RU2426302C2 - All-weather greenhouse - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: greenhouse includes multiple sectional parts from cellular polystyrene as a construction material of the greenhouse, assembling which forms a closed inner space for growing of plants, and also a door opening with a door for personnel entrance/exit. Neighbouring sectional peripheral walls are fixed to each other, have the specified dimensions, shape and extent of blowing for all-weather use. The greenhouse also comprises a lighting fixture and an plant for air conditioning.

EFFECT: increased strength of structure, quickness and ease of assembly.

13 cl, 13 dwg

Description

FIELD OF THE INVENTION

The present invention relates to an all-weather greenhouse for growing vegetables and fruits.

State of the art

A known system for growing (cultivating) crops for growing vegetables and fruits in enclosed spaces, such as a polyvinyl greenhouse or a growing plant (see, for example, document 1 below). Of these, in particular, the plant for growing withstands natural disasters and allows you to systematically grow plants by artificially regulating light, temperature, etc.

Document 1: Japanese Patent Application Laid-Open Hei-7-111828.

Disclosure of invention

Object of the invention

However, the construction of a growing factory is a laborious and expensive task.

Summary of the invention

The all-weather greenhouse proposed in the present invention can be assembled from a plurality of sectional parts made of polystyrene foam as a building material. From sectional parts, a greenhouse with an internal space for growing plants can be assembled. The greenhouse also has a lighting device and air conditioning.

From the segmented parts, a curved surface can be assembled, forming a predominantly semi-cylindrical enclosed space.

Any two adjacent segment parts are preferably joined end-to-end in the longitudinal direction by means of a reinforcing element.

The greenhouse can be installed by means of folded support blocks in the area where the greenhouse should be installed, and by connecting their lower ends.

It is preferable to use a reflective element that reflects light from the lighting device on the inner surface of the enclosed space.

Advantages of the Invention

Since the all-weather greenhouse proposed in the present invention can be assembled from a plurality of sectional parts made of polystyrene foam as a building material, large-scale on-site work is not required, as in the case of the construction of a growing plant, due to which the construction schedule can be reduced and costs can be reduced .

Brief Description of the Drawings

1 is a perspective view of an entire weatherproof greenhouse according to an embodiment of the present invention,

figure 2 is a perspective view with a spatial separation of the parts shown in figure 1 of the greenhouse,

figure 3 is a view in vertical section illustrating the stage of assembly in the peripheral direction of the greenhouse,

figure 4 is an enlarged view of part IV shown in figure 3,

figure 5 is an enlarged view of the part V shown in figure 3,

in Fig.6 (a) is a perspective view illustrating the assembly stage in the anteroposterior direction of the greenhouse, in Fig.6 (b) is a cross-sectional view along the line VI-VI in Fig.2 and in Fig.6 (c) - improvement scheme,

Fig.7 (a) is a view in cross section along the line VII-VII in Fig.1 and Fig.7 (b) is an enlarged view of its main part,

on Fig is a view in cross section along the line VIII-VIII in figure 1,

Fig.9 is a top view of the internal structure of the greenhouse according to the present invention and

10 is a plan view illustrating air flow in a greenhouse according to the present invention.

Explanation of Digital Positions

11, 21 - sectional part

30 - support block

50 - H-profile steel beam

105 - a chamber for growing

210, 211 - lighting

220 - air blower

230 - air conditioning unit

Preferred Embodiment

Next, with reference to FIGS. 1-9, an embodiment of an all-weather greenhouse proposed in the present invention is described.

First, we explain the form of the all-weather greenhouse as a whole. 1 shows a perspective view of a greenhouse 1 according to an embodiment of the present invention. Figure 2 shows a perspective view with a spatial separation of the parts shown in figure 1 of the greenhouse. It should be noted that hereinafter, for convenience, the front, rear, left and right sides correspond to those shown in the drawings.

As shown in figure 1, the greenhouse 1 includes a semi-cylindrical peripheral wall 10 extending in the anteroposterior direction, and the front and rear walls 20 are predominantly semi-disk-shaped, which overlap the front and rear ends of the peripheral wall 10. The greenhouse 1 generally has a so-called tunnel (arched ) form.

