RU2034447C1 - Device for irradiating plants in greenhouse having multi-stage rack hydroponic apparatus - Google Patents

Abstract

FIELD: agriculture, particularly, plant growing. SUBSTANCE: this device for irradiating plants growing in greenhouse provided with multi-stage rack hydroponic apparatus includes sources of radiation, and reflector radiation source rotary drive. Reflector is horizontal pipe 1 securely mounted on rack 1. Sources of radiation are arranged in cassette composed of three luminescent lamps 9, 10 and 11 isolated from one another by blades of optical multi-bladed reflector screen 8. Cassette axle is connected to rotary drive. EFFECT: energy saving and higher productivity. 5 cl, 3 dwg

Description

 The invention relates to agriculture, to the plant growing of protected soil.

 A known greenhouse containing racks mounted on top of one another for placement of germinated plants and covering them with a translucent coating.

 The disadvantage of this greenhouse is its low efficiency, low productivity.

 It is known the production of vegetables in residential premises in pots, drawers, vessels, racks and other structures installed on the windowsills of apartments and illuminated by natural light through a window and / or fluorescent and other lamps using reflective screens.

 The disadvantage of these known designs are their low efficiency, low productivity and high energy consumption due to the irrational use of light.

 The closest technical solution adopted for the prototype is the installation of irradiation of plants of the UORT type in a greenhouse, containing fixtures, one of which is suspended between adjacent multi-tier narrow-rack installations, and the other is placed inside a hydroponic installation.

 A disadvantage of the known plant irradiation plant is a significant loss of light and energy consumption and, therefore, a high specific power of the plant.

 The creation of a device for plant irradiation, which allows to reduce light losses, reduce energy costs in the greenhouse, and also to best meet the light-physiological requirements of cultivated crops, is an urgent task.

 The invention solved the problem of creating a device for irradiating plants, which allows to increase the productivity of the greenhouse by creating the best light-physiological conditions for growing plants.

 A device for irradiating plants in a greenhouse with a multi-tiered shelf hydroponic installation, containing radiation sources and a reflector, is equipped with a rotation source of radiation sources, and the reflector is made in the form of a horizontal pipe mounted on the rack, while the radiation sources are arranged in a cassette with an additional optical multi-blade in the center a reflecting screen, the blades of which isolate radiation sources from each other, and the axis of the cartridge is located in the center of the reflector and is connected with the rotation drive.

 In a preferred embodiment, in the cartridge, the number of blades of the optical reflective screen is equal to the number of independent radiation sources.

 The cassette preferably has an optical three-blade reflective screen, each blade of which is made in the form of a plate parallel to the radiation source, and fluorescent lamps are used as radiation sources.

 Preferably, the maximum part of the optical energy flux of the 1st, 2nd and 3rd fluorescent lamps of the cartridge is located in the regions of 400-500, 500-600, 600-700 mn for cucumber or tomato crops, respectively.

 In addition, preferably the reflector is made of a metallized heat-resistant film.

 The invention allows to achieve the following technical result.

 The implementation of the reflector in the form of a horizontal pipe, which is mounted on the rack and has a reflecting inner surface, which is a light guide, can significantly increase the efficiency of plant irradiation due to volumetric irradiation created by direct and reflected rays, which, in turn, can drastically reduce energy costs.

 Providing the device with a rotation drive of the cassette of radiation sources allows you to create a dynamic light environment in space and in time more intense, which favorably affects the productivity of the plant.

 The implementation of the radiation sources independent and arranged in a cassette, having in the center an additional optical multi-blade reflective screen, allows to maximize the efficiency of each radiation source, which, in turn, satisfies the light-physiological requirements of the grown plants.

 Providing a cassette of radiation sources with a rotation drive allows you to create uniform irradiation of plants with the same radiation in space and time.

 The inventive device for irradiating plants in a greenhouse differs from the known one adopted for the prototype in that it is equipped with a drive for rotating radiation sources, the reflector is made in the form of a horizontal pipe mounted on a rack, and the radiation sources are independent and arranged in a cassette with an additional center optically multi-blade reflective screen, the blades of which isolate the sources from each other, while the axis of the cartridge is located in the center of the reflector and is connected with the rotation drive.

