RU177510U1 - GREENHOUSE - Google Patents

Abstract

The utility model relates to the agricultural industry and can be used in specialized farms, on household plots and cottage plots for growing plants. The technical problem is a more uniform distribution of the interior of the greenhouse relative to the height of the pyramid and a decrease in the number of direct and refracted (on the edges of the pyramid) sunlight entering the soil inside the greenhouse. The technical problem is solved by optimizing the design of the frame. The technical result is more uniform distribution of the interior of the greenhouse along the height and elimination of the penetration of part of direct and refracted sunlight on the soil inside the greenhouse. This part of the sun's rays passes through the greenhouse. As a result, the volume of the inner space of the greenhouse is uniformly warmed up and a certain degree of illumination throughout the volume is maintained at all stages of plant growth, there is also no overheating of the soil inside the greenhouse. The technical result is achieved in that in a greenhouse containing a parallelepiped-shaped square frame with a square the base and the pyramid installed on top, the height of the pyramid B is from 0.9 to 1.1 of the length of the side of the square base A, while the B / B ratio is in the range azone from 1.4 to 1.7, where B is the height of the parallelepiped. Thus, the use of the greenhouse, with the indicated size ratios, allows you to uniformly warm up the volume of the inner space of the greenhouse and maintain a certain degree of illumination throughout the volume at all stages of plant growth.

Description

The utility model relates to the agricultural industry and can be used in specialized farms, in household plots and cottage plots for growing plants.

A known greenhouse is RF patent No. 2550654, which includes a foundation base, pitched translucent fences, the panels of which are facing south and oriented in the possible direction of sunlight, the working passage on the rear heat-insulated panel and the device for heating and irrigation, characterized in that the front and rear panels are framed a frame made of an 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, with panels and jumpers between they are made of dielectric material.

Disadvantages:

1. Not a safe design for personnel during a thunderstorm.

2. Orientation of the vertices of the base to the cardinal points does not allow to accumulate and use the energy of the electromagnetic field of the earth, as the magnetic poles are constantly moving and their location is different from the location of the poles of the Earth.

Novelty:

The aspect ratio is not indicated, which also does not allow the efficient use of cosmic energy, and the energy generated by the Earth.

A known greenhouse is RF patent No. 20816 (prototype), comprising a frame with a rectangular base for filling with soil and a side surface with faces made of translucent material inclined to the base, characterized in that the base has the shape of a square, and the faces the shape of triangles converging at one vertex with the formation of a regular pyramid, with a / b 1.4-1.6, where a is the length of the side of the square, and b is the height of the pyramid. The pyramid is raised above the base by 0.7-0.9 m.

Disadvantages:

Due to the ratio of a / b, in the range 1.4-1.6, the main volume of the internal space of the greenhouse is at the base of the pyramid, and the faces of the pyramid are turned more toward the base (horizontally) rather than to the height (vertically) all this leads to the initial the period of plant growth to overheating of the soil due to direct and refracted (on the edges of the pyramid) sunlight. Also in such a greenhouse it is inconvenient and difficult to grow tall plants more than 1 meter because of the small amount of space located at the top of the pyramid.

Novelty:

The ratio a / b is 1.4-1.6, where a is the length of the side of the square, and c is the height of the pyramid. The pyramid is raised above the base by 0.7-0.9 m. Based on figure 2, the height includes the height of the pyramid and parallelepiped, which contradicts the formula. But even so we get the following: the height of the pyramid is much less than the length of the side of the square, the ratio of the height of the pyramid to the height of the parallelepiped is unknown.

The technical problem is a more uniform distribution of the interior of the greenhouse relative to the height of the pyramid and a decrease in the number of direct and refracted (at the edges of the pyramid) sunlight that hits the soil inside the greenhouse.

The technical problem is solved by optimizing the design of the frame.

The technical result consists in a more uniform distribution of the interior of the greenhouse along the height and elimination of the ingress of part of direct and refracted sunlight to the soil inside the greenhouse. This part of the sun's rays passes through the greenhouse. As a result, the volume of the internal space of the greenhouse is uniformly warmed up and a certain degree of illumination is maintained at all stages of plant growth throughout the volume, there is also no overheating of the soil located inside the greenhouse.

The technical result is achieved by the fact that in a greenhouse containing a frame covered with translucent material in the form of a parallelepiped with a square base and a pyramid mounted on top, the height of the pyramid B is from 0.9 to 1.1 of the side length of the square base A, while the B / B ratio is in the range from 1.4 to 1.7, where B is the height of the box.

Proof of the materiality of the signs:

The volume of the pyramid V (Pr) is equal to one third of the product of the base area of the pyramid S (Pr) by the height of pyramid B.

The volume of the parallelepiped V (P) is equal to the area of the base of the parallelepiped S (P) by the height of the parallelepiped S (P).

The area of the base of the pyramid S (Pr) is equal to the area of the base of the parallelepiped S (P).

Due to the fact that the W / B ratio is in the range from 1.4 to 1.7, we obtain the V (Pr) / V (P) ratio equal to from 0.46 to 0.56, thereby the volume of the pyramid is more than a third the volume of the internal space of the greenhouse, which allows you to grow tall plants (for example cucumbers) in comfortable conditions for both plants and staff serving the greenhouse.

Due to the fact that the height of the pyramid B is from 0.9 to 1.1 of the side length of the square base A, it turns out that the inclined face of the pyramid (the hypotenuse of the triangle, which is the projection of the pyramid from the side) is approximately at an angle of 60 degrees to the horizontal and approximately 30 degrees to the vertical, this compared with the prototype makes the pyramid higher and due to the W / B ratio in the range from 1.4 to 1.7, the number of direct and refracted sunlight falling on the soil inside the pyramid is reduced compared to proto type, therefore, overheating of the soil in the initial period of plant growth is eliminated. Elimination of soil overheating inside the greenhouse reduces the amount of evaporated water from the soil, which leads to a more uniform and balanced microclimate inside the greenhouse.

The greenhouse, made according to the above ratios, is higher compared to the prototype, which allows you to grow tall plants, providing plants with sufficient light and temperature throughout the entire height of the greenhouse.

Proof of Novelty:

None of the known sources of information contain the ratios of the size of the greenhouse indicated in the formula. Thanks to precisely these ratios of the size of the greenhouse, the volume of the internal space of the greenhouse is heated uniformly and a certain degree of illumination is maintained throughout the volume.

The figure 1 shows the projection of the greenhouse from the side, where the length of the side of the square base A, the height of the parallelepiped B, the height of the pyramid B.

The figure 2 shows a three-dimensional model of the frame of the greenhouse, where the frame 1 of the parallelepiped and the frame 2 of the pyramid are indicated.

The greenhouse is assembled as follows:

First, the frame of the parallelepiped 1 is assembled, then the frame of the pyramid 2 is separately assembled. After that, the surface is prepared on the land plot - it is leveled. Next, the frame of the parallelepiped 1 is installed on the prepared surface, after which the frame of the pyramid 2 is attached to it from the top. Then both frames 1 and 2 are covered with translucent materials (not shown in the figures). It is convenient to use a plastic film as a translucent material. On one side, the film is not fixed firmly; this side is used as a door.

As the material of the frame of the greenhouse, you can use wood or metal (for example, aluminum). As a translucent material, polycarbonate can be used. To increase the durability of the greenhouse on the prepared surface, you can fill the foundation and install the frame of the greenhouse on it.

Using:

Plants can be grown by known methods. A distinctive feature of the design of this greenhouse is that in the initial period of plant growth (when the leaves of the plants do not obscure the soil), the soil inside the greenhouse does not overheat. Subsequently, as the mass of the plant increases (growth in height and increase in the surface of leaves) in the greenhouse at all heights, the optimum temperature and illumination are maintained.

Thus, the use of the greenhouse, with the indicated size ratios, allows you to uniformly warm up the volume of the inner space of the greenhouse and maintain at all stages of plant growth a certain degree of illumination throughout the volume.

Claims (1)

A greenhouse containing a frame covered with translucent material in the form of a parallelepiped with a square base and a pyramid mounted on top, characterized in that the height of the pyramid B is from 0.9 to 1.1 of the side length of the square base A, while the B / B ratio is in the range from 1.4 to 1.7, where B is the height of the box.

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