As shown in FIG. 2, the peripheral wall 10 is assembled from a plurality of arched sectional peripheral walls 11. Each sectional peripheral wall 11 includes three sectional parts 11a-11c. Sectional peripheral walls 11a-11c are in contact with each other and bonded to each other in the longitudinal axial direction. The front and rear walls 20 include one sectional part 21. It should be noted that the front and rear walls 20 can be made by assembling from a variety of sectional parts. The width of the greenhouse 1 in two rows is the support blocks 30 described in detail below, on which the lower ends of the peripheral wall 10 are supported. The size of one greenhouse 1 is on the order of, for example, from 5 to 10 m in width (in the transverse direction), from 20 to 50 m in depth (in the longitudinal direction) and from 3 to 5 m in height.

Each of the sectional parts 11a-11c and 21 is a polystyrene molded product with a 10-50-fold degree of blowing and a thickness of 10-50 cm. For example, in places where the snow cover reaches almost 80 cm, polystyrene sectional parts can be used with a 20-fold degree of blowing and a thickness of 20 cm. It should be noted that to ensure the same strength, the sectional part of expanded polystyrene with a higher degree of blowing should have a greater thickness. In areas where snow accumulation is not required, expanded polystyrene may have a 20-fold or higher degree of inflation or a reduced thickness of 20 cm or less. In contrast, in areas where the snow depth is 1 m or more, expanded polystyrene must have a more than 20-fold degree of inflation or increased thickness to ensure strength. Expanded polystyrene of this kind has an excellent light-blocking effect to cut off incoming light from the outside.

Sectional parts 11a-11c and 21 are prefabricated at the factory and assembled on site. The sizes of the sectional parts 11a-11c and 21 are selected taking into account the possibility of their transportation and assembly. Since the sectional parts 11a-11c and 21 are made of polystyrene foam, they are lightweight and easy to transport and assemble. The sectional part 21 is preformed with an opening 22 for entering the greenhouse 1, to which an opening and closing door 23 is attached (Fig. 1).

Figure 3 shows a view in vertical section illustrating the stage of assembly of the sectional peripheral wall 11, divided into three parts. Figure 4 shows an enlarged view of part IV shown in figure 3. Figure 5 shows an enlarged view of the part V shown in figure 3. As shown in FIG. 4, a protrusion 111 is located at the upper end of the sectional part 11a, and a recess 112 facing the sectional part 11a is located at the lower end of the sectional part 11b. The protrusion 111 enters the recess 112, and in this position, the sectional parts 11a and 11b are connected and fastened to each other. Although not shown, the sectional parts 11b and 11c are connected and bonded to each other in a similar way.

As shown in FIG. 2, on the ground in two rows at a distance equal to the width of the greenhouse 1, a plurality of support blocks 30 are arranged. Each support block 30 is predominantly U-shaped in cross section, as shown in FIG. 5, wherein the lower portion of each sectional part is included in the U-shaped portion of the support block 30. The support block 30 is made of concrete. Figure 2 shows that part of the support block 30 is underground for mounting the support block 30 in place. The lower end of the sectional part 11a is attached to the support block 30 with a mortise bolt 31, which horizontally penetrates into the support block. Although not shown, the lower part of the sectional part 11c is likewise attached to the support block 30. This allows the greenhouse 1 to be installed in place by the support block 30.

A foam base 41 is laid between the left and right support blocks 30, on top of which the flooring concrete 42 is poured. The flooring concrete 42 is coated 43 to make the surface of the flooring in the greenhouse 1 smooth, without any irregularities. A reflective element 44, which may be, for example, aluminum foil, is applied to the inner surface of each of the sectional parts 11a-11c. Since aluminum foil reflects not only light but also heat, constant temperature conditions can be maintained inside the greenhouse 1. It should be noted that instead of aluminum foil, an aluminum sheet may be used. The aluminum sheet can be easily used since the greenhouse 1 has an arched shape. After forming the sectional parts 11a-11c, a reflective element 44, such as an aluminum sheet, is preferably first placed in the molding machine and formed as a unit with the sectional parts 11a-11c. In order to improve the various properties of the greenhouse 1, such as fire resistance, fire resistance, weather resistance, water resistance, strength and sound insulation, a coating material 45 is applied to the outer surface of each of the sectional parts 11a-11c, such as tar concrete, including concrete and mixed with it polymer. It should be noted that to improve the adhesion of the resin concrete, it is preferable that the greenhouse has a rough surface, and therefore the surfaces of the sectional parts 11a-11c give an uneven shape.

