RU2682749C1 - Greenhouse - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to agriculture, in particular, to plants growing in closed ground. Greenhouse comprises at least one greenhouse unit equipped with a watering device. Unit additionally includes a device for ventilating the greenhouse and a soil heating device. Automatic control system of said devices includes at least one temperature and humidity sensor, which outputs are connected to part of inputs of arithmetic logic unit, made with function to receive signals from sensors, to compare obtained data with control ones and to output control signals to switch on said devices. Other part of the inputs of the arithmetic logic unit is connected to the outputs of the replaceable storing memory device, on which the program of the selected climatic zone and the program for growing the selected plant of this climatic zone are recorded. Third part of inputs is connected to outputs of position sensors of elements of said devices, inputs of which are connected through automatic control system with outputs of arithmetic logic unit and inputs of indication unit. Ramp translucent enclosures along lower perimeter are equipped with polyethylene flute connected with irrigation system. Ramp translucent enclosures in lower part are equipped with cleaning brushes installed on the telescopic device and driven by an electric drive connected to the automatic control system. Cultivators are placed along the rear panels above the ground, the actuators of which are connected to an automatic control system. Cultivators are equipped with spray guns, which are connected by means of metal-ceramic pipes located inside the axis of the cultivator with irrigation system. Humidity sensor is in form of a mobile microwave device placed in the extreme working members of the cultivator. In addition, there are illumination sensors whose outputs are connected to corresponding inputs of the arithmetic logic unit. Ramp translucent enclosures on the inner side are provided with shutters the actuator of which is connected to the automatic control system.EFFECT: such design ensures creation of a greenhouse for cultivation of a wide range of grown plants of any climatic zone with an automatic control system for irrigation, ventilation and heating.1 cl

Description

The invention relates to agriculture, in particular to the construction of sheltered soil, and can be used on personal plots and in farms.

A well-known greenhouse with a glass fence, incl. enclosed in a removable frame (patent for invention RU No. 20111336 [1]). The disadvantages of such a greenhouse are: low mechanical strength of the glass, the relatively large mass of glass and frames, the complexity or inability to disassemble the frame (greenhouse) for off-season safety.

The known design of the greenhouse, which is a frame covered with a continuous film (patent for utility model RU No. 30058 U1 [2]). The disadvantages of such a greenhouse are: rapid “aging” of the film under the influence of temperature and weather changes, mechanical destruction of the film when pulling it on the frame and removing it, during the operation of the greenhouse - from fluctuations under the influence of wind.

A known greenhouse (patent for utility model RU No. 85298 U1, 08/10/2009 [3]), the design of which can be used for greenhouses and greenhouses of small sizes. A characteristic feature of this design is the presence in the frame arcs of grooves along which translucent sheets move, providing the formation of openings for ventilation and the performance of work to care for plants. The disadvantage of this solution is the difficulty in manufacturing grooves in arcs, as well as certain difficulties associated with the "jamming" of the sheets when they are moved in the grooves.

The technical result, which is achieved by the well-known utility model (RU No. 103272 U1, 04/10/2011 [4]), is to create a durable, resistant to external influences, durable, easy to assemble and easy to use greenhouse, which is characterized by ease of manufacture, ease of assembly, reliability and low labor intensity in operation.

In this case, the technical result is achieved due to the fact that the greenhouse containing side frame arcs forming the end walls fastened by rigid horizontal guides (stiffeners), a flexible translucent coating in the form of end sheets fixedly mounted on the frame arcs, the top sheet rigidly fixed to side arches and guides, and two moving side sheets fixed in their own frames, made in the form of a cylinder having a longitudinal horizontal slice. Each lateral arc of the end wall, forming a circular segment, is rigidly connected with diametrically extending jumpers that intersect and are rigidly fastened in the center of the segment.

At the point of attachment of said jumpers, i.e. in the center of the segment, a round pin is welded, through which the tops of the sectors of the side sheets are pivotally fastened to the bridges of the end wall. The lateral moving sheet is rigidly enclosed in a frame, the lower and upper parts of which are stiffeners, and the lateral are sectors whose radius is less than the radius of the end (side) arc. The plane of the cut greenhouse is installed on the surface of the soil, on which sowing and growing crops. The material used to cover the greenhouse - polycarbonate, is durable, flexible and resistant to mechanical and weather influences.

A significant drawback of the known greenhouse designs [1-4] is the lack of automated communications to ensure the livelihoods of farmed crops.

