RU2029462C1 - Device for growing plants - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: plants has vegetation modules with inclined panels. The modules have trays 2 for growing plants 4. The trays are mounted on triangular frames 1. The devise is provided with a system or irradiation. The system has a number of radiation sources 5 located under trays 2 between two adjacent modules. The sources of radiation are provided with deflectors 6. The system of irradiation is also provided with another group of radiation sources 9 located in the vegetation modules. They are provided with additional cylindrical deflectors 10 and 11 arranged in couples over and under the group of radiation sources 9. Deflectors 6 are sides of a cylinder with their convex surfaces directed toward roof 12. Deflectors 6, 10, 11 are mounted so that one of planes 14 tangent to the surface of deflector 6 passing through one of its edges is located over the upper part of frame 1 or runs cross with it. Other tangential plane 15 crosses frame 1 between its upper part and base. The planes tangent to the surface of additional deflector 9 crosses the base of frame 1. EFFECT: higher crop yielding ability owing to uniform irradiation. 4 cl, 2 dwg

Description

 The invention relates to agriculture, in particular to the field of crop production in greenhouses.

 A known plant growing plant comprising vegetation modules comprising two inclined panels consisting of plant growing trays mounted on triangular frames connected to a nutrient solution supply system, and a plant irradiation system comprising a first group of blocks of optical radiation sources placed above the trays for growing plants, between which are two adjacent modules and equipped with reflectors.

 The disadvantage of this installation is the uneven irradiation of plants during their growing, since the light flux is mainly absorbed by the green mass of plants located in the upper part of the frames, which does not provide uniform irradiation of plants and does not allow to increase yield and achieve simultaneous maturation of products of the same quality. In addition, plants located in different parts of the installation, due to filtering by upstream plants, are irradiated with a stream of a different (and therefore non-optimal) spectral composition than that emitted by light sources.

 The aim of the invention is to provide a facility that provides uniform irradiation of plants during their cultivation.

 This goal is achieved by the fact that in the plant for growing plants containing vegetation modules, including two inclined panels, consisting of trays for growing plants mounted on triangular frames connected to the nutrient solution supply system, and a plant irradiation system containing the first group of blocks of optical sources radiation placed above the trays for growing plants, in the interval between each two adjacent modules and equipped with reflectors, according to the invention, the irradiation system The plants are equipped with a second group of optical radiation sources located in the cavities of the vegetation modules, with additional cylindrical reflectors placed pairwise above and below each block of the optical radiation sources of the second group, and the reflectors of the blocks of the first group are made lateral in the form of parts of a cylindrical surface whose convex surfaces face the roof, and the planes passing through the lower edges of each reflector of the blocks of sources of the first group and tangent to its surface in x points, tangent to the cylindrical surface of the additional reflector disposed above an optical radiation sources of the second group of two adjacent modules vegetation.

 A preferred embodiment of the installation is one in which the side reflectors of each vegetation module are interconnected by two connecting elements with the possibility of the formation of one or two cavities between them.

 Each block of optical radiation sources of the first group preferably contains at least two radiation sources that are optically isolated from each other by means of side reflectors and their connecting elements, the connecting elements being made curved, convex surfaces facing the roof, and concave surfaces facing the panels of two neighboring vegetation modules.

 The invention is illustrated by drawings.

 Figure 1 shows the proposed installation for growing plants; figure 2 - reflectors located above the trays between adjacent vegetation modules.

 Installation for growing plants contains vegetation modules, which include two inclined panels, consisting of triangular frames 1, mounted on them is cut in the form of trays 2 made of metal or plastic. Trays 2 are mounted on brackets 3, rigidly mounted on triangular frames 1. Plants 4 are placed in trays 2. Trays 2 are connected to a nutrient solution system (not shown in the drawings). The vegetation module also includes a plant irradiation system, which contains the first group of blocks of optical radiation sources 5 with cylindrical side reflectors 6. The radiation sources 5 are placed above the trays 2 for growing plants 4 in the interval between each two adjacent vegetative modules. The block contains at least two radiation sources 5, optically isolated from each other by means of side reflectors 6 and their connecting elements 7, 8.

 In the cavities of the vegetation modules there is a second group of radiation sources 9, equipped with additional cylindrical reflectors 10 and 11, located in pairs above and below each block of radiation sources 9.

