RU2075288C1 - Greenhouse - Google Patents

Abstract

FIELD: growing of plants in protected ground constructions, in particular, selection greenhouses with hydroponic plant growing system. SUBSTANCE: greenhouse has transparent heat-shielding outer fencing 1, plant growing system with vegetative pots and environment control system. Outer fencing 1 is made spherical. Greenhouse is divided by transparent spherical concentrically mounted wall 5 into two climate chambers. Vegetative pots are formed as annular trays 9,10 arranged in tiers on inner surfaces of fencing 1 and wall 5 in horizontal position. Wall 5 used in the construction allows light energy to be efficiently used and planting area to be increased. EFFECT: increased efficiency, simplified construction, increased yield and enhanced reliability in operation. 3 cl, 1 dwg

Description

 The invention relates to agriculture, in particular, to greenhouses with hydroponic plants for growing vegetables, mainly for breeding purposes in the production of new varieties of agricultural products.

 Known greenhouse containing a translucent outer fence, a system of growing plants, including vegetation vessels installed with the ability to move and a control system of microclimate parameters, including blocks supplying nutrient solution and irradiation (AS USSR N 1519595, class A 01 G 31/06 1988).

 A disadvantage of the well-known greenhouse is that it does not provide for the efficient use of light, shelving requires significant production space, extensive engineering communications.

 The task was to increase the efficiency of light use, save the space of the greenhouse and reduce the length of utilities.

 This problem was solved by the present invention. In a greenhouse containing a translucent heat-proof outer enclosure, a plant growing system including moving vessels installed with the possibility of movement, and a microclimate control system including nutrient solution and plant irradiation supply units according to the invention, the translucent heat-insulating external enclosure is made spherical, and the greenhouse by spherical translucent placed concentrically relative to the mentioned fence and secured to it per The city is divided into internal and external climate chambers, while the vegetation vessels located in tiers on the inner surfaces of the said chambers are made in the form of horizontal circular trays, and technological marches are fixed on the outer surface of the spherical partition.

 In a preferred embodiment of the greenhouse, horizontal circular trays are mounted for rotational movement in the plane of its location.

 Preferably, the optical radiation sources of the plant radiation unit are located in an internal climate chamber.

 The implementation of a spherical translucent heat-shielding external fence makes it possible to efficiently use the solar light flux to irradiate plants in the greenhouse, and in conjunction with a semitransparent septum concentrically attached to it, dividing the greenhouse into the inner and outer chambers, it allows creating the necessary radiation and thermal regimes for year-round cultivation in a closed volume plants. When using an artificial light source, this process is also feasible at night, and in the daytime and cloudy weather, plant lighting improves.

 The presence of two climate chambers in the greenhouse will significantly increase productivity due to the internal sphere by increasing the area under the vegetation vessels, reduce the consumption of electric and thermal energy and building materials for its manufacture, as well as create an autonomous microclimate in each climatic zone necessary for the crop being grown.

 The implementation of vegetation vessels in the form of horizontal circular trays installed in tiers on the inner surface of the external fence and a spherical partition with the possibility of rotation allows them to be used effectively for growing plants, reduce the production area of the greenhouse, and reduce engineering communications.

 A specific example of a greenhouse is shown in the drawing, where its general view is shown.

 The greenhouse contains a translucent heat-shielding fence 1 made of a spherical shape and mounted on supports 2 above the engineering support building 3 of the greenhouse. Inside the fence 1 is placed concentrically relative to it and mounted on the frame 4, a spherical translucent partition 5, which divides the greenhouse into internal and external climatic chambers, allowing them to create autonomous temperature and humidity conditions. A frame 6 is installed on the outer surface of the partition 5. On the inner surfaces of the outer fence 1 and the spherical partition 5, horizontal circular trays 9 and 10 are installed in tiers for brackets 7 and 8, for hydroponic growing of plants, with the possibility of rotational movement in the plane of their movement.

 In several places near the trays, technological marches are attached to the frame 6 for caring for plants and servicing the trays 9, containing scaffolds 11, platforms and stairs 12.

 Trays 10 with plants, located on the inner surface of the internal climate chamber, are located at arm's length, and service areas are not required.

 Inside the translucent sphere 5 on the brackets installed optical radiation sources 13.

 In the engineering support block 3 there is a climate control system with units for supplying nutrient solution and plant irradiation, a heating and ventilation system, and a switchboard. The entrance of the staff is through a cylindrical shaft 14 on the stairs 15.

 The greenhouse works as follows. Pots with plants with the same temperature and humidity conditions, for example, seedlings of cucumbers, are installed in the trays of the indoor climate chamber, and pots with plants that require a different temperature and humidity conditions, for example, tomatoes, are installed in the trays of the outdoor climate chamber 7. Natural light through translucent the outer fence 1 and the inner translucent partition 5 irradiate plants in the daytime. On cloudy days and the night period, additional illumination by artificial sources of optical radiation is included 13. Plants are maintained and maintained from the scaffolds 11 of the technological marches, by rotating trays 9 to the scaffolds.

 The use of a room-sized greenhouse can be used for breeding purposes and will increase the efficiency of light use, reduce the length of utilities, increase the planting area of the greenhouse and its productivity.

Claims (3)

 1. A greenhouse containing a translucent heat-shielding external fence, a system for growing plants, including vegetative vessels installed with the possibility of movement, and a climate control system including micro-climate supply units and irradiating plants, characterized in that the translucent heat-shielding external fence is made spherical, and the greenhouse by means of a spherical translucent placed concentrically relative to the mentioned fence and mounted on it the horns are divided into internal and external climate chambers, while the vegetation vessels are arranged in tiers on the inner surfaces of the chambers and are made in the form of horizontal circular trays, and technological marches are fixed on the outer surface of the spherical partition.  2. The greenhouse according to claim 1, characterized in that the horizontal circular trays are installed with the possibility of rotational movement in the plane of their location.  3. A greenhouse according to claim 1, characterized in that the optical radiation sources of the plant irradiation unit are located in an internal climate chamber.