RU2709466C1 - Method for production of linear led phyto-lamp - Google Patents

Abstract

FIELD: lighting technology.

SUBSTANCE: invention relates to lighting engineering, namely to LED lamps intended for artificial illumination of plants with a different-spectral light field with the effect of photobiological action. Method of making a linear LED phyto-lamp comprises the steps of: making an aluminum body with the possibility of accommodating a channel for forced water cooling and attaching a LED strip thereto. Aluminum housing is made by extrusion in form of Ω-shape, with a lower flat part and an upper rounded part, and the light-emitting diode tape is made by soldering to a light-emitting diode of a different spectrum of luminescence and a power cable, with subsequent installation on each LED using a lens holder, creating a light beam with angle of 60°. In the lower flat part of the profile, after application of the heat-conducting paste, a LED tape is installed and fixed by means of fasteners, and in the upper rounded part of the profile along the light-emitting diode tape there is a channel for forced water cooling. On lateral ends of aluminum housing ends are fixed, made in form of nozzle for supply of cooling water with sealing rubber glands for insulation of housing of phyto-lamp, note here that unions with sealing rubber glands arranged in grooves are secured at channel ends for forced water cooling by their pressing.

EFFECT: simplified design, improved heat removal from light-emitting diodes, improved tightness, as well as improved emitting characteristics of light-emitting diodes.

1 cl, 4 dwg

Description

The invention relates to lighting equipment, namely, to LED lamps intended for artificial lighting of plants with a multi-spectral light field with the effect of photobiological action.

The problem of growing plants in greenhouses, greenhouses, winter gardens, agro-industrial complexes, as well as at home in the autumn-winter period is that there is not enough light for the normal course of physiological processes, so plants, in particular seedlings, have to be additionally irradiated .

It is known that sunlight can be decomposed into a spectrum with different light wavelengths: the ultraviolet part lies below 380 nm, the violet part lies in the region of 380-430 nm, the blue part is 430-490 nm, the green part is 490-570 nm, and the yellow part is 570-600 nm, red and orange - 600-780 nm, infrared - above 780 nm. Each part of the spectrum in its own way affects the physiology of plants. The ultraviolet part with wavelengths less than 280 nm is fatal to plants, the range of ultraviolet rays 315-380 nm is useful for metabolism and plant growth, ultraviolet radiation in this wavelength range inhibits the extension of stems. Radiation with wavelengths from the range 280-315 nm affects plants, increasing their cold resistance. The blue (430-490 nm) and violet (380-430 nm) parts of the radiation spectrum inhibit excessive plant growth. Exposure to this radiation stimulates the formation of plant proteins and cell division. This part of the spectrum is almost completely absorbed by chlorophyll, which is the key to intense photosynthesis. The green part of the spectrum (490-570 nm) is practically not absorbed by the leaf plates of plants, with their excess, the plants become thin, elongated. At the same time, photosynthesis is in progress, but its level is the lowest. The red and orange parts (600-780 nm) account for a peak in photosynthesis. These wavelengths affect the development and regulation of all processes: metabolism, respiration, root system development, flowering. The most important segment is 625-720 nm, these rays contribute to the growth, production of carbohydrates, densely absorbed by chlorophyll. Infrared rays also affect plants, but their effect is somewhat specific, they create thermal conditions for physiological processes and photosynthesis.

With the development of science and the advent of new technologies, lighting fixtures are actively being developed in lighting, in which LEDs of various colors are used as radiation sources. The luminous flux in the luminaires of modern designs can reach significant values due to the use of powerful LEDs, which accordingly increases the technical requirements regarding solutions for the efficient removal of heat generated. The main reason for heating the LED is the heat generated during its operation. For the organization of the correct mode of operation, it is necessary to ensure efficient heat dissipation.

There are various structural designs of LED lamps containing a housing made in the form of a heat sink profile with heat sink ribs that are formed during the manufacture of the profile, an LED radiation source, power supply and control wires to the LEDs from an external power circuit, as well as elements for attaching the device to the supporting surface (patent RU 116201, patent RU 85784, patent RU 124768, patent US 20070058368, patent US 5278432).

However, the known fixtures are difficult to manufacture due to the need to perform on the outer surface of the casing of the fins, which performs the function of radiators to remove heat from the housing. The presence of fins on the housing complicates the design, leads to an increase in their mass, dimensions and, as a result, the cost of fixtures increases. The service life of such lamps is limited as a result of their overheating. This is due to the fact that heat is removed from the internal volume of the housing by means of fins mounted on the outer surface of the housing, i.e. the heat from the LEDs enters the radiator and is “stretched” over its entire area not uniformly, which leads to an increase in the temperature of the lamp, as well as uneven lighting.

To improve heat dissipation, phyto-luminaires were developed in which a channel for forced water cooling was used instead of a radiator to remove heat from the luminaires.