 In FIG. 1 shows the proposed device, a General view; figure 2 is a cross section of a device with a folded upper part of the reflector; figure 3 the same, with the closed upper part of the reflector.

 A device for irradiating plants in a greenhouse with a multi-tiered rack hydroponic installation contains a reflector made in the form of a horizontal pipe 1, which is fixed from the ends to the posts 2, and in the lower part to the rack 3. Racks 2 are rigidly fastened to the caps 4 of the ends of the racks 3.

 The rack 3 is made in the form of a tray with a lid 5, in the openings of which are placed germinators (pots) 6 with plants 7.

 In the reflector 1 in its lower part there are holes for the passage of plants during growth, coaxial with the holes of the lid of the tray.

 Independent radiation sources are arranged in a cassette, in the center of which there is an additional optical multi-blade reflecting screen 8. The number of screen blades 8 is equal to the number of radiation sources. For example, in a cassette three radiation sources are arranged in the form of fluorescent lamps 9 11, which are isolated from each other, respectively, by three blades of a reflective screen 8.

 At the end of the reflector 1 there is a drive in the form of an engine, the output shaft of which is connected to the axis of the cartridge, which is the axis 12 of the reflecting screen 8 and located in the center of the reflector 1.

 The maximum part of the optical energy flux of fluorescent lamps is located in the ranges, respectively: lamp 9 400-500 mn; lamp 10 500-600 mn; lamp 11 600-700 mn for the most common crops of cucumbers and tomato.

 The inner surface of the reflector 1 is covered with a layer of metallized heat-resistant film, for example a polyethylene terephthalic film.

 The upper part 13 of the reflector 1 is made reclining, for example, connected to the lower part by a hinge 14.

 The device operates as follows.

 The upper part 13 of the reflector 1 is thrown back and plants 7 are planted in the pots (pots) 6, and a nutrient solution corresponding to the plant being grown is fed into the tray 3.

 At a given point in time, the rotation of the cassette begins from radiation sources 9 11 separated by a reflecting screen 8, as a result of which uniform irradiation of the plant with the same radiation in space and time is created in the reflector 1, which creates the necessary light-physiological regime.

 Since the inner surface of the reflector 1 is made reflective, the plants are also irradiated by rays reflected from its surface, i.e. Irradiation occurs simultaneously and the upper and lower parts of the sheet plates with both direct and reflected rays.

 Thus, the claimed device allows for uniform homogeneous irradiation of both the upper and lower parts of the leaf plates with direct and reflected rays, which ensures the best light-physiological regime, and, therefore, increases the productivity of the plant.

 At the same time, the proximity of the cassette of radiation sources 9-11 to plants and their placement in the enclosed space of the tubular reflector 1 reduces the flow of light energy and reduces the installation power of the device.

Claims (5)

 1. A device for irradiating plants in a greenhouse with a multi-tiered rack hydroponic installation, comprising a main reflector and a cassette of radiation sources, characterized in that the cassette of radiation sources is located in the cavity of the main reflector and is equipped with a drive for its rotation and an optical multi-blade reflective screen, the blades of which are connected on one side with the axis of rotation of the cartridge associated with the drive of rotation of the latter and placed coaxially with the main reflector, which is made in the form of a horizontal qi a cylindrical reflector for mounting on the rack of a hydroponic installation, the radiation sources being parallel to the axis of rotation of the cartridge in the spaces between adjacent vanes of the optical multi-blade reflective screen and with a gap relative to the latter and the axis of rotation of the cartridge, the cartridge of radiation sources being placed along the entire length of the reflector for fixing on the rack hydroponic installation.  2. The device according to claim 1, characterized in that the number of blades of the optical multi-blade reflective screen is equal to the number of radiation sources in the cassette.  3. The device according to claim 2, characterized in that the fluorescent lamps are used as radiation sources, and the blades of the optical multi-blade reflective screen are made in the form of plates placed in parallel with the respective radiation sources.  4. The device according to claim 3, characterized in that for the crops of cucumber and tomato as the first, second and third sources of radiation of the cartridge used radiation sources with the location of the maximum part of the optical energy flux, respectively, in the ranges of 400 500, 500 600 and 600 700 nm.  5. The device according to claim 1, characterized in that the main reflector is made of metallized heat-resistant film material.

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