KR101063554B1 - Construction method of variable green house structure - Google Patents

Abstract

The present invention relates to a method for constructing a variable greenhouse structure, wherein a vertical cell formed in a rectangular shape is movable up and down by a guide and a cylinder, and automatically adjusts the temperature inside the greenhouse structure, during weather worsening due to typhoons or snow, or energy. The present invention relates to a method for constructing a variable greenhouse structure capable of controlling the volume of an interior for savings.
The present invention provides an effect that can control the greenhouse structure without a great effort by automating the variable of the greenhouse structure due to the aging of the rural population, by automatically opening and closing the greenhouse structure according to the climatic conditions, the summer temperature is high It is possible to save energy by reducing the volume of the room by completely opening or lowering the height at the time of winter and low temperature, and maintenance is effective by replacing only the broken cell during partial damage of the greenhouse structure.
In addition, when strong wind pressure is generated, it lowers the height of the greenhouse structure and increases the wind direction by the operation of the wind pressure control unit provided outside to reduce the damage of the greenhouse structure, thereby providing the effect of preventing disasters such as typhoon damage, In addition, it provides the effect of maintaining the proper volume by varying the greenhouse structure according to the purpose, such as the type of livestock or the temperature control of day and night.

Description

Construction method of variable green house structure

The present invention relates to a method for constructing a variable greenhouse structure, wherein a vertical cell formed in a rectangular shape is movable up and down by a guide and a cylinder, and automatically adjusts the temperature inside the greenhouse structure, during weather worsening due to typhoons or snow, or energy. The present invention relates to a method for constructing a variable greenhouse structure capable of controlling the volume of an interior for savings.

The conventional vinyl house has a structure in which a plurality of arch-shaped frames are arranged in a rib shape at regular intervals and connected to each other by horizontal frames to fix them, and then cover the outside with vinyl.

In addition, during the winter season, the inside of the vinyl is covered with a thermal insulation film to keep the inside temperature constant, and in summer, both sides of the vinyl house are opened and closed to prevent the internal temperature from rising. .

In addition, since the vinyl is installed in a double and ground water is injected into the inner vinyl to form a water film, a method of lowering the heat inside the house through the ground water is used.

However, the conventional vinyl house is provided to maintain the internal temperature at the optimum temperature for plant growth, but when the external temperature is optimal, such as in summer, even if both sides of the vinyl house are opened, the temperature is higher than necessary. There is a high rise or poor room temperature control, which can cause crop failure or damage.

In addition, the vinyl house has a problem in that the vinyl is weakly oxidized and corroded in the summer, and the transparency is reduced, so that it does not absorb the sun properly in the winter, which adversely affects the growth of crops.

In addition, there is a problem that the crop is damaged due to the collapse or flying of the weak vinyl and the frame due to bad weather such as typhoons or snow.

In addition, there is a problem that the installation and maintenance of the plastic house is difficult due to the aging of the agricultural population.

The present invention is to solve the above problems, it is an object of the construction on the ground by automating the variable of greenhouse structures due to the aging of the rural population.

In addition, by automatically opening and closing the greenhