RU2722442C1 - Rack system for cultivating plants with irradiating plant with forced cooling - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to agriculture, in particular, to hydroponics plants cultivation. Multi-tier rack plant for growing plants comprises light-emitting diode lamps arranged on tiers. Pipes with connection elements for supply of air for forced cooling are located perpendicular to the stages; at that, air supply through pipes for cooling is performed downwards. LED lighting fixtures include modules of a LED board and a radiator-cooler in the form of tubes with a developed ribbed surface.EFFECT: technical result is higher degree of plants protection against overheating due to heat removal from radiators.7 cl, 5 dwg

Description

The invention is intended for use in agriculture, in particular for growing plants by hydroponic nutrition, in sheltered soil.

Widespread, at present, in the world are multi-tiered rack-type plants for growing salad and herbal plants. The fundamental difference from classical greenhouses with light culture is a more efficient use of the area, the ability to use installations in conditions with low levels of natural light (including its complete absence), the ability to create mobile automated installations for use in remote areas, beyond the Arctic Circle, etc. The growing population of large cities also stimulates an increase in demand for fresh greens, with a shortage of areas, and in remote settlements, on the contrary, there is the problem of providing the population with fresh green mass necessary for healthy nutrition.

From the point of view of agricultural technology, multi-tiered racking systems allow using various combinations of nutrient mixtures, as well as spectra and levels of plant irradiation, to achieve high quality products with minimal energy costs. On certain crops, it is also possible to reduce the duration of plant vegetation.

State of the art

Thus, from the prior art, shelving plants for growing crops are known. For example, in document RU 55249 U1, a device for growing plants in protected ground conditions is described, comprising a plant cultivation system including a vertical multi-tiered rack installation for vegetation trays with plants, systems for creating the required climate and light conditions, the latter of which includes at least one light source, configured to move up and down between the tiers of the rack installation, characterized in that it contains means providing continuous reverse movement of the light source between the tiers during the period of plant irradiation. Document RU 61081 describes a plant for growing hydroponic green fodder, containing multi-tiered vegetation racks, a pre-germination chamber and auxiliary equipment, including a mobile electric processing device containing a rack located on the base, and a power source connected to conductive circuits mounted on the rack. A document for growing hydroponic feed is known from document RU 67392, comprising a sectional multi-tiered vegetation rack with a variable distance between tiers, rotating columns with a two-way screw support surface, shelves with pallets for growing feed, lighting devices and a moving irrigation boom with nozzles, characterized in that pallets are made with antimicrobial coating, including silver nanoparticles. Finally, the document RU 178645 discloses a phytostack containing a multi-tiered rack installation, radiation sources, a reflector and a control system of radiation source modes, characterized in that the rack installation contains vertical racks with the possibility of installing at least one lower shelf for plants and at least one the upper shelf for placement above plants on cooling radiators with a developed ribbed surface of at least one multichannel radiation source equipped with a lens diffuser with a light transmission coefficient of more than 0.92; at the same time, at least one channel of the multichannel source operates in the UV range of 365-400 nm, at least one channel operates in the visible range of the spectrum 400-740 nm and at least one channel operates in the infrared range of the spectrum above 740 nm, reflectors in the form of separate screens mounted on vertical racks between the upper shelf and the lower shelf on all four sides of the phyto-rack, with the condition that the gap between the reflectors and the shelves is maintained, while the reflector screen is removable on the front side of the rack to provide access to plants, and the radiation source operating mode control system is a multichannel current source located on the rack, interconnected by wires, radiation sources and a controller installed on the front side of the phyto-rack and equipped with software for controlling the spectral and temporal characteristics of the radiation, a control panel, for example, in the form of a touch screen, as well as non-volatile memory for I store in the database information on the dynamic and spectral characteristics of the incident radiation, and a screen reflecting the processed information from the database in the form of tables and / or graphs.

Among the main problems of existing installations, it is important to note the following:

Heat generation by irradiator. The main source of radiation in systems of this type is the LED module (cluster). For the proper functioning of the LEDs, it is necessary to ensure effective heat dissipation, while if the average level of irradiation at the plant level should be approximately 200 μmol / (cm ² ), taking into account the current level of LED efficiency of 2.0 μmol / J, the power consumed irradiating installation will be 100 W / sq.m. This leads to the release of thermal energy of the order of 60% or 60 W / sq.m.

Given the multi-tiered installation, in conditions of natural convection, the heat from the irradiators will rise up, warming the nutrient fluid, which at higher levels will lead to overheating of the root system of the plant and its death. Thus, a multi-tiered rack installation has different temperature conditions for the same plant culture in the same growing cycle.

Thus, there is a need to create a multi-tiered rack installation for growing plants with a regime that is approximately the same over the entire height of the installation, to prevent damage to the plant nutrition system and increase yields.