A known method of manufacturing a linear LED phyto-lamp (patent CN 103032769), which is closest to the claimed invention (prototype), comprising a square-shaped aluminum housing, an LED strip equipped with a plurality of LEDs and light-transmitting glass, which are installed in the lower part of the aluminum case, in the middle part an aluminum case there is a channel for forced water cooling, and on one (lower) side of the channel for forced water cooling are located those indicated LEDs, and on the other (upper) side of the channel for the cooling water is forced board LED control circuit also comprises a sealing tape fitosvetilnik disposed just before the LED ribbon at the bottom of the aluminum case.

The disadvantage of the prototype is the complex design, low (insufficient) heat sink, since the channel for forced water cooling is located in the middle of the aluminum case and is designed to remove heat not only from the LEDs, but also from the LED control circuit board located on the opposite side of the channel, which in turn leads to an increase in the temperature of the phyto-lamp, as well as uneven lighting. Another disadvantage of the prototype is uneven lighting, since the presence of light-transmitting glass along the entire LED strip (located at a certain distance from them), instead of the lenses on each LED, leads to insufficient lighting, which is necessary for the normal course of physiological processes. Another disadvantage of the prototype is the low tightness of the luminaire, since the sealing tape is located only on the front side of the LED strip and is designed to seal the LEDs, while there is no channel sealing for forced water cooling.

The technical result of the claimed invention is to simplify the design, improve the heat sink from the LEDs, increase the tightness, and also improve the emitting characteristics of the LEDs.

The claimed technical result is achieved by the fact that the method of manufacturing a linear LED phyto-lamp contains the following steps: manufacturing an aluminum housing with the possibility of placing a channel for forced water cooling and attaching an LED strip to it, the aluminum housing being made by extrusion in the form of an Ω omega profile, from the bottom flat part and upper rounded part; LED strip is made by soldering to a rail of LEDs of various emission spectra and power cable; install on each LED, using the holder, a lens that creates a light beam with an angle of 60 °; in the lower flat part of the profile, after applying heat-conducting paste, the specified LED strip is installed and fixed with fasteners, and in the upper rounded part of the profile, along the LED strip, a channel for forced water cooling is placed; the ends made in the form of a fitting for supplying cooling water with rubber sealing glands to isolate the phyto-lamp housing are fixed on the lateral ends of the aluminum case;

In a preferred embodiment, the LED strip contains LEDs of the red spectrum, blue spectrum, yellow spectrum and UV spectrum.

In the claimed method of manufacturing a linear LED phytosanitary fixture, the simplification of the design is ensured by the manufacture of a single housing in the form of an Ω omega profile by extrusion, as well as by the manufacture of an LED strip in which the LEDs and the LED power cable are soldered to the rail. Improving the heat sink from the LEDs is ensured by the forced water cooling channel located in the upper rounded part of the aluminum Ω omega profile along the LED strip, which allows for adequate heat removal from the phyto-lamp housing, keeping the temperature of the LEDs at 60 °, which in turn extends the life service and preserves the emitting characteristics of LEDs. Improving the tightness is ensured by pressing on the ends of the aluminum body of the endings, which simultaneously play the role of fittings for supplying cooling water and rubber sealing glands for insulation of the body of the luminaire. Improving the emitting characteristics of LEDs is ensured by installing a lens on each LED, which creates a light beam with an angle of 60 °, which in turn leads to an improvement in photosynthesis and photostimulation of plant growth.

The invention is illustrated by drawings, where:

FIG. 1 is a General view of a linear LED phyto-lamp assembly,

FIG. 2 - a linear LED phyto-lamp in a collapsible form,

FIG. 3 - aluminum casing of a linear LED phyto-lamp in the form of an Ω omega profile (sectional view),

FIG. 4 - end fitting with rubber sealing glands assembled.

In FIG. 1 shows a general view of a linear LED phytosanitary assembly, which is designed for artificial lighting with a multi-spectral light field of plants in greenhouses, greenhouses, conservatories, agricultural complexes, as well as at home.

In FIG. 2, on the left side, the aluminum housing 1 of a linear LED phyto-lamp, made by extrusion in the form of an Ω omega profile, is represented on the right side, LED strip 2, with LEDs and LED power cable soldered to the rail, and in the middle is LED strip 2 already in assembled, where each LED has a holder with a lens that creates a light beam with an angle of 60 °. Moreover, said LED strip preferably contains 28 LEDs of different emission spectra (Fig. 1).

In FIG. Figure 3 shows an aluminum casing made by extrusion in the form of an Ω omega profile (in section). An LED strip 2 is installed in the lower part of the aluminum housing 1, which is flat, and a channel for forced water cooling 3 is located in the upper part of the aluminum housing, which is rounded. Moreover, the channel for forced water cooling 3 is located along the entire LED strip 2, which makes it possible to provide appropriate heat removal from the aluminum housing of the phyto-lamp by controlled water flow, while keeping the temperature of the LEDs at a level of up to 60 °. The above-mentioned manufacture of an aluminum case with a channel for forced water cooling, as well as the absence of additional structural elements (for example, such as an LED control board) that produce heat, allows for the appropriate microclimate in greenhouses, greenhouses, conservatories, agricultural complexes, as well as at home, due to the high temperature of the lamp.

