RU2028757C1 - Greenhouse - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: greenhouse has railing, skeleton in form of triangular frames made up of paired hinge-connected posts with fitted on pans for plants, and system of pipelines for culture solution. According to invention, greenhouse has screens arranged in parallel with posts. Each screen is made of three plates arranged one under the other in parallel with each other. First and third plates are rigidly connected with posts, and second plate is installed for travel along posts being moved by drive which is connected through control unit with temperature, moisture illumination intensity pickups. Holes in all three plates are arranged coaxially. EFFECT: provision of automatic temperature regulation is greenhouse near plants. 3 cl, 7 dwg

Description

 The invention relates to agriculture, specifically to greenhouses for growing plants.

 Known greenhouse containing a fence, a frame in the form of triangular frames made of pairwise articulated racks with trays for plants attached to them, a piping system for supplying and draining nutrient solutions.

 However, in such a greenhouse without complex additional devices, it is impossible to automatically control the temperature near the plants. Existing temperature control devices in the greenhouse do not exclude local overheating and overcooling of plants in separate trays.

 The objective of the invention is to provide automatic temperature control in a greenhouse near plants, which leads to increased plant yields.

 This is achieved by the fact that the greenhouse containing the fence, a frame in the form of triangular frames made of pairwise articulated racks with plant trays attached to them, the piping system for supplying and draining the nutrient solution, according to the invention is equipped with screens arranged parallel to the racks, each of which made in the form of three plates parallel to each other, and the first and third plates are rigidly connected to the racks, and the second is installed with the ability to move it along the racks after by means of a drive, which is connected via a control unit to sensors of temperature and / or humidity and / or illumination, while the holes in all three plates are aligned.

 The preferred embodiment of the greenhouse is that it is equipped with rollers fixed to the ends of the second plates and springs, each of which is attached at one end to a rack or guard, and the other at the end of the second plate, opposite the end connected to the drive.

 In FIG. 1-7 show a greenhouse in various positions.

 The greenhouse contains a roofing fence 1 with gutters 2 located under the fence with louvered screens 3, a frame in the form of triangular frames made of pairwise articulated racks 4 with holders 6 mounted on their hinges 5, on which trays 7 are mounted, for example, for mushrooms " oyster mushroom. " Trays 8 for growing plants are installed on the racks 4, between the racks 4 there are air ducts 9 made of perforated plastic film fixed to the ropes 10 and 11. Light sources 12 are installed above the trays 8 between the frames.

 At the ends of the holders 6 there are rollers 13, which allow the holders to move along the guides (not shown), under the frames there are air channels 14 and channels 15, in which conveyors 16 for growing mushrooms are placed.

 The piping system for supplying and draining the nutrient solution includes flexible radial feed pipes 17 with holes of a given diameter. Using the pipes 17, the entrances of the trays 7, 8 are connected to the collectors 18 located in the upper parts of the frames and connected to the pipeline 19 and the feed tank 20 through a pump 21 equipped with an electric motor 22. The feed tank 20 is connected via a hose 23 through a pump 24, which is driven driven by an electric drive 25, connected to a tank 26 for preparing a nutrient solution. Capacity 26 with the help of hoses 27 and metering pumps 28 (each for its own type of fertilizer) is connected with tanks 29, intended for mother liquor of fertilizers. Dosing pumps 28 are connected to electric drives 30, which are electrically connected with mineral fertilizer concentration controllers 31, a concentrator 32 and a nutrient solution temperature sensor 33 located in a container 26, air temperature and humidity sensors 34, solar radiation level or artificial radiation sources 35, concentration carbon dioxide 36, located in the greenhouse, and the master 37 phase of the development of plants, placed on the control panel of the operator. Hoses 38 are designed to discharge the nutrient solution from the outlet openings of the trays into the main tray 39, associated with the tank 20.