The identified drawback of the known technical solutions is partially eliminated by equipping the greenhouses with heating systems (patents: RU No. 2150818 C1, 06.20.2000 [5], DE No. 1632908 A, 06.24.1971 [6], copyright certificates: SU No. 1111706 A, 07.09 .1984 [7], SU No. 1323029 A1, 07/15/1987 [8], SU No. 1525290 A1, 11/30/1989 [9], SU No. 1349727 A1, 11/07/1987 [10], SU No. 1630684 A1, 02/28/1991 [11]), which contain a boiler, a heating system for the tent of the greenhouse, a condensing surface heat exchanger connected via a water path to the subsoil heating system, and a channel for removing combustion products into the atmosphere in which the condensate collector is installed combustion products with a hydraulic shutter and a separation device - drop eliminator. The gas distribution system has a carbon dioxide generator and is communicated through a filter with a channel for the removal of combustion products into the atmosphere. The installation of a condensation surface heat exchanger of the exhaust gas combustion products allows for deep cooling of the combustion products, removal of the air decarbonizer with the storage tank of the heated degassed water from the device circuit and eliminating the need to install a special draft fan machine for transporting the combustion products through the heat exchanger. However, the disadvantages of such devices can be attributed to low productivity and increased fuel consumption, increased capital investment in the maintenance and operating costs of maintaining a contact heat recovery unit for the heat of combustion products.

The reasons that impede the achievement of the technical result when using the known devices [5-11] include the fact that the known devices for heating the greenhouse have reduced efficiency due to the increased capital investment for the maintenance and operational costs of maintaining a contact heat recovery unit of the combustion products and air decarbonizer with the storage tank of heated degassed water, and also because of the need to install a special draft blower for transporting products anija via pin heat exchanger. The decarbonizer vapor is not utilized in the device, in addition, the connection of the decarbonizer vapor outlet pipe to the gas distribution system of the greenhouse does not increase its efficiency, because the volumetric content of carbon dioxide in the air decarbonizer vapor does not exceed 0, even when treating the source water with a high initial concentration of carbon dioxide, 2% (see Sharapov V.I. Preparation of makeup water for heat supply systems using vacuum deaerators. - M.: Energoatomizdat, 1996, p. 90).

For example, the essence of the known invention [5] aimed at improving efficiency is as follows.

It is known that contact-heated water absorbs a certain amount of carbon dioxide and oxygen from the products of combustion. Carbon dioxide gives water the properties of a weak carbonic acid with enhanced corrosion properties. To ensure reliable operation of heat supply systems (heating), the water heated by the contact method is degassed. Degassing is carried out in an atmospheric thermal deaerator or (in the absence of a deaerator) in a decarbonizer with air purging with a low pressure electric fan, which significantly reduces the overall efficiency of the plant. In addition, when using a contact heat recovery unit with significant aerodynamic drag, there is a need for a special draft blower to transport combustion products through the heat recovery unit. To increase efficiency by reducing capital investments and operating costs, it is advisable to heat the water circulating in the heat supply (heating) systems in condensing surface heat exchangers, when using which the exhaust combustion products are also cooled below the dew point, but the heated coolant does not come into contact with the combustion products. In this case, the degassing of heated water is excluded, as well as the need to install a special draft machine for transporting combustion products through the heat exchanger, since the additional aerodynamic resistance created by the condensation surface heat exchanger is negligible and is overcome by reducing the volume and increasing the density of the combustion products due to a decrease in their temperature and loss parts of water vapor in the form of condensate.

However, the known technical solution [5], has significant mass and size characteristics, and is also not an environmentally friendly device due to the fact that the gas distribution system is communicated through a filter with a channel for the removal of combustion products into the atmosphere.