 As radiation sources, DM3-3000 lamps can be used. Reflectors 6, 10, 11 are made with a reflective coating, for example, an aluminized polyethylene terephthalate film. Reflectors 6 of the first group are made lateral in the form of parts of a cylindrical surface, the convex surfaces of which are facing the roof 12 of the greenhouse with gutters 13. Reflectors 6,10, 11 are installed so that the planes passing through the lower edges of each reflector 6 and tangent to its surface at these points, tangent to the surface of the additional cylindrical reflectors 10 located above the blocks of optical radiation sources 9 of the second group of two neighboring vegetation modules. In this case, the light flux emitted by the group of optical radiation sources 9 and 5 have a certain direction and are limited to the light planes 14,15,16 passing through the edges of their surfaces.

 The side reflectors 6 of each vegetation module are interconnected by means of two precipitation elements 17, 18 with the formation of one or two cavities 19, 20 between them. The connecting elements 17, 18 are made curved, their convex surfaces face the roof 12 of the greenhouse, and the concave surfaces - towards the panels of two adjacent vegetation modules. Cavities 19, 20 can be used as ducts for heating air in the cold season, where radiation sources 9 serve as a heat source, and air can be pumped into these cavities through air intakes in the roof 12 (not shown in the drawings).

 On the concave parts 21 of the reflectors 6 and the lower parts 22 of the connecting element 18, a reflective coating is applied.

 Installation for growing plants works as follows.

 Plant trays are planted in trays 2. Periodically, after a predetermined period of time, radiation sources or groups of 9 and 5 thereof are included, preferably containing three sources with a radiation spectrum: the first 400-500 nm, the second 500-600 nm, the third 600-700 nm. Reflectors 6 located above the trays 2 between adjacent vegetation modules direct the light flux generated by the light sources or their groups 5 so that the light planes 14 tangent to the upper edges of the reflectors 6 are located above the upper part of the triangular frames 1 or intersect it; the light planes 15 tangent to the lower edges of the reflectors 6 intersect the triangular frames 1 between their upper part and the base. Thus, irradiation of plants 4 located on the upper tiers of the frames is performed. Reflectors 10,11, installed in the cavities of the vegetation modules above and below the radiation sources 9 or their groups, respectively, limit the luminous flux to planes 15, 16, tangent to the edges of the reflectors 10,11. The light planes 15, tangent to the edges of the reflectors 10, intersect the triangular frames 1 between their upper part and the base, while being tangent to the lower parts of the reflectors 6, and the light planes 16, tangent to the edges of the reflectors 11, intersect the base of the frames. The concave part of the lower cavity 20 directs the reflected light flux from the radiation sources 5 to the green mass of plants 4, which exit to the outer space of the frames 1. Thus, the plants 4 located on the lower tiers of the triangular frames 1 of the vegetation modules are irradiated.

 The proposed installation for growing plants allows for uniform irradiation of plants in the process of growing them.

Claims (4)

 1. PLANT FOR GROWING PLANTS, containing vegetation modules, each of which includes two inclined panels, consisting of trays for growing plants mounted on triangular frames connected to the nutrient solution supply system, and a plant irradiation system, including the first group of blocks of optical radiation sources, placed above the trays for growing plants in the interval between each two adjacent modules and equipped with reflectors, characterized in that the plant irradiation system is equipped with a second group of a block of optical radiation sources located in cavities under the inclined panels of each vegetation module, additional cylindrical reflectors placed in pairs above and below each block of optical radiation sources of the second group, while the reflectors of the blocks of optical radiation sources of the first group are made lateral in the form of parts of a cylindrical surface , the outer sides of which are covered with a reflective layer, and the bulges are facing the roof, and the planes passing through the lower edges of each reflector of the optical radiation sources of the first group of blocks and the tangent to the surface at that point, tangent to the cylindrical surface of the additional reflector disposed above an optical radiation sources of the second group of two adjacent modules vegetation.  2. Installation according to claim 1, characterized in that the side reflectors of each vegetation module are interconnected by means of connecting elements with the possibility of the formation of one or two cavities between them.  3. The installation according to claim 1, characterized in that each block of optical radiation sources of the first group contains at least two radiation sources optically isolated from each other by means of side reflectors and their connecting elements, the latter being made curved and their convex surfaces facing side of the roof, and concave - in the direction of the panels of two adjacent vegetation modules.  4. The installation according to claim 1, characterized in that the blocks of optical radiation sources of the first and second groups contain three sources of optical radiation with the location of the maximum part of the optical energy flux, respectively, in the ranges 100 - 500, 500 - 600 and 600 - 700 nm.

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