Fig. 6 (a) is a perspective view illustrating the stage in which the sectional peripheral walls 11 are connected in the anteroposterior direction; Fig. 6 (b) is a cross-sectional view of the connected section (along line VI-VI in Fig. 2 ) Between any two adjacent sectional parts 11a, a predominantly rounded H-profile steel beam 50 is placed along the contour of the greenhouse. The lower end of the H-profile steel beam 50 together with the sectional part 11a as a whole is inserted with the mortise bolt 31 (Fig. 5) to the support block 30. At the front and rear ends of each sectional part 11a, recesses 113 and 114 are provided for the H-profile steel beam 50, by which adjacent sectional parts 11a are connected and fastened to each other. Although not shown, adjacent sectional parts 11b or adjacent sectional parts 11c are similarly connected to each other by an H-profile steel beam 50. Thus, the H-profile steel beam 50 acts as a reinforcing element of the greenhouse 1, increasing its strength as a whole. Due to this, a greenhouse several tens of meters long can be assembled from the sectional peripheral walls 11 or the greenhouse 1 can be installed where there is a lot of snow.

If the greenhouse 1 does not require such high strength (for example, in the absence of snow cover), a plate 51, shown in FIG. 6 (c), can be used instead of the H-shaped steel beam 50 to connect the sectional parts 11. Although not shown, a reinforcing element, such as an H-profile steel beam 50 or plate 51, is also used to connect the sectional peripheral wall 11 and the sectional part 21.

Unlike a polyvinyl greenhouse, expanded polystyrene greenhouse 1 as a building material has high strength and is able to withstand natural disasters such as earthquakes and typhoons. In addition, even if cracks form on the surface of the greenhouse as a result of an earthquake, or a partial deformation of the surface of the greenhouse occurs as a result of collision with any object in the typhoon stream, it can be easily restored. Compared to conventional buildings or glass greenhouses, the greenhouse 1 proposed in the present invention is less prone to collapse, and there is no danger of broken glass getting into the greenhouse, since glass is not used on its surface. In addition, since the walls are of sufficient thickness, even in the case of any impact on the walls, it will not reach the inside of the greenhouse. In addition, there is no danger of damage to the plantings, because unlike the polyvinyl of ordinary polyvinyl greenhouses, the polystyrene foam of the greenhouse 1 does not deform and does not collapse under the influence of wind.

Since polystyrene foam has excellent thermal insulation properties and a shielding effect, it makes it easy to regulate the conditions for growing plants (vegetables and fruits), that is, temperature, humidity, duration of light exposure, etc. and get a stable crop regardless of external weather conditions. When implementing the present invention in the form of a collapsible greenhouse, the installation of the greenhouse 1 can be carried out faster and at a lower cost than the construction of a room for growing. In addition, the use of the reflecting element 44 can improve the efficiency of light irradiation of cultivated plants and reduce the number of places of installation of light sources.

The following describes an example of an all-weather greenhouse assembly procedure 1. First, as shown in FIG. 2, support blocks 30 are laid at the greenhouse assembly site 1. Then a reinforcing element (for example, an H-shaped steel beam 50) is set to a position corresponding to the front side of the greenhouse 1 , and combine the front end of the recess 114 of each of the sectional parts 11a-11c with the H-profile steel beam 50. In this position, the lower end of the H-profile steel beam 50 and the lower end of the sectional parts 11a, 11c are fixed with mortise (through) bolts 31 to the supporting bl 30. After that, any two adjacent sectional parts from the sectional parts 11a-11c are connected to each other in the peripheral direction by means of a recess 112 and a protrusion 111 and fastened to each other, as a result of which a sectional peripheral wall 11 is formed. Then, into the recess 113 on the back At the end of the assembled sectional peripheral wall 11, an H-profile steel beam 50 is inserted. The operation of connecting the sectional peripheral walls 11 to each other by means of H-profile (I-beam) steel beams 50 is repeated until the greenhouse will reach the specified length.