Also known devices that are greenhouses (patents RU No. 2239986 C2, 11/20/2004 [12], EP No. 0744121 A1, 11/27/1996 [13], FR No. 2668027 A1, 04/24/1992 [14], EP No. 0217978 A1, 04/15/1987 [15], EP No. 0378868 A1, 07/25/1990 [16], EP No. 0529725 A1, 03.03.1993 [17], RU No. 2054865 C1, 02/27/1996 [18]) and related to the field of agricultural cultivation facilities protected soil and which can be used, in particular, in the construction of greenhouses intended for growing various vegetable, fruit, medicinal and flower crops in an artificial microclimate under a translucent coating. For example, the well-known greenhouse [12] contains vertical spros and sprocks of the roof, girders of the roof and side walls, ridge profile, ventilation windows, translucent panels. The ridge profile is made with a groove in which the hinges of the ventilation window rotate, fixed in working positions by rods of the opening-closing mechanism. The upper and lower bindings of the ventilation window are connected by translucent panels and sproils of the ventilation window, and the lower binding rests on the under-profile - directly on the rib and through a flexible shock-absorbing pad. Translucent panels along the ridge profile are interconnected by roof spurs, and along the roof slope - by connecting profiles. The profiles of the lower and upper roof trusses support translucent panels and roof spros, with the lower profile resting on the side edge of the gutter. The upper harnesses of the roof and ventilation vents are made with a loop in the form, which provides both the initial installation of the harnesses during the installation of the greenhouse, and the subsequent installation in the working position. Achieved technical result is to increase the efficiency of condensate removal from the inner surfaces of the roof of the greenhouse and ventilation windows; increasing the reliability of the junction of the narthex of the ventilation window with the underlying parts of the roof of the greenhouse; ensuring a strong and reliable connection of translucent panels of the roof of the greenhouse; simplification of the installation and dismantling of ventilation vents on the ridge profile of the greenhouse; ensuring rigidity of fastening of the profile of the upper trim of the greenhouse roof to the ridge profile; decrease in material consumption of the ridge profile of the greenhouse.

The disadvantage of this technical solution is the impossibility of changing the temperature and humidity conditions inside the greenhouse depending on the state of the external atmosphere to ensure agronomic requirements when growing various crops in full, as well as the low level of automation of the process of regulating the temperature and humidity conditions inside the greenhouse.

Famous greenhouses for personal plots of various designs, as a rule, consist of frame or arc frames with a door and openings closed with various translucent materials. Side or top frames in some types of greenhouses are made movable for ventilation. Separate greenhouses are equipped with semi-automatic ventilation, watering and heating devices. In such greenhouses, only unpretentious crops and flowers of this climatic zone (for example, central Russia) can be grown, because it is impossible to constantly maintain the necessary climatic conditions (different air temperatures in the daytime and at night, the necessary humidity of air and soil, changes in irrigation during plant growth from seeds to crops, etc.) without the presence of a person, and a person is often in his household plot. only on weekends. The main disadvantage of known greenhouses is the need for a constant human presence for its operation.

Also known devices that relate to agriculture, namely, the means of growing plants in closed ground (patents: RU No. 2259036 C1, 08.28.2005 [19], RU No. 2122315 C1, 11.27.1998 [20], RU No. 2025956 C1 , 01/09/1995 [21], RU No. 2121787 C1, 11/20/1998 [22]).

So, for example, the well-known automated greenhouse [20], containing at least one greenhouse block, a tank for water sludge with a connection pipe to the water supply via the main pump, in communication with the water supply pipe, which is connected to the fuel system, the control unit, the first , the second and third outputs of which are connected with the first and second controlled valves installed respectively on the connection pipe to the water supply, water supply pipe and control input of the main pump. The well-known automated greenhouse is also equipped with a hydroponic multi-tiered module, including a nutrient solution supply pump, connected to the reservoir with the nutrient solution and through the corresponding pipeline, at least one sprouting plant, as well as a third controlled valve and controlled hydraulic switch, which are installed on the first and second branches the main pipeline, respectively located after the main pump and before the second controlled valve, while the first is in communication with the tank with a nutrient solution, and the second one with one of the exits of the hydraulic switch, the other outlet of which is connected to the pipeline is laid out, and the output is with the output of the pump of the nutrient solution, and the fourth and fifth outputs of the control unit are connected to the corresponding inputs of the controlled hydro switch and the pump of the nutrient solution and the reservoir with the nutrient solution is equipped with level sensors connected to the corresponding inputs of the third controlled valve.

This greenhouse allows you to automatically only water the plants, and only certain types of plants.

So, for example, the known greenhouse [19] contains at least one greenhouse block equipped with an irrigation device. The unit is additionally equipped with a greenhouse ventilation device and a soil heating device. The automatic control system of these devices includes at least one temperature and humidity sensor, the outputs of which are connected through amplifiers-converters with part of the inputs of the arithmetic-logic device, configured to receive signals from sensors, compare received data with control signals and issue control signals to enable these devices. The other part of the arithmetic-logic device inputs is connected to the outputs of a removable permanent storage device on which the program of the selected climatic zone and the program of growing the selected plant of this climatic zone are recorded. The third part of the inputs is connected to the outputs of the position sensors of the elements of these devices, the inputs of which are connected through the control unit and amplifiers-converters with the outputs of the arithmetic logic device and the inputs of the display unit. The automated control system is powered by a voltage of 12 V. Such an implementation provides the creation of a greenhouse for growing a wide range of plants grown in any climate zone with an automatic control system for irrigation, ventilation, heating compared to the known greenhouse [20].

