RU2787086C1 - Cabinet for growing plants - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of hydroponic and aeroponic automated cultivation of plants. The cabinet for growing plants consists of a metal heat-insulated chamber with a solid inner shell made of ABS plastic, a front door with a panel for indicating parameters and their control. The cabinet contains retractable irrigation trays with cells for seed mats, to which adjustable nozzles-filters are connected. The cabinet includes an adjusting pipe, a container with a lid, in which holes are made for sensors of the nutrient solution adjustment system with a tubular electric heater. The cabinet contains a LED lighting system, an air exchange and temperature maintenance system inside the cabinet, a solenoid valve connected to a cylinder containing CO₂ installed in the lower part of the cabinet, and video cameras installed above each irrigation tray.

EFFECT: invention provides balanced growth and development of cultivated plants.

2 cl, 1 dwg

Description

The invention relates to the field of hydroponic and aeroponic automated cultivation of plants of various morphological structures and can be used in everyday life, as well as in food and agricultural industries for growing cultivated plants: field, garden, orchard, as well as forest plantations, i.e. the claimed invention as a whole can be attributed to crop production - agriculture and forestry, namely to equipment for planting and growing plants.

Known from the prior art is the source of information RU 132309 U1, 09/20/2013, which discloses a vegetative installation that relates to the field of agriculture, in particular, to growing plants in artificial conditions and can be used when conducting experiments on light culture, namely, obtaining experimental data on plant productivity depending on irradiation conditions.

This technical solution provides conditioning of the air supplied to the chamber for growing plants, determination of parameters and regulation of the composition of the gaseous environment of plants, the possibility of conducting comparative parallel experiments with varying conditions for irradiating plants while maintaining other parameters of the microclimate and irrigation regime at the same level.

To do this, the microclimate system includes an air conditioning device, the chamber for growing plants is made multi-section, the air ducts of the microclimate system and pipelines of the plant irrigation system pass through all sections of the chamber for growing plants in such a way that the parameters of temperature, humidity, gas composition of air and the mode of watering plants in them are maintained at the same level, and the exposure parameters may vary in individual sections of the chamber.

The disadvantage of the analogue is the lack of the ability to control and regulate a number of parameters that affect the intensification of plant cultivation.

The source of information RU 2546221 C1, 04/10/2015 is known from the prior art, which discloses an artificial climate cabinet containing a glazed working chamber with a glazed front door for observing plants, light sources located on the outside of the working chamber, a control unit and an air preparation unit , communicating with the working chamber through holes in the common wall, which is its ceiling and the bottom of the working chamber, characterized in that the rear glazed wall of the working chamber is made double in such a way that a cavity is formed for forcing air into it from the air preparation unit, and its inner glass has a slot in the upper part for the exit of circulating air into the working chamber and further into the air preparation unit through the holes in the bottom of the working chamber.

The disadvantage of the analogue is the lack of the ability to control and regulate a number of parameters that affect the intensification of plant cultivation.

The problem to be solved by the claimed invention is to eliminate the shortcomings of the prior art.

The technical result is to ensure a balanced growth and development of plants.

The essence of the technical solution of the claimed invention lies in the fact that the cabinet for growing plants is characterized by the fact that it consists of a metal heat-insulated chamber with a solid inner shell made of ABS (acrylonitrile butadiene) plastic, a front door with a panel for indicating parameters and their control, retractable irrigation trays with cells for seed mats, to which adjustable filter nozzles are connected, an adjusting nozzle, containers with a lid, in which holes are made for sensors of the nutrient solution adjustment system with a tubular electric heater, LED lighting system, air exchange and temperature maintenance system inside the cabinet, electromagnetic valve connected to the cylinder containing CO ₂ installed in the lower part of the cabinet, and video cameras installed above each irrigation tray.

Also the essence of the claimed invention is that the front door has double glazing with photochromic tinting.

Thus, the claimed invention is intended for growing plants with automatic maintenance of the required level of temperature, humidity, illumination, CO ₂ level, as well as measuring and adjusting the parameters of stiffness, electrical conductivity and temperature of the nutrient solution, to ensure the most efficient growth of various crops at all stages of growth and plant development.

The essence of the claimed invention is illustrated by the following drawings.

In FIG. 1 shows a general view of the claimed invention, a cabinet for growing plants (for better perception, it is presented without a door).

The claimed invention, a cabinet for growing plants is made in the form of a metal heat-insulated chamber with a solid inner shell made of ABS plastic and a front door with a parameter indication and control panel.

The front door has double glazing with photochromic tinting, which allows you to change the light transmission and reflective properties of the glass.

Inside the chamber there are retractable irrigation trays, with protection against leakage when extended, with cells for seed mats, to which adjustable nozzles-filters are connected for the circulation of the nutrient medium.

