process of the OI flux by the light elements: O is the center of radiation of the light element 1, O _x is the direction perpendicular to the plane of the light element 1, O _y is the direction tangent to the plane of the light element 1, n is the normal to the surface reflective element 4 in the direction of the angle γ, I ₀ - light intensity in the direction of O _x , I _γ - light intensity in the direction of angle γ without reflective element 4, - the power of light reflected by the reflective element 4.

Figure 3 in polar coordinates shows the light distribution of the energy-saving LED phytoradiator in a plane perpendicular to its axial line: SC is the light center, I ₀ is the minimum value of light intensity, I _max is the maximum value of light intensity, I is _equal to the value of light intensity with uniform light distribution , A - light distribution curve from the totality of light elements without reflective elements, B - the same, in the presence of reflective elements.

Figure 4 in two projections shows the placement of phytoradiator in the crop: Ф - phytoradiator, and the distance between plants.

The basis of phytoradiator (figure 1) is a transparent cylindrical ceiling 3 made, for example, of glass or acrylic. Inside the plafond there is a hollow profile 2, representing a regular polygon in cross section (for example, a square section profile is shown in Fig. 1), on the outer flat faces of which there are light elements 1, consisting of groups of LEDs with different emission spectra, for example, of a three-color RGB LED -tape, the maximum emission of LEDs which lie in the blue (400 ... 500 nm), green (500 ... 600 nm) and red (600 ... 700 nm) spectral regions. The fastening of the light elements on the profile provides heat removal from the light elements 1 by an upward flow of air passing through the lamp along the inner surface of the hollow heat-removing profile 2 through the holes in the upper and lower covers 5. The reflective elements 4 are made springy and, in addition to correcting the light distribution, serve to fix the profile 2 coaxially in the lampshade 3.

The operating voltage with a certain law of its change in time from the power source through an external control system is supplied to individual groups of light elements. The control system can be an RGB dimmer, a DMX controller, or a control computer. The flow of OI is emitted from T. About (figure 2). The radiation power of the light elements 1 located on one face of the profile 2 in the direction of O _{x is} maximum, in the direction of O _y is minimal. With the joint radiation of the flux from the light elements 1 located on the adjacent faces of the profile 2, the radiation force vectors are assigned to the single light center of the SC. In this case, an uneven spatial light distribution is formed (curve A in FIG. 3). Due to the presence of additionally introduced extended retroreflective elements 4, the total spatial light distribution is adjusted to uniform (curve B in FIG. 3).

Phytoradiator is placed vertically inside the plantings with the possibility of changing its position in height (figure 4). Moreover, all tiers of plants receive uniform irradiation and the flow of OI is used more rationally. The control system (not shown in FIG. 4) is moved outside the phytoradiator housing and may be common to several phytoradiators.

Example. With cosine light distribution of a separate light element located on a rectangular section profile without using additional reflective elements, the dependence of the force on the angle (curve A in figure 3) is described by the equation in polar coordinates

I _γ = I ₀ (cosγ + sinγ).

The function has a maximum value at γ = 45 °, in the direction of the profile edge

I _max = I ₀ (cos45 ° + sin45 °) = 1.41 I ₀

Given the permissible unevenness of the created illumination, and hence the permissible decrease in luminous intensity by 15%, it is possible to determine the critical angle γ _cr , at which the permissible luminous intensity is provided, from the expression

I ₀ (cosγ _cr + sinγ _cr ) = (1.41-0.15) I ₀ .

γ _cr = 18 °.

This means that the lighting requirements are not provided in the directions corresponding to the angles ± γ _cr from the normal to the profile plane. In fractions of all directions of space, these directions are 8 γ _cr / 360 ° = 8 · 18/360 ° = 0.4 or 40%. To ensure the lack of illumination, it is necessary to increase the installed power by this value, or to ensure uniform distribution of light while maintaining the same power. Thus, ensuring uniform distribution of light achieved by choosing the shape of the reflective element increases the energy efficiency of phytoradiator by 40%.

The determination of the shape of the profile, providing the necessary correction of the initial light distribution to uniform, is carried out by known analytical or numerical methods.

A prototype of an energy-saving LED phyto-irradiator was made in the laboratory of energy-efficient electrical technologies of GNU SZNIIMESKh of the Russian Agricultural Academy and is used in light culture experiments.

Additional advantages of the proposed phytoradiator are its increased reliability and lower material consumption.

The application of the proposed utility model in light culture will maximize the energy-saving potential of modern LED sources.

Claims (3)

1. Energy-saving LED phytoradiator containing light elements, consisting of groups of LEDs with different emission spectra, and a transparent cylindrical ceiling, characterized in that the light elements are fixed on the outer flat faces of the hollow heat-sink profile, representing a regular polygon in cross section, coaxially placed in a transparent cylindrical a plafond and fixed in it with long spring-loaded reflective elements located between the ribs of the heat-removing profile and inside the surface of the transparent cylindrical ceiling, the cross-sectional shape of each springy reflective element depending on the cross-sectional shape of the used heat-conducting profile is selected from the condition of ensuring maximum uniformity of the light flux distribution from the light elements through the transparent cylindrical ceiling to the surrounding space, and the gaps between the heat-conducting profile and the cylindrical ceiling at their ends they are protected by end caps from moisture entering the area of the light elements. 2. Phyto-irradiator according to claim 1, characterized in that the cross-section of the hollow heat-sink profile is a square. 3. Phyto-irradiator according to claim 1, characterized in that the light elements are made of a tri-color RGB LED strip, the maximum emission of the LEDs of which are in blue (400 ... 500 nm), green (500 ... 600 nm) and red (600 ... 700 nm ) spectral regions.