However, the well-known greenhouse requires large energy costs and in modern economic conditions this will lead to an overestimated price for the grown products.

Greenhouses are also known (RU No. 2550654 C1, 02.20.2014 [23], RU No. 2207752 C1, 07/10/2003 [24], SU No. 418998 A3, 08/01/1974 [25], RU No. 20816 U1, 12/10/2001 [26 ], RU No. 2040666 C1, 07.25.1995 [27], GB No. 2187221 A, 09/03/1987 [28]), which relate to agriculture and can be used in specialized farms, in household plots and cottages for growing, for example, seedlings of vegetable crops. So, for example, the well-known greenhouse [23] includes a foundation base, pitched translucent fences, the panels of which are facing south and are oriented in the possible direction of sunlight, the working passage on the rear heat-insulated panel and devices for heating and irrigation. The front and rear panels are framed by a frame made of electrically conductive material in the form of faces of a quadrangular pyramid, the tops of which are oriented to the cardinal points and are grounded. The panels and jumpers between them are made of dielectric material. The top of the pyramid is equipped with a lightning rod and / or is electrically connected to the converter and the battery. This implementation provides stimulation of the vital activity of plants and soil microflora, a beneficial effect on the staff and on the environment inside and outside the greenhouse, which increases the efficiency of use of the greenhouse.

However, the well-known designs of greenhouses [19] and [23], along with their advantages over known analogues, do not fully provide the necessary conditions for growing agricultural products.

In order for the cultivation of vegetables in greenhouses to be successful, the necessary conditions must be provided:

optimal humidity; correct temperature day and night; adequate ventilation; soil containing all the necessary fertilizers, trace elements and organic matter; proper care.

To achieve such results, you need to know the rules of how to grow vegetables in a greenhouse, and at the same time follow the growing technology. Only then the quality of the crop will justify the invested forces and means.

The basic rules for growing vegetables in a greenhouse are as follows.

In the summer, the air temperature in the greenhouse can rise above the permissible level, which will adversely affect the cultivation of vegetables in it. Vegetables in the greenhouse are wilted, and there will be no harvest. Air temperature is the most important factor in the proper cultivation of vegetables.

If the temperature in the summer rises above 50 degrees, then the vegetables urgently need to be saved. To do this, you need to create shading in the greenhouse or greenhouse in advance. This will save the greenhouse from overheating and raising the temperature of the air inside. Cucumbers are very thermophilic, they do not tolerate frost and can die even with a slight decrease in temperature. An equally important factor for proper cultivation in greenhouses is watering plants.

The water temperature for watering vegetables in the greenhouse should correspond to the temperature of the soil. The ideal option for irrigation is drip irrigation. If watering is carried out by the traditional method, then pour water under the root of the plant.

For the preparation of nutrient solutions, all mineral salts are taken in strictly defined quantities. For the normal development of most plants, the ratio nitrogen - phosphorus - potassium - magnesium is 1: 0.5: 2: 0.3.

It is also necessary to take into account the fact that the simultaneous cultivation of vegetables in greenhouses in the neighborhood may be incompatible. This is due to the fact that all plants are different and they need different care, some need abundant watering, while others, on the contrary, like dry soil, someone needs high air temperature, but someone does not.

Vegetables in greenhouses and on the open ground need nutrients that are not always found in the soil. Therefore, it is periodically necessary to add special top dressing.

As natural nutrients that plants need, it is worth separately mentioning humus, manure, bird droppings, peat. It is in these substances that there is everything necessary for each culture, it is often recommended to mix them with straw. To enrich the soil with nitrogen, it is recommended to first sow legumes. After they grow enough, plants are plowed into the soil. Wheat and rye straw is popular, which is mixed with litter and a small amount of manure. When this mixture is decomposed, nutrients are released into the soil, which can be an excellent nutrition at the beginning of crop growth. Other fertilizers are used for greenhouses: biohumus, which improves the structure of the soil; ordinary humus with worms that not only secrete nutrients in the process of their life, but also loosely soil.

So that crops can develop normally and bear fruit in the greenhouse, it is necessary to choose the right soil for this. For each crop, the composition and type of soil will vary, but there are basic requirements that must be observed:

the thickness of the fertile layer should be 5-10 cm for seedlings and 30-35 cm for an adult plant; the substrate in the greenhouse must be periodically changed, as pathogens gradually accumulate in it. For disinfection, you can use special chemicals, but often enough to leave a layer of soil in the open sun for a while; all greenhouse substrates must meet the following requirements: fertility, breathability, lack of toxic substances, pathogenic bacteria.

When asked how to grow vegetables in a greenhouse, you need to pay attention to many details. This is not only fertilizers and soil, but also watering, the level of lighting, humidity. Planting and harvesting are carried out at different times.

The temperature for growing in a greenhouse should be at the level of 26-28 ° C during germination of seeds after sowing; during growth - 18-35 ° C; the difference between night and day temperature should be 4-6 ° C, but in cloudy weather it should be less; for soil, the temperature is suitable at 25-30 ° C, since the plant loves heat very much; temperature differences from the soil level to the top of the greenhouse should be very smooth, do not change at an altitude of 2 m.

Before planting, for example, cucumbers in the ground, it is necessary to dig in the soil biofuel, which is manure (preferably horse). About 3-4 kg of manure should go to one plant to ensure soil heating.

You can mix manure with straw to increase the amount of biofuel for laying. Growing cucumbers suggests that on hot summer days the walls and roof of the greenhouse should be slightly shaded, otherwise burns will appear on the leaves.

On ordinary days, this shading is not necessary. With a shorter daylight, you need to slightly lower the temperature, but only within the range.

The daylight hours should last from 10 to 12 hours, a larger and smaller value is not recommended, since there will be disturbances in growth. The humidity level should be high, reach 85-95%, this is especially important on the hottest days. Ventilation is organized to supply carbon dioxide to plants, but we must remember that drafts are not allowed, since cucumber does not like cold air.

Watering is plentiful, the soil should always be slightly moist.

An average of 150-200 liters of water is consumed per 10 kg of crop. The temperature of the liquid should be equal in temperature to the soil, often it is with the help of water that the soil can be heated if it begins to lose heat.

After each irrigation, the soil loosens so that there is no stagnation of water, as this will provoke the appearance of rot.

To prevent damage to the structures caused by melting snow or heavy rains, drainage should be provided around the structure - an ordinary ditch 50 cm deep.If the greenhouses are mobile, then there should be spare free places for moving the greenhouses 2-3 times per season.

Free areas are chosen so that they are 3-4 times larger than the area of the greenhouse. Growing vegetables in greenhouses and greenhouses requires the creation of an artificial microclimate, laying quality land. Naturally, it is necessary to focus on what kind of culture is planned to be grown, on age, the specifics of the variety, weather conditions, and cultivation goals. One of the most important factors for greenhouse plants is the light that is needed to create a special microclimate.

First of all, thanks to light, carbon dioxide is absorbed by plants, and the heat that sunlight brings with it is necessary to heat the greenhouse. The light passing into the greenhouse through glass or film does not all pass through. About 10% of the rays are retained by glass and structural elements.

If the day is cloudy, then about half of the whole world gets into the greenhouse. Therefore, you need to know about the factors that affect the illumination. This is the location of the greenhouse or greenhouse, design features, the angle of the roof, the degree of contamination of glass, film.

Glass and film should be periodically cleaned, washed with water using cleaning products.

In most regions of Russia, vegetables can be grown year-round only with artificial light (in November-December), with the exception of the southern and eastern regions. Most often, cucumbers and tomatoes are grown in greenhouses and greenhouses, so you can take them as a sample. Cucumber is susceptible to heat, and even to the human - it is better to pay attention to cucumbers every day. Recommended temperatures: in the daytime, but when it is cloudy, it is about 22 ° C, when the sun is 25-30 ° C, at night it is 15-18 ° C.

In this case, the relative humidity is 90-95%. Since the roots of the cucumbers are small (no more than 20 cm), they are watered every day in summer, unless the weather is cloudy. Water temperature 35-40 ° C.

To moisturize the air, moisten paths, walls and plants several times a day. Leaves of mature cucumbers should not be moistened, as this interferes with their ventilation and diseases can spread in a humid environment. In general, for cucumbers, the optimal atmosphere would be stuffy, moist, warm.

They do not like drafts, so they ventilate gently, opening one door or through the windows. The microclimate in the greenhouse with cucumbers is such that it contributes to the appearance of fungal diseases. A plant can become ill with a lack of care, and this seriously weakens it.