 The greenhouse contains 4 screens parallel to the racks, each of which is made in the form of three plates 40-42 parallel to one another. The first 40 and third 42 plates are rigidly connected to the uprights 4, and the second plate 41 is installed with the possibility of moving it along the uprights 4 by means of a drive 43.

 In FIG. 2 shows the location of the holders 6, mounted on hinges 5. The rollers 13 provide the ability to move the holders 6 along the rails 44, on which the latches 45 can be located, which ensure the fixation of the holders 6. The trays 8 are mounted on the brackets 46. The second parts 41 of the screens are rigidly connected to the brackets 47, which, in turn, are connected to a flexible cable 48 connected through a cabinet 49 to the actuator 43. Position 50 denotes rollers that allow the plates 41 of the screens to be moved along the guides.

 In FIG. Figure 3 shows the design of the screens and their relationship with the sensors. Each of the three plates 40-42 of each of the screens contains holes 51. The holes of the first 40 and third 42 plates of each screen are aligned, and the holes of the second plate 41 overlap with the holes of the first and third plates when the second plate can be moved on the rollers 50 along guides 52. The actuator 43 is connected through a block to sensors 53 of temperature, humidity 54, and light 55.

 In FIG. 4 shows the design of the duct 9. At 56, perforations are indicated.

 In FIG. Figure 5 shows the fastening of the trays 7 in the greenhouse using the holders 57, rigidly mounted on the racks 4. The arrow shows the direction of movement of the air entering the duct.

 In FIG. 6 shows an embodiment of the duct 9 in the form of a rigid structure in the form of a parallelepiped with perforations. Grooves 58 are made on the air duct, which serve as guides, which make it possible to move the holders 6.

 In FIG. 7 shows the location of the second parts 41 of the screens in the frame of the greenhouse (top view). Reference numeral 59 denotes springs fixed at one end to the uprights 4 or guard 1, the other ends thereof being connected to the ends of the second screen portion 41 opposite to the ends connected to the actuator 43.

 The greenhouse is maintained as follows. The parts of the screen are adjusted so that, at normal temperature, the perforations 51 of the middle plate 41 of the screen do not overlap with the holes 51 of the plates 40 and 42 of the screen, and at an elevated temperature, such overlap takes place. Adjustment is made using electric drives 43, including the latter and pulling (releasing) flexible cables 48.

 In the trays 7 and conveyors 15 sow spores of mushrooms. In this example of the operation of the greenhouse, only the temperature sensor 53 is connected to the control unit (Fig. 3). If the temperature is lower than required, the control unit does not turn on the actuators 43. If the temperature exceeds the required, the sensor sends a signal of the appropriate level to the control unit and the latter turns on the actuator 43 for a certain time, while the holes of all three plates of the screen are aligned. Through them, air exchange occurs and the temperature in the space of the frame decreases.

 If the temperature drops below a critical temperature, then the control unit is turned on by a signal from the temperature sensor, which, in turn, turns on the reverse stroke of the actuator 43 for a certain time. The holes exit the overlapping position.

 Thus, the proposed device allows for automatic temperature control in a greenhouse near plants.

Claims (3)

 1. GREENHOUSE containing a fence, a frame in the form of triangular frames made of pairwise articulated racks with plant trays fixed to them, a piping system for feeding and draining the nutrient solution, characterized in that it is equipped with screens arranged parallel to the racks, each of which made in the form of three plates parallel to one another, the first and third plates being rigidly connected to the uprights, and the second is installed with the possibility of moving it along the uprights by means of a drive, otorrhea connected through the control unit with temperature sensors and / or humidity and / or ambient light, the holes in all three of the plates are arranged coaxially.  2. The greenhouse according to claim 1, characterized in that it is equipped with rollers mounted on the ends of the second plates.  3. Greenhouse according to paragraphs. 1 and 2, characterized in that it is provided with springs, each of which is attached at one end to a rack or guard, and the other at the end of the second plate, opposite the end connected to the drive.

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