RU186764U1 - PHYTOR LED MODULE - Google Patents

Abstract

The utility model relates to the field of agriculture - crop production, and in particular to artificial lighting systems with a certain spectrum of emitted light (phyto-lamps) and is aimed at stimulating plant growth and increasing the yield of garden crops and flowering plants.

The task to which the claimed technical solution is directed is to create an easy-to-manufacture and highly efficient phyto-LED module. The technical result achieved by solving the task is to increase the reliability of the phyto-LED module.

The phyto-LED module contains a group of LEDs for plants with a radiation range from 400 to 700 nm, a power supply, a varistor and a resettable fuse. The power supply unit includes: a diode bridge, a capacitor, a current stabilizer chip, a current-setting resistor. The phyto-LED module is made in the form of a printed circuit board with an aluminum base, on which LEDs, a varistor, a self-healing fuse and all elements of the power supply are installed by the method of automatic surface mounting. Preferably, the power supply has a circuit diagram shown in figure 1. It is also preferable that the stabilizer chip type CYT1000B manufactured by CYT (China) be used as a stabilizer chip. In some cases, as a stabilizer chip, a stabilizer chip of the type NSI50150ADT4G manufactured by ON Semiconductor (USA) can be used. It is preferable that phyto-LEDs of the FM-P3528WBRS-BS type with a rated operating current of 60-75mA manufactured by NationStar (China) are used as LEDs. 4 s.p. f-ly, 5 Fig.

Description

The utility model relates to the field of agriculture - crop production, and in particular to lighting devices for greenhouses and greenhouses, in particular to artificial lighting systems with a certain spectrum of emitted light (phytoluminaires).

The utility model is aimed at stimulating plant growth, increasing the yield of horticultural crops, flowering plants and can be used to grow various plant products in home or industrial conditions, where it is necessary to illuminate plants with a lack of natural light.

For growing plants under artificial lighting, mainly electric light sources are used, designed specifically to stimulate plant growth by emitting electromagnetic waves that are favorable for photosynthesis.

Science has long known that of the entire spectrum of light waves possessed by sunlight, the most important for plants are light waves with a wavelength of 400-500 nm (blue light) and 600-700 nm (red light). Blue light contributes to the process of photosynthesis in a plant and is responsible for leaf development and plant growth. Red light also promotes photosynthesis and is responsible for the development of the root system, fruit ripening and flowering plants (https://ru.wikipedia.org/).

Currently, in accordance with industry procedures, the spectral composition of the radiation characterized by the ratio of the radiation intensity of the three spectral bands k _i,%: blue k _syn (400 ... 500 nm), green k _zel (500 ... 600 nm) and red k _cr (600 ... 700 nm). (Prikupets, L.B. Optimization of the emission spectrum when growing vegetables under conditions of intense light culture / LB Prikupets, A.A. Tikhomirov // Lighting Engineering. - 1992. - No. 3. - P.5-7).

A known method and device of light-pulse lighting of plants, which uses laser irradiators with a wavelength of 500-530 nm. (RF patent No. 2171028 for the invention "A method for processing cuttings of roses", IPC A01G 9/26, published on July 27, 2001). A disadvantage of the known light-pulse lighting is that it has limited use, in particular, exclusively for growing a certain type of roses. In addition, the implementation of the known method requires special, complex and expensive equipment.

A device for light-pulse lighting of plants is known, in which pulses of light flux are formed in the form of electric discharges using spark gaps (RF patent No. 2262834 for the invention "Method of light-pulse treatment of plants" IPC A01G 7/04, published on October 27, 2005). The known device contains a surface with plants, a power source, a voltage converter, a control unit, a housing with light sources and a light pulse shaper. A disadvantage of the known device is the fact that its implementation requires a special arrester. To obtain light pulses, high voltage pulses must be applied to the arrester, which is unsafe. The action of the arrester is accompanied by a high level of noise. And, in addition, the life of such light devices is small and limited by a certain number of flashes.

A known lighting installation for illuminating crops in a greenhouse, comprising a number of light sources, such as lamps located above the crops to be illuminated, and a number of light intensity control devices for light sources, wherein the light intensity control devices are provided with control means for periodic, automatic changes in light intensity of light sources interacting with devices for adjusting light intensity according to a predefined Birmingham. Lighting sources are divided into a number of groups, while the lighting installation is made in such a way that, when used, the power of each group changes according to a predetermined scheme, while the schemes of different groups are phase-shifted relative to each other so that the electricity consumed by the joint groups , changes less than the sum of the changes in the power level of individual groups (US patent No. 8350490 for the invention of "Crop Lighting", IPC A01G9 / 14; H05B37 / 02, publ. 2010-02-11). The known device is characterized by complexity of execution and high energy intensity.