Tomato roots are deepened by 50-70 cm. The plant prefers dry air (air humidity not more than 70%). Tomatoes, unlike cucumbers, can hang on the bush for a long time, without interfering with the ripening of new fruits.

Water the plant a lot, every 3-4 days or every week, in the morning in sunny weather. Do not spray - water must flow through the grooves. Subsoil irrigation is recommended.

The earth needs to be loosened periodically and often enough. The watered plant is mulched with bark. Thick plantings of tomatoes are extremely undesirable, strong varieties are planted in 2-3 plants, and medium - 3-5 units per square meter. Tomatoes are more sensitive to excess heat than cucumbers.

When the ambient temperature rises to approximately 29 ° C, the fruits stop setting and blush unevenly.

The design of the known greenhouses, their equipment does not fully meet the necessary requirements.

The objective of the proposed technical solution is to increase the efficiency of use of the greenhouse.

The problem is solved due to the fact that in the greenhouse, including the foundation base, pitched translucent fences, the panels of which are facing south and are oriented in the possible direction of sunlight, the working passage on the rear heat-insulated panel and devices for heating and irrigation, the front and rear panels are framed a frame made of electrically conductive material in the form of faces of a quadrangular pyramid, the vertices of the base of which are oriented to the cardinal points and are grounded, while the panels and jumpers between they are made of dielectric material, while the top of the pyramid is equipped with a lightning rod and / or is electrically connected to the converter and the battery, an automatic control system for these devices, including at least one temperature and humidity sensor, the outputs of which are connected to part of the arithmetic inputs a logical device configured to receive signals from sensors comparing the received data with the control and issuing control signals to turn on these devices, another part the arithmetic - logic device inputs are connected to the outputs of a removable permanent storage device on which the program of the selected climatic zone and the program for growing the selected plant of this climatic zone are recorded, and the third part of the inputs is connected to the outputs of the position sensors of the elements of these devices, the inputs of which are connected via an automatic control system with the outputs of the arithmetic - logical device and the inputs of the display unit, in contrast to the prototype, pitched translucent fences along the lower perimeter is equipped with a polyethylene gutter articulated with an irrigation system, pitched translucent fences in their lower part are equipped with cleaning brushes mounted on a telescopic device and driven by an electric drive connected to an automatic control system, multicultivators are located along the rear panels above the ground, an actuator which is connected to an automatic control system and equipped with atomizers, which are connected by metal of ceramic tubes located inside the axis of the multicultivator, with an irrigation device, the humidity sensor is made in the form of a mobile microwave device located in the extreme working bodies of the multicultivator, light sensors are additionally introduced, the outputs of which are connected to the corresponding inputs of the arithmetic-logic device, pitched translucent fences on the inside equipped with blinds, the actuator of which is connected to an automatic control system.

The technical result of the claimed invention is the creation of a greenhouse for growing a wide range of cultivated plants of any climate zone with an automatic control system for irrigation, ventilation of the greenhouse and its heating.

According to the prototype [23], the front and rear panels are framed by a frame made of an electrically conductive material in the form of faces of a quadrangular pyramid, the tops of which are oriented to the cardinal points and are grounded, while the panels and jumpers are made of dielectric material.

In addition, the top of the pyramid is equipped with a lightning rod and / or is electrically connected to the converter and the battery.

As in the prototype (Fig. 1 prototype), the greenhouse includes a foundation base embedded in the soil and rising above the soil. A greenhouse frame in the form of faces of a quadrangular pyramid is mounted on a foundation base. The frame includes its base, the vertices of which are oriented to the cardinal points. The frame is made of electrically conductive material, such as aluminum alloy. Ribs extend from each vertex of the base at an angle to the vertical. The sides of the base and ribs are the faces of the quadrangular pyramid, the top of which is equipped with a lightning rod. The vertices of the base of the frame are grounded by means of corresponding pins. The sides of the base and the inclined edges of the pyramid are a means of framing the front - pitched translucent panels, and the rear insulated panels. Pitched translucent panels are made of a dielectric material, for example, cellular polycarbonate. Translucent faceplates face south, more specifically, respectively, to the southeast and southwest. The rear heat-insulated panels face the northeast and northwest, respectively; these panels can be limitedly translucent. Each translucent panel can be made of several parts, the jumpers between which are made of dielectric material. On the back panels, work passages and other known devices are provided. The pyramid frame has enhanced conductive properties. In it, the top of the pyramid and the lightning rod are electrically connected to the converter of the emerging electric current and the battery. The greenhouse has a device for heating and irrigation.

