RU158956U1 - LED PHYTOR LIGHT ON A SUNNY BATTERY - Google Patents

Abstract

1. LED phyto-lamp on a solar battery, consisting of a housing, on the upper surface of which a solar battery is placed, and on the lower surface there is a reflector in which LED elements of the blue and red radiation spectrum with wavelengths of 400-500 nm and 600-700 nm are placed, respectively which, in turn, are connected through an electric circuit through a switch to a storage battery and a solar battery, while the connection of the solar battery to the storage battery is made through a diode, and the sleep housing itself It is equipped with a holder, characterized in that the holder is made in the form of a vertical rod, the lower end of which is adapted for sticking into the ground, and its upper end is made hollow, where along the vertical axis there is a battery inside it. 2. A solar-powered LED phyto-lamp according to claim 1, characterized in that a voltage converter is included in the electrical circuit of the device, which allows to increase the voltage when transferring it from the battery to the LED elements. 3. Solar LED phyto-lamp according to paragraphs. 1 and 2, characterized in that a switch or microcontroller is included in the electrical circuit of the device, which allows you to turn on the LED elements of the blue and red emission spectrum both individually and together.

Description

The utility model relates to lighting devices, namely to luminaires with a certain spectrum of emitted light, used to illuminate plants that lack sunlight, to so-called phyto-lamps.

For plants growing in indoor conditions and lacking in sunlight (especially in the winter), phyto-lamps were invented and have long been used. 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.

There are phyto-luminaires that use gas discharge lamps containing mercury, sodium and xenon vapors to provide plants with blue and / or red light. An example is the Philips GreenPower discharge lamp. The following disadvantages are inherent in such lamps: large dimensions, high energy consumption, the need for special disposal. Such lamps are mainly used for growing a large volume of plant products for commercial purposes.

With the development of science and the advent of new technologies, LEDs have recently been used in lighting. Thus, phyto-luminaires began to appear on LEDs in which blue and red LEDs were used as a radiation source (for example, patent US 20070058368, IPC F21V 9/00, 2007 publication)

Such luminaires are lighter, safer, have a longer life and consume less energy, but they are more expensive, because they require a voltage converter and cooling system to work so that the LEDs do not overheat. Therefore, such lamps are used on a smaller scale and often for indoor plants.

Another device (prototype) is known, consisting of a housing, on the top of which a solar battery is placed, which converts daylight into electricity, and on its lower part there is a reflector, where blue and red LEDs are also installed. The device is also equipped with a rechargeable battery for storing electricity received from the solar battery. The housing itself is connected to a bendable holder, at the other end of which there is a spring clip. In addition, there is a speaker in the device case with which you can play music for the plant, since it is believed (but not completely proven by science) that plants can hear and certain music can contribute to the well-being of the plant (patent KR 1020110086232, IPC A01G 7/00 2011 publication).

The advantage of this device is that it does not require external power and has a renewable energy source (solar battery). At the same time, sunlight is not necessary for the generation of electric current to solar batteries, it is enough natural daylight or artificial light. The device can be compact and this solution is justified for small single indoor plants, when buying a large lamp is unreasonably expensive, there is no place where to place it, and when the task is to illuminate the indoor plant a bit on cloudy days, rather than lighting it constantly. Nevertheless, the design of the device has an unsuccessful solution, since most of the parts, including the speaker and heavy battery, are located in one case and the bulk of the device is concentrated in it. The heavy case of the device must be placed above the flower during operation, and the bending holder and spring clip are responsible for its positioning, which in this case have increased requirements for quality and reliability. In addition, the spring clip cannot be effectively used on all protrusions (in particular, we are talking about flower pots) and this limits the use of the device. In addition, the function of the device to play music makes it more expensive to manufacture, heavier, while music is not an important factor for the growth and flowering of plants.

The technical result of the proposed utility model is a more stable design for the operation of the device.

The technical result is achieved in that the LED phyto-lamp on a solar battery has a holder made in the form of a vertical rod, the lower end of which is adapted for sticking into the ground, and its upper end is made hollow, where along the vertical axis there is a battery inside it, and the case is also attached to the upper end of the holder perpendicularly or at an angle to its vertical axis, on the upper side of which there is a solar battery, and on the lower surface there is a reflector in which LED elements of the blue and red emission spectrum with wavelengths of 400-500 nm and 600-700 nm, respectively, are placed, which are connected through a switch to the storage battery and the solar battery, and the solar battery is connected to the storage battery through a diode.

A voltage converter can be included in the electrical circuit of a LED phytosanitary fixture on a solar battery, which allows to increase the voltage when transferring it from the battery to the LED elements.

A switch or a microcontroller can be included in the electrical circuit of a LED phytosanitary fixture on a solar battery, which allows you to turn on the LED elements of the blue and red emission spectrum, both individually and together.

The claimed design of the LED phyto-lamp on a solar battery is shown in the drawing, where: in FIG. 1 it is shown on the side, in the working position; in FIG. 2, the device is shown above.

The LED phyto-lamp on the solar battery has a holder 1 made in the form of a vertical rod, the lower end of which is adapted for sticking into the ground, and its upper end is hollow, where along the vertical axis, the battery 2 is placed inside it, and to the upper end of the holder perpendicularly or at an angle to its vertical axis, a housing 3 is also attached, on the upper side of which a solar battery 4 is placed, and on the lower surface there is a reflector 5 in which the blue LED elements are placed 6 and red 7 emission spectra with wavelengths of 400-500 nm and 600-700 nm, respectively, which are connected through a switch (not shown) to the battery 2 and the solar battery 4, and the connection of the solar battery 4 with the battery 2 through a diode (not shown in the drawings).

A voltage converter (not shown in the drawings) can be included in the electrical circuit of the LED phyto-lamp on a solar battery, which allows to increase the voltage when transferring it from the battery 2 to the LED elements 6 and 7.

A switch or a microcontroller (not shown in the drawings) can be included in the electrical circuit of the LED phytosanitary lamp on a solar battery, which allows you to turn on the LED elements of the blue 6 and red 7 emission spectrum, both individually and together.

The claimed LED phyto-lamp on a solar battery is operated as follows. The holder 1 of the device is stuck in the ground next to the plant, which needs additional illumination. Then, the battery 2 is charged from the solar battery 4, while daylight or artificial light is sufficient to charge the battery 2 from the solar battery 4. After the accumulation of the necessary charge by the battery 2, the device turns on, the LED elements 6 and 7 installed in the reflector 5 illuminate the plant.

The claimed design of a LED phytoflash lamp on a solar battery is more stable during operation.

Claims (3)

1. LED phyto-lamp on a solar battery, consisting of a housing, on the upper surface of which a solar battery is placed, and on the lower surface there is a reflector in which LED elements of the blue and red radiation spectrum with wavelengths of 400-500 nm and 600-700 nm are placed, respectively which, in turn, are connected through an electric circuit through a switch to a storage battery and a solar battery, while the connection of the solar battery to the storage battery is made through a diode, and the sleep housing itself It is equipped with a holder, characterized in that the holder is made in the form of a vertical rod, the lower end of which is adapted for sticking into the ground, and its upper end is hollow, where, along its vertical axis, a battery is placed inside it. 2. LED phyto-lamp on a solar battery according to claim 1, characterized in that a voltage converter is included in the electrical circuit of the device, which allows to increase the voltage when transferring it from the battery to the LED elements. 3. LED phyto-lamp on a solar battery according to paragraphs. 1 and 2, characterized in that a switch or microcontroller is included in the electrical circuit of the device, which allows you to turn on the LED elements of the blue and red emission spectrum both individually and together.

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