With the development of science and the advent of new technologies, LEDs began to be used in lighting. LED or light-emitting diode (LED, LED, Light-emitting diode) is a semiconductor device with an electron-hole transition, which creates optical radiation when an electric current is passed through it (http://en.wikipedia.org/wiki/LED) . LED lighting devices are widespread due to their inherent advantages - high light output, low power consumption, long life, high security, compactness and low weight, resistance to mechanical stress, light purity, directivity of radiation, etc.

 Known phyto-lamp, in which blue and red LEDs are used as a radiation source. The device also includes a heat dissipation radiator and switches for controlling the red and blue LEDs to provide controlled exposure to various light sources (application No. US2007058368 (USA) for the invention “Efficient high brightness led system that generates radiometric light energy capable of controlling growth of plants from seed to full maturity ”, IPC F21V 9/00, published March 15, 2007). The known device is characterized by complexity of execution.

A device for lighting plants is known, comprising a housing, an LED module with a group of LEDs with a different emission spectrum, a voltage converter, a control unit, pulse shapers, a pulse parameter regulator, which includes frequency, amplitude and duration adjusters, and the pulse parameter regulator is common for all groups of LEDs, and the pulse shaper is made in the form of a switch installed in the power supply circuit of the LEDs between the common negative output ohm and control unit (RF Patent No. 2326525 for the invention "Light-pulse illuminator (options) and method of light-pulse illumination of plants", IPC A01G 9/26, publ. 06/20/2008]. The disadvantage of this device is the design complexity.

Known for the closest set of essential features to the claimed utility model selected as a prototype phyto-LED module containing a group of LEDs with a radiation spectrum in the range from 400 to 700 nm, and a power supply, which includes: voltage converter, control unit, pulse shapers , pulse parameter regulators, productivity sensor of irradiated plants, calculator. The composition of the pulse parameter controllers includes adjusters of periodicity, amplitude and duration. The pulse shapers and pulse parameter controllers, which additionally contain phase angle adjusters, are included in each group of LEDs, the output of the irradiated plant productivity sensor is connected to the input of the computer, the output of the computer is connected to the inputs of the pulse parameter controllers, the outputs of which are connected to pulse shapers through the control unit (RF patent No. 2554982 for the invention "Method of energy-saving pulsed irradiation of plants and a device for its implementation", IPC A01G 7/04, A01G 9/2 6, publ. 07/10/2015). A disadvantage of the known phyto-LED module is the design complexity and insufficiently high reliability.

The task to which the claimed technical solution is directed is to create an easy-to-manufacture and highly efficient phyto-LED module.

The technical result achieved by solving the task is to increase the reliability of the phyto-LED module.

The specified technical result is achieved in that the phyto-LED module contains a group of LEDs for plants with a radiation range from 400 to 700 nm, a power supply, a varistor and a self-healing fuse. The power supply unit includes: a diode bridge, a capacitor, a current stabilizer chip, a current-setting resistor. The phyto-LED module is made in the form of a printed circuit board with an aluminum base, on which LEDs, a varistor, a self-healing fuse and all elements of the power supply are installed by the method of surface mounting.

Preferably, the power supply has a circuit diagram shown in figure 1.

It is also preferable that the stabilizer chip type CYT1000B manufactured by CYT (China) be used as a stabilizer chip.

In some cases, as a stabilizer chip, a stabilizer chip of the type NSI50150ADT4G manufactured by ON Semiconductor (USA) can be used.

It is preferable that phyto-LEDs of the FM-P3528WBRS-BS type with a rated operating current of 60-75mA manufactured by NationStar (China) are used as LEDs.

A comparative analysis of the claimed utility model with the prototype showed that in all cases of execution, it differs from the well-known, closest technical solution:

- the implementation of a phyto-LED module containing a varistor and a resettable fuse;

- the implementation of the power supply unit containing a diode bridge, a capacitor, a current stabilizer chip, a current-setting resistor;

- the implementation of the phyto-LED module in the form of a printed circuit board with an aluminum base, on which LEDs, a varistor, a self-healing fuse and all elements of the power supply are installed by the method of automatic surface mounting.

In some cases, the performance of the utility model differs from the well-known, closest technical solution:

- the implementation of the power supply having the circuit diagram shown in figure 1;

- using as a microcircuit a stabilizer microcircuit type CYT1000B manufactured by CYT (China);

- using as a stabilizer microcircuit type NSI50150ADT4G manufactured by Semiconductor (USA);

- the use of phyto-LEDs of the type FM-P3528WBRS-BS with a rated operating current of 60-75mA manufactured by NationStar (China) as LEDs.