In contrast to the prototype, pitched translucent fences along the lower perimeter are equipped with a polyethylene gutter articulated with an irrigation system. Pitched translucent fences in their lower part are equipped with cleaning brushes mounted on a telescopic device and driven by an electric drive connected to an automatic control system. Multicultivators are located along the rear panels above the ground, the actuator of which is connected to an automatic control system and equipped with spray guns, which are connected by means of ceramic-metal tubes located inside the axis of the multicultivator to an irrigation device. The humidity sensor is made in the form of a mobile microwave device, located in the extreme working bodies of the multiculture. Additionally, light sensors were introduced, the outputs of which are connected to the corresponding inputs of the arithmetic-logic device. Pitched translucent fences on the inside are equipped with blinds, the actuator of which is connected to an automatic control system.

The moisture sensor, made in the form of a mobile microwave device as a microwave emitter, contains a Gunn diode mounted flush mounted in the extreme working bodies of the multicultivator, which provides reliable measurement of soil moisture, in contrast to the known designs of humidity sensors such as LMA-200PM, MW-1000 and description of patent RU No. 2641715 C1, 01/22/2018.

The use of spray guns, in contrast to the moisture sprayers used in the analogues and prototype, makes it possible to deliver moisture to the root system of the grown products.

Due to the fact that after watering the cultivated products, it is necessary to loosen the soil, multicultators are provided in the proposed technical solution.

To regulate the necessary illumination for a particular cultivated product, light sensors are placed in the greenhouse, the outputs of which are connected to the corresponding inputs of the arithmetic-logic device.

For this purpose, blinds are also intended, the actuator of which is connected to an automatic control system, as well as cleaning brushes, which in winter can, if necessary, be used to clear snow.

Due to the fact that rainfall is required to divert rainfall from the frame elements of the greenhouse in the rainy season, in the proposed technical solution, the pitched translucent fences along the lower perimeter are equipped with a polyethylene gutter articulated with an irrigation system, which makes it possible to replenish the supply of water for irrigation.

An automatic irrigation device can be made in the form of an accumulation tank and a distributor of the same capacity with automatic controlled drainage of water into cermet tubes located inside the axis of the multiculturizer and connected to spray guns.

The automatic heating device can be made in the form of a conductive heating element in a protective shell, for example, heating panels, placed in the foundation under the soil layer of the greenhouse.

The automatic control system is a micromodule controller based on an Intel-compatible NEC V25 processor with a PCMCIA flash drive and a standard output communication tool based on the RS232 interface. The microcontroller contains a built-in multi-channel ADC with a serial interface, programmable timers, real-time clocks, digital I / O ports, external hardware interrupt channels and a direct memory access channel. Distinctive features of the controller used are miniature dimensions (100 × 70 × 30 mm), low consumption (0.5 W), high reliability and low cost.

The inputs of the automatic control system are connected to the outputs of the sensors for recording temperature, humidity, illumination and greenhouse devices.

The developed ALU in a specific design is the minimum configuration of a personal computer and includes: a processor - Pentium 166 MHz, RAM - 32 MB, an SVGA card with 1 MB memory, an additional card with two serial ports with FIFO memory (UART16550-compatible).

The software for the algorithms for growing products and the functioning of the equipment of the greenhouse is written in a high-level C language, which at the same time allows for fine control of the hardware up to bitwise operations in their registers, typical for assembler. The use of Borland C language compilers by appropriately adjusting the compiler environment allows generating codes that are largely invariant to the type and class of the IBM-compatible computer used. As a result, the program turns out to be workable for all types of processors, starting with the 8086/8088 family and ending with 80486 and Pentium.

The version of the program is located in the EPROM microcontroller. The launch of the program for execution and, accordingly, the start of work occurs automatically when power is supplied to the microcontroller.

The proposed greenhouse is used as follows.