After the greenhouse reaches a predetermined length, a foam base 41 is laid between the left and right support blocks. Then, flooring concrete 42 is poured on top of it and coating 43 is applied to the upper surface of the flooring concrete 42. Next, a reflective element 44 is installed on the inner surface of the greenhouse 1, and on the outer surface of the greenhouse 1 apply coating material 45. After that, using heavy equipment, large components or finished products are imported, such as growth frames 200 (Fig. 7), and by means of an H-shaped steel beam 50, the sectional part 21 is connected to the sectional peripheral wall 11 on the front and rear end surfaces of the greenhouse 1 As a result, the front and rear end surfaces of the greenhouse 1 form a closed space, protected from external influences. It should be noted that to simplify assembly operations, a reflective element 44 is pre-installed in the factory on the sectional parts 11a-11c and coating material 45 is applied to the reflective element 44.

Further, by the example of growing strawberries in a greenhouse 1, its internal structure is described. 7 shows a cross-sectional view along the line VII-VII. On Fig shows a view in cross section along the line VIII-VIII in figure 1. Figure 9 shows a top view. The internal structure of the greenhouse 1 is illustrated in these drawings. As shown in FIG. 9, the interior of the greenhouse is divided into a windproof chamber 101, a blower chamber 102, a locker room / preparation chamber 103, a sterilization chamber 104, and a growth chamber 105.

In the growth chamber 105, a plurality of growth frameworks 200 are installed. For example, three sets of widths and two sets of lengths are installed, a total of six sets of frames 200. As shown in FIG. 7 (a), each growth frame 200 is predominantly A-shaped in cross section, and mounted on its inclined surfaces cylindrical grooves 201 extending in the anteroposterior direction. The gutters 201 are mounted on a plurality of levels (five levels in FIG. 7 (a)) one above the other, that is, the growth frames 200 are multi-level growth frames.

As shown in FIG. 7 (b), a pot 203 is installed in each receiving section 202 on the upper surface of the trough 201 in which strawberries are grown. A pipe 204 is connected to the front and rear ends of the trough 201, through which liquid fertilizer is supplied to the trough 201 by means of a pump (not shown). The supplied liquid fertilizer enters the lower surface of the gutter 201 and then returns to the reservoir. Then the liquid fertilizer is again fed into the chute 201 through the nozzles 204. This allows the liquid fertilizer to be pumped through a closed system inside the chute 201 and to supply strawberries with water and nutrients necessary for growing through the pot 203. Since water and nutrients in the described manner enter the nozzles 204 and the gutter 201, there is no need to irrigate the chamber with water. Accordingly, since there is no need for water tanks and outlets, the penetration and spread of microorganisms can be prevented.

A plurality of lighting lamps 210 (e.g., fluorescent lamps) are attached to the inner surface of the walls of the greenhouse to irradiate strawberries with light. Lighting lamps 211 are also attached to the inside of each growing frame 200. In addition, as mentioned above, the entire inner surface of the greenhouse is covered with a reflective element 44. Due to this, light emitted in any direction enters the frame 200 for growing strawberries, which allows receive homogeneous fruits of high quality. In this case, the cultivation of strawberries can be accelerated by appropriate regulation of illumination and the duration of exposure to light.

As shown in FIGS. 7 (a) and 8, an air blower 220 is attached to the ceiling of the growth chamber 105, while the air flow is controlled so that outside air is not directly drawn into the growth chamber. This prevents the entry of microorganisms and insects. In addition, in the growing chamber 105, there is an air conditioning unit 230 (air conditioning) to maintain the temperature and humidity conditions within the chamber suitable for growing strawberries. 10 is a plan view schematically illustrating flow in a growing chamber 105. As shown in FIG. 10, in order to maintain a constant atmosphere in the growth chamber 105, air is circulated in the growth chamber 105, as indicated by arrows. Since the ceiling of the growing chamber 105 has an arched shape, air stagnation is reduced and a constant atmosphere can easily be maintained inside the chamber. In addition, since expanded polystyrene has excellent thermal insulation properties, it is easier to provide air conditioning in greenhouse 1 than in a concrete growing room. Thus, due to the use of expanded polystyrene, the greenhouse has high cooling capacity and heat capacity.