For sealing (isolation) of the phyto-lamp housing on the lateral ends of the aluminum housing 1, the tips 4 (gland-fittings) are installed. As seen in FIG. 4, the tips 4 are made in the form of a fitting with rubber sealing glands, which simultaneously play a role for supplying cooling water and for isolating the housing 1 of the luminaire, respectively.

The manufacturing process of the claimed linear LED phyto-lamp contains the following steps.

At the first stage, an aluminum housing of 1 Ω omega profile is manufactured. The manufacturing process of the Ω omega profile is carried out by extrusion, a continuous process during which extruded molten aluminum through an extrusion die under high pressure. The resulting aluminum housing 1 of a linear LED phytosanitary fixture preferably has the following dimensions: length from 1090 to 1110 mm., Width 30 mm., Height 30 mm.

At the second stage, LED strip 2 is made. LEDs of various emission spectra and a power cable for the LEDs are soldered to the strip of LED strip 2. Then on each of the LEDs put on (fasten) the holder into which the lens is inserted, forming a light beam (cone) with an angle of 60 °. LED strip 2 preferably contains 28 LEDs, including: red spectrum LEDs - 15 pcs., Blue spectrum - 5 pcs., Yellow spectrum - 5 pcs., UV spectrum - 3 pcs. In the manufactured luminaire, preferably, emitter type LEDs are used, the total power of which is 50 watts. The power supply of the luminaire is preferably carried out by a voltage converter 220V / 54-84V.

At the third stage, the endings 4 are made, which simultaneously play the role of fittings designed to supply cooling water, and rubber sealing glands designed to isolate the body of the luminaire. Sealing rubber glands are inserted into grooves specially provided for this in the fittings. In a preferred embodiment, the mounting kit 4 of the endings consists of two fittings and six rubber sealing glands.

After the implementation of the three steps described above, they begin to assemble a linear LED phytosanitary fixture.

A heat-conducting paste is applied to the lower flat part of the aluminum Ω omega profile, to which the LED strip 2, made in the second stage, is attached. In a preferred embodiment, the specified LED strip 2 is attached to the aluminum housing 1 using fasteners, for example, with screws in the amount of 11 pieces. In the upper rounded part of the aluminum Ω omega profile 1, along the LED strip 2, a channel for forced water cooling 3 is placed. Then, the ends 4 made in the third stage, made in the form of a fitting with rubber sealing glands, are pressed into the ends of the channel for forced water cooling 3 s two sides of the assembled aluminum Ω omega profile. In the preferred embodiment, after pressing in the fittings with rubber sealing glands are additionally fixed with fasteners, for example, with 6 screws (3 pieces per fitting). The power cable soldered to the LED strip is fixed in a slot specially made in one of the fittings. The finished linear LED phyto-lamp is tested for leaks by supplying water in the channel for forced water cooling 3 under a given pressure.

Ready-made linear LED phyto-lamp operates as follows.

A linear LED phyto-lamp is placed above the surface of the site with cultivated plants, installing it at a selected height. When power is supplied to the LED strip, the LEDs begin to emit light, respectively, of the red, blue, yellow and UV spectrum of the glow, when mixed, a combined light flux with phytobiological activity is generated. Depending on the chosen surface of the site for cultivated plants (greenhouses, greenhouses, winter gardens, agricultural complexes, or home conditions), the required number of phyto-lamps is chosen. Heat is removed from the LEDs in a linear LED phyto-lamp by means of a channel for forced water cooling 3 controlled either manually or using automation, depending on the total heat generation and the selected size of the room in which they work.

Claims (2)

1. A method of manufacturing a linear LED phytosanitary fixture, comprising the following steps: manufacturing an aluminum case with the possibility of placing a channel for forced water cooling and attaching an LED strip to it, characterized in that the aluminum case is made by extrusion in the form of an Ω omega profile, with a flat bottom part and upper rounded part; manufacturing of LED strip by soldering to the rail of LEDs of various emission spectrum and power cable; installation on each LED using a lens holder that creates a light beam with a 60 ° angle; installation in the lower flat part of the profile, after applying heat-conducting paste, the specified LED strip and fixing it with fasteners, and in the upper rounded part of the profile, along the LED strip, the placement of the channel for forced water cooling; fixing the ends on the side ends of the aluminum case made in the form of a fitting for supplying cooling water with rubber sealing glands to insulate the phyto-lamp housing, and the fitting with sealing rubber glands inserted into the grooves is fixed at the ends of the channel for forced water cooling by pressing them. 2. A method of manufacturing a linear LED phyto-lamp according to claim 1, characterized in that the LED strip contains LEDs of the red spectrum, blue spectrum, yellow spectrum and UV spectrum.

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