At the bottom of the irrigation tray there is an adjusting pipe designed to regulate the filling level of the tray, prevent overflow and filter out large particles. Adjusting the fill level is necessary to maintain the required substrate parameters depending on the type of substrate, the crop being grown and the current plant development cycle.

At the bottom of the chamber is a removable plastic container for the nutrient solution. The container has a hermetically sealed lid with holes for installing sensors for the level of electrical conductivity (EC), acidity (PH) and temperature of the nutrient solution, holes for feeding the components of the nutrient solution and a hole for installing a sterilizing ultraviolet lamp. At the end of the tank there is a hole with a quick connector and a check valve for filling in water from the central water supply system and a hole for draining the solution coming from the shelves.

At the bottom of the tank there is a hole for draining the waste solution into the central sewage system. The tank has two solution level sensors (upper and lower limit) and an emergency sensor (above the upper level) designed to determine the amount of solution and automatically fill it with liquid in automatic mode.

Filling the tank from the central water supply system is carried out by means of an electromagnetic valve controlled by the controller depending on the readings of the level sensors.

To purify the water coming from the central water supply system, the device is equipped with a system of cassette filters for coarse cleaning and a reverse osmosis system for fine cleaning.

To maintain the temperature of the nutrient solution in the tank, an electric heater can be installed.

The nutrient solution control system consists of conductivity (EC), acidity (pH) and nutrient solution temperature sensors and a system of peristaltic pumps. In the body of the product there are cells for installing cartridges containing concentrated multi-component mixtures of nutrients. Based on the readings of the sensors, the controller gives control signals to start the peristaltic pumps, which pump mixtures of nutrients from the cartridges into the nutrient solution tank to achieve the parameters set by the program in the controller.

The supply of nutrient solution from the tank is carried out using pumps and solenoid valves independently for each irrigation tray. The time and duration of the feed is adjusted by means of the controller or in manual mode by pressing the corresponding button on the control panel of the device.

When growing different types of plants, it is possible to install several containers for mixing the nutrient solution.

Installed above each irrigation tray is a combined LED lighting system consisting of full spectrum LEDs, red spectrum (660nm), far red (730nm) and ultraviolet (265nm) LEDs.

The full spectrum, red and far red LEDs are independently adjustable with a controller and can change their brightness depending on the life cycle of the plant.

Ultraviolet LEDs are necessary for disinfection of the chamber during the replanting period.

The luminaires have an independent closed system of active cooling; heated air from the luminaire radiator is utilized into the atmosphere thanks to a fan installed inside the luminaire chamber.

The air exchange and temperature maintenance system inside the device consists of supply and exhaust fans, a heat exchanger radiator and internal fans. A temperature and humidity sensor is installed above each irrigation tray.

To supply fresh air from the environment and remove exhaust air, supply and exhaust fans are used, which, through a system of ventilation ducts located inside the device case, supply and remove air through ventilation grills located above each irrigation tray. Carbon and HEPA filters can be installed to purify the incoming and outgoing air. When the maximum air temperature inside the chamber is exceeded, the cooling of the heat exchanger radiator is switched on, the refrigerant begins to be pumped through it using a refrigeration compressor located behind the rear wall in the lower part of the device. The air in the internal chamber of the device begins to circulate through the radiator with the help of internal fans.

There are CO ₂ level sensors inside the chamber. When the level of CO ₂ drops below the level set in the controller, an electromagnetic valve opens, through which CO ₂ is supplied into the chamber from a replaceable cylinder installed at the bottom of the device for the required concentration and increase in the rate of photosynthesis.

Video cameras are installed in the working cavity of the chamber above each irrigation tray, allowing real-time monitoring of the growth and development of plants. Camera data can be collected and processed on a cloud server on the Internet. Subsequently, based on the collected data, it is possible to train a neural network model to determine all cycles of growth and development of various crops, determine the optimal parameters of the microclimate, solution concentration, irrigation and lighting periods to obtain the maximum yield and quality of each type of cultivated crop, as well as determine various diseases and pests on various crops in the early stages of growth.

Thus, the claimed invention, a plant growing cabinet, provides a balanced growth and development of cultivated plants.

Claims (2)

1. Cabinet for growing plants, characterized by the fact that it consists of a metal heat-insulated chamber with a solid inner shell made of ABS plastic, a front door with a panel for indicating parameters and their control, retractable irrigation trays with cells for seed mats, to which adjustable nozzles-filters are connected , control pipe, a container with a lid, in which holes are made for sensors of the nutrient solution adjustment system with a tubular electric heater, LED lighting system, air exchange and temperature maintenance system inside the cabinet, electromagnetic valve connected to a cylinder containing CO ₂ installed in the lower part of the cabinet , and video cameras installed above each irrigation tray. 2. Cabinet for growing plants according to claim 1, characterized in that the front door has double glazing with photochromic tinting.

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