The greenhouse, through the vertices and faces of the quadrangular pyramid - its inclined edges and sides of the base - perceives and partially accumulates the chronic cosmic energy that enters planet Earth year-round and around the clock. This phenomenon in the greenhouse is enhanced by the implementation of the faces of the pyramid of electrically conductive material and orientation of the vertices of the base to the cardinal points; it is obvious that the inclined edges of the pyramid are also oriented to the cardinal points. In the Earth’s atmosphere there are always electric charges and electromagnetic fields, which are amplified under certain conditions. Part of the charges is perceived by a lightning rod installed on the top of the pyramid, and the edges of the pyramid, spreads inside and outside the pyramid, is transmitted to the sides of the base. From the lightning conductor and the energy-intensive top of the pyramid, part of the electric charges flows into the converter, where it is structured, converted into an ordered direct current and supplied to the battery. Part of the energy through the grounding pins is diverted to the foundation of the greenhouse and, ultimately, to the ground.

Inside the pyramid greenhouse, the largest energy field is concentrated at a distance equal to one third of the height of the pyramid, counting from the base. At this height, it is advisable to install dielectric racks for growing, for example, vegetable seedlings. Inside the greenhouse is illuminated by sunlight penetrating through the front - pitched translucent panels. Rear heat-insulated panels to some extent impede the removal of internal heat. When reducing the duration of daytime, artificial lighting inside the greenhouse is possible due to the energy stored in the battery. Natural lightning discharges do not penetrate into the greenhouse, since energy is extracted by means of lightning rods, pyramid ribs and pins, this is facilitated by their execution from electrically conductive material. Maintenance of the greenhouse and technological operations are carried out through the working aisles, which are also used for ventilation in hot summers. The cultivation of vegetables and other crops, their irrigation, as well as heating in cold time (if necessary) is carried out in a known manner in accordance with the modes for these conditions and the current parameters recorded by sensors, based on which control signals are generated for the corresponding equipment ..

Automatic control system (ACS) operates as follows.

In the initial state, the power supply is turned off, and at this time in the greenhouse the necessary agricultural work is carried out (soil preparation, planting, harvesting, etc., preventive and maintenance work with the control system). Before turning on the power, a removable permanent storage device is installed on the arithmetic-logic device, on which the program of the selected climatic zone and the program of growing the selected plant of this climatic zone are recorded. When you turn on the display unit displays the parameters of the selected climate zone (temperature and humidity), date, time, power status and all devices that support the selected mode, as well as other useful information. Information from the sensors and devices of the greenhouse enters the ALU, which compares the received data with the control obtained from the ROM, if they do not match, the ALU includes the devices that are currently needed.

The specific energy-efficient “climate” inside the greenhouse, including through the use of chronic cosmic energy, stimulates the vital activity of plants and soil microflora, increases the consumer properties of cultivated crops, has a beneficial effect on staff and the environment inside and outside the greenhouse, while accumulating and additional use of part of the incoming energy. Thanks to this, the efficiency of using the greenhouse is increased.

Information sources.

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Claims (1)

The greenhouse, including the foundation base, pitched translucent fences, the panels of which are facing south and are oriented in the possible direction of sunlight, the working passage on the rear heat-insulated panel and devices for heating and irrigation, the front and rear panels are framed by a frame made of electrically conductive material in the form of faces a quadrangular pyramid, the vertices of the base of which are oriented to the cardinal points and are grounded, while the panels and jumpers between them are made of dielectric material, wherein the top of the pyramid is equipped with a lightning rod and / or is electrically connected to the converter and the battery, an automatic control system for these devices, including at least one temperature and humidity sensor, the outputs of which are connected to part of the inputs of the arithmetic-logic device, configured to receive signals from sensors for comparing the received data with the control and issuing control signals to turn on the specified devices, the other part of the inputs of the arithmetic-logical device soy dinene with the outputs of a removable permanent storage device on which the program of the selected climatic zone and the program for growing the selected plant of this climatic zone are recorded, and the third part of the inputs is connected to the outputs of the position sensors of the elements of these devices, the inputs of which are connected through the automatic control system with the outputs of the arithmetic-logic device and the inputs of the display unit, characterized in that the pitched translucent fences along the lower perimeter are equipped with a polyethylene groove, with articulated with an irrigation system, pitched translucent fences in their lower part are equipped with cleaning brushes mounted on a telescopic device and driven by an electric drive connected to an automatic control system, along with rear panels above the ground multicultures are placed, the actuator of which is connected to an automatic control system and equipped with spray guns, which are connected by ceramic-metal tubes located inside the axis of the mult of the cultivator, with an irrigation device, the humidity sensor is made in the form of a mobile microwave device located in the extreme working bodies of the multicultural machine, light sensors are additionally introduced, the outputs of which are connected to the corresponding inputs of the arithmetic-logic device, pitched translucent fences on the inside are equipped with blinds, the actuator of which connected to an automatic control system.