The presence of a self-resetting fuse and varistor, as well as the implementation of a power supply unit containing a diode bridge, capacitor, stabilizer, current-setting resistor, protect the lamp from short circuits in the circuit and input overvoltage pulses. The implementation of the phyto-LED module in the form of a printed circuit board with an aluminum base, on which LEDs, a self-healing fuse, a varistor and all elements of the power supply are installed by the method of surface mounting, allows efficient heat removal from the elements installed on it. All this increases the reliability of the module.

The use of direct current regulators of the type CYT1000B (manufacturer CYT, China) or NSI50150ADT4G (manufacturer ON ON Semiconductor, USA) as stabilizers for microcircuits allows stabilizing the current in a wide voltage range: 30-70 mA (CYT1000B) or 150-350 mA (NSI50150ADT4G ) To protect the LEDs and the entire device from overheating, stabilizers have a negative temperature coefficient - with increasing temperature, the stabilization current decreases. This provides effective protection of LEDs from extreme operating conditions. These stabilizers have identical cases, which does not require changing the topology of the board when installing them.

The proposed utility model is illustrated by the graphic materials presented in figures 1-5.

In FIG. 1. presents a circuit diagram of a phyto-LED module

In FIG. 2 is a photograph of the phyto-LED module assembly.

In FIG. 3 is a photograph of a plant lighting device based on a phyto-LED module.

In FIG. 4 is a graph of the emission spectrum used in the FM-P3525-WBRS-BS LED module.

In FIG. Figure 5 shows a graph of the dependence of the stabilized output current on the resistance of the regulating resistor of the stabilizer CYT1000B in the output voltage range up to 250V.

In a preferred embodiment, the phyto-LED module contains a group of LEDs (1) (with a radiation spectrum in the range from 400 to 700 nm) and a power supply (2). The power supply unit (2) includes a diode bridge (3), a capacitor (4), a stabilizer (5), a current-setting resistor (6). The phyto-LED module also contains a varistor (7) and a resettable fuse (8). The phyto-LED module is made in the form of a printed circuit board (9) with an aluminum base, on which LEDs (1), a varistor (7), a self-healing fuse (8) and all the elements of the power supply unit (2) are installed by automatic surface mounting. The power supply has a circuit diagram shown in figure 1. The stabilizer microcircuit (5) can be used: an adjustable direct current stabilizer microchip type CYT1000B manufactured by CYT (China), or a linear stabilizer microcircuit type NSI50150ADT4G manufactured by ON Semiconductor (USA). As the LEDs, phyto-LEDs FM-P3528WBRS-BS with a rated operating current of 60-75mA manufactured by NationStar (China) can be used. The base of the circuit board (9) is made of aluminum.

The utility model works as follows.

Light sources — light emitting diodes (1) (so-called “full-spectrum” plant LEDs with a radiation range from 400 to 700 nm (with a pronounced maximum of radiation at 440 and 660 nm), a self-healing fuse are placed on one printed circuit board (9) by automatic surface mounting (8), varistor (7), diode bridge (3), capacitor (4), stabilizer (5), current-sensing resistor (6). The aluminum base of the printed circuit board (9) allows you to effectively remove heat from the elements installed on it. phyto LED of the module is achieved by changing the value of the current-carrying resistor (6) and / or the stabilizer microcircuit (5). Changing the characteristics of the entire phyto-lamp is achieved by changing the number of phyto-LED modules. The proposed phyto-LED module can be used with or without secondary optics. components, structural reliability, ease of assembly, flexibility of the product range provide ample opportunities to use the proposed utility model for art lighting of cultivated plants.

Claims (5)

1. Phyto-LED module containing a group of LEDs with a radiation spectrum in the range from 400 to 700 nm and a power supply, characterized in that it contains a varistor and a resettable fuse; the power supply unit includes: a diode bridge, a current stabilizer microcircuit, a current-setting resistor and a capacitor, and the phyto-LED module is made in the form of a printed circuit board with an aluminum base, on which LEDs, a varistor, a self-healing fuse, and all elements of the power supply unit are installed. 2. Phyto-LED module according to claim 1, characterized in that the power supply has a circuit diagram shown in figure 1. 3. The phyto-LED module according to claim 1, characterized in that a chip of the type CYT1000B manufactured by CYT (China) is used as a current stabilizer chip. 4. The phyto-LED module according to claim 1, characterized in that a microcircuit of the type NSI50150ADT4G manufactured by ON Semiconductor (USA) is used as a current stabilizer chip. 5. The phyto-LED module according to claim 1, characterized in that the phyto-LEDs FM-P3528WBRS-BS with a rated operating current of 60-75mA manufactured by NationStar (China) are used as LEDs.

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