The arrangement of the respective cameras 101-105 is indicated in FIG. 9 by arrows. Thus, the staff first enters the windproof chamber 101, and then the blowing chamber 102, in which dust adhering to the body is removed with a stream of air, etc. Then they enter the locker room / preparatory chamber 103, in which the staff takes a set of work clothes for training. In the sterilization chamber 104, the whole body is disinfected, after which personnel enter the growth chamber 105. This procedure prevents the entry of microorganisms and insects from the outside when personnel enter the growing chamber 105, thereby maintaining acceptable hygienic conditions.

In addition, the inner surface of the greenhouse 1 as a whole has a curved shape from top to bottom and has fewer uneven areas, due to which dust and microorganisms do not accumulate in the greenhouse and a highly hygienic space is provided in the chamber. Lighting lamps 210 may be recessed into the inner surface of the sectional parts 11a-11c. This prevents the uneven surface of the mounting parts of the lighting lamps 210, which is preferred from the point of view of hygiene.

The embodiment described above provides the following advantages.

1. Since the greenhouse 1 can be assembled from sectional parts 11a-11m and 21 made of polystyrene foam as a building material, the greenhouse 1 as a whole can be covered with expanded polystyrene of considerable thickness, thereby ensuring sufficient strength of the greenhouse 1. In addition, it is not required carrying out large-scale work on site, as in the case of the construction of a premises for growing, due to which the construction schedule can be reduced and costs can be reduced. Thus, since the greenhouse 1 is constructed by assembling the sectional parts 11a-11c and 21, it is only necessary to assemble the prefabricated sectional parts 11a-11c and 21 in place, which simplifies on-site operations. The assembly does not require special technology, so it can be easily done by lay people.

2. Since polystyrene foam is used as the building material, greenhouse 1 has excellent thermal insulation properties and a shielding effect, and an atmosphere suitable for growing plants can be effectively maintained inside the greenhouse. In addition, since expanded polystyrene is a lightweight material, it is easy to transport and assemble. It can also be easily reused.

3. Since the greenhouse 1 can be assembled by adding sectional peripheral walls 11 to obtain an elongated structure, any desired size corresponding to the configuration of the earth's surface can be selected for the greenhouse 1.

4. Since adjacent sectional peripheral walls 11 are connected to each other by H-shaped steel beams 50, they serve as reinforcing elements, giving the greenhouse additional strength. Thus, greenhouse 1 can be used in areas with high snow cover.

5. Since the sectional peripheral walls 11 are connected to each other by means of recesses 113 and 114 on both end surfaces of each sectional peripheral wall and the H-shaped steel beams 50 placed therein, the H-shaped steel beam is hidden, and the entire surface of the greenhouse 1 can be covered with polystyrene foam.

6. Since greenhouse 1 rests on support blocks that are laid in place, it is not necessary to build a foundation, as in the case of conventional buildings, and greenhouse 1 can be built in a relatively short time. In addition, since the sectional part 11a, 11c and the H-shaped steel beam 50 are integrally attached to the support block 30 by a bolt 31, the number of fastening points by the bolts 31 is relatively small, thereby simplifying the operation. The operations of moving and removing the greenhouse 1 are also relatively simple.

7. Since a reflecting element 44 is applied to the inner surface of the greenhouse 1, light is reflected from the reflecting element 44, and growing on multi-level frames 200 can be carried out without using a plurality of lighting lamps 210.

It should be noted that in the above embodiment, the greenhouse 1 has an arched shape with a closed inner space of a predominantly semi-cylindrical (approximately arched) shape. However, since the greenhouse 1 can be assembled from a plurality of sectional parts, its shape is not limited to the above, and the shape of the sectional parts is not limited to the above. For example, a greenhouse as a whole may be in the form of a hemisphere or a rectangular parallelepiped. On a side wall assembled from sectional parts, a roof assembled from sectional parts can be placed.