Description of drawings

FIG. 1 - schematically shows the design of an irradiating installation with pipes for supplying air for forced cooling, depending on the level or location of the shelving shelf with the culture.

FIG. 2 is a detailed diagram of a multi-tier rack installation with forced cooling in the form of air supply through pipes, including the position of the LEDs and radiator-cooler elements in the form of pipes.

FIG. 3 - shows the individual elements of the rack installation.

Brief Description of Shapes:

Items shown in the Figures:

1 - Pipe with connecting elements and air supply

2 - LED lamp

3 - rack

4 - air compressor 5 - connecting element

6 - round lamp housing

7 - element of the body-radiator

8 - LED board module.

Description of the invention

According to the present invention, a multi-tiered rack installation for growing plants is provided, with LED board modules, LED lamps, pipes with connecting elements perpendicular to the tiers for supplying air for forced cooling, with air supplying from top to bottom.

In one embodiment, the installation includes 4 or more tiers for growing plants.

In addition, in one embodiment, the air flow rate is regulated depending on the degree and power of the radiation.

Additionally, in one embodiment, the installation includes a heat sensor on the upper tier, for more efficient regulation of the air supply through the pipe for cooling.

In yet another embodiment, the installation includes at least 4 separate pipes for supplying air for forced cooling. In another embodiment, the installation includes pipes for supplying air for forced cooling, which at the same time can be the supports of a multi-tiered installation or serve to increase the rigidity of the rack.

In yet another embodiment, the forced air cooling pipes have a developed ribbed surface, preferably located in the area of the irradiator.

The advantages of this solution:

- Efficient cooling of LED modules. At the same time, it was possible to achieve a higher efficiency of the irradiator, as well as the ability to use a smaller number of LEDs in the higher unit power mode, which reduces the cost of the irradiating installation and increases the operating life.

- The possibility in the winter period, or in conditions of insufficient heating of the room, to use the heat removed to heat the room, by evenly distributing in the room the heat removed from the irradiators.

- The absence of the influence of heat generated by irradiators on the plant nutrition system.

- The ability to create specific irradiation spectra, through the use of various combinations of LEDs that accelerate plant growth and improve quality characteristics. Reducing the operating temperature of the LED crystals, due to forced cooling, reduces degradation processes and allows you to maintain the stability of the lighting parameters of the irradiators.

The main differences from the known installations

In the described installation, the following fundamental differences can be noted from existing solutions:

- The versatility of this installation. This installation makes it possible to work with all existing technologies for plant nutrition in closed ground conditions: growth in the ground, hydroponics (both by flooding and flow method), aeroponics, etc.

- The complete absence of spurious thermal effects on the supply trays and cassettes from the side of the irradiating LED installation.

- Low solution cost and low power consumption. This installation allows you to control the power consumed by the air compressor, depending on the ambient temperature and the temperature near the irradiators.

- The LED illuminator is located in a sealed transparent tube made of glass, plastic or any other material that provides mechanical strength to the structure and has a sufficient degree of transmission of light flux in the range from 300 to 800 nm.

The use of additional reflectors inside transparent tubes allows the formation of specific light intensity curves that reduce the loss of lateral emission and increase the efficiency of the irradiation system as a whole.

This installation was tested on lettuce crops and showed a yield increase of 25% compared to plants that do not have forced air cooling in the form of pipes with forced air flow from top to bottom.

The studies were carried out in the framework of Agreement No. 14.576.21.0099 on the provision of a subsidy dated September 26, 2017 (hereinafter - the Agreement) concluded between VNISI LLC and the Russian Ministry of Education and Science. Agreement ID: 0000000007417PD20002. Unique identifier of the work (project) RFMEFI57617X0099.

Claims (7)

1. A multi-tier rack installation for growing plants, characterized in that on the tiers there are LED board modules, LED lamps, pipes with connecting elements, perpendicular to the tiers for supplying air for forced cooling, a radiator-cooler in the form of pipes, while the air supply pipes for cooling are carried out from top to bottom, and LED lamps include LED board modules and a radiator-cooler with a developed ribbed surface in their housing. 2. Installation according to claim 1, characterized in that it includes 4 or more tiers for growing plants. 3. Installation according to claim 1, characterized in that the air supply rate is regulated depending on the degree and power of the radiation. 4. The installation according to claim 1, characterized in that it includes a heat sensor on the upper tier for more efficient regulation of the air supply through the cooling pipe. 5. Installation according to claim 1, characterized in that it includes at least 4 separate pipes for supplying air for forced cooling. 6. Installation according to claim 5, characterized in that the pipes for supplying air for forced cooling can simultaneously be the supports of a multi-tiered installation or serve to increase the rigidity of the rack. 7. Installation according to claim 1, characterized in that it is intended for growing plants in a closed ground.

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