In the embodiment described above, an example of growing strawberries in a greenhouse 1 is provided. However, other fruits, vegetables, mushrooms and the like can be grown in greenhouse 1. When growing mushrooms, it is preferable to adjust the lighting conditions and the atmosphere so that the greenhouse is relatively dark and high humidity is maintained. In addition to edible plants, flowers can be grown in the greenhouse.

In the above-described embodiment, an H-profile steel beam 50 or plate 51, as a reinforcing element, is inserted into the anteroposterior direction between adjacent sectional parts. However, the shape of the reinforcing element is not limited to that described. The reinforcing element may not be used. The reinforcing element can be inserted into the connecting portion between adjacent sectional parts, not only in the anteroposterior, but also in the peripheral direction. In the above embodiment, for growing in a greenhouse, multilevel frames 200 are installed. However, the design of the interior of the greenhouse is not limited to those described above. Since greenhouse 1 has a large width and height, a cultivator or soil milling cutter can be used in it to mechanically till the soil in the greenhouse.

Despite the fact that the greenhouse 1 is designed to install on the support blocks 30 a predominantly U-shaped cross section, the shape of the support block is not limited to that described. For example, the sectional parts 11a and 11c may have a recess or protrusion at the bottom, and the support block may be aligned with the recess or protrusion. The installation location of the greenhouse 1 is not limited to the ground. Greenhouse 1 can be installed, for example, on the roof. It is also possible to install many greenhouses 1 and grow various plants in various greenhouses. Alternatively, a single greenhouse may have multiple growing chambers 105, and various plants may be grown in various growing chambers.

Thus, with regard to the implementation of the features and functions of the present invention, it is not limited to an all-weather greenhouse according to the embodiment described above. It should be noted that the above description is merely illustrative, and in interpreting the present invention, the correspondence relationship between the described embodiment and the accompanying claims should not be limited.

Claims (13)

1. An all-weather multi-section greenhouse containing a lighting device and an air conditioning unit, as well as a doorway with a door for personnel entry / exit, characterized in that it includes many sectional parts made of polystyrene foam as a building material of the greenhouse, during the assembly of which a closed internal space is formed for growing plants, while adjacent sectional peripheral walls are bonded to each other, have a given size, shape and degree of inflation for all-weather use Ania. 2. An all-weather greenhouse according to claim 1, characterized in that each of the sectional parts has a curved surface, and the enclosed space has a predominantly semi-cylindrical shape. 3. The all-weather greenhouse according to claim 1, characterized in that any two sectional parts of the sectional parts are butt-joined in the longitudinal direction by means of a reinforcing element. 4. The all-weather greenhouse according to claim 1, characterized in that it further includes supporting blocks stacked at the installation site of the all-weather greenhouse, wherein the all-weather greenhouse is adapted to be mounted on supporting blocks in the place where the all-weather greenhouse is to be installed, and aligned with the lower ends of the sectional parts with support blocks. 5. The weatherproof greenhouse according to claim 1, characterized in that it further includes a reflective element deposited on the inner surface of the enclosed space to reflect light from the lighting device. 6. The weatherproof greenhouse according to claim 5, characterized in that the reflective element is aluminum foil or aluminum sheet. 7. An all-weather greenhouse according to claim 4, characterized in that it further includes fasteners for attaching the lower ends of the plurality of sectional parts to the support blocks. 8. The weatherproof greenhouse according to claim 1, characterized in that the end surfaces of any two adjacent sectional parts from the plurality of sectional parts are fastened and connected to each other. 9. An all-weather greenhouse according to claim 1, characterized in that the outer surface of the plurality of sectional parts is covered with weather-resistant material. 10. The weatherproof greenhouse according to claim 1, characterized in that it further includes at least one frame for growing crops in a confined space. 11. An all-weather greenhouse according to claim 10, characterized in that it further includes a lighting device attached to the inside of at least one frame for growing. 12. An all-weather greenhouse according to claim 1, characterized in that it further includes a plurality of spaces in the greenhouse isolated from the enclosed space, wherein at least one space from the plurality of spaces isolated from the enclosed space is between the doorway and the enclosed space. 13. An all-weather greenhouse according to claim 9, characterized in that the weather-resistant material contains resin concrete, and the surface of the sectional parts has irregularities to improve the adhesion of the resinous concrete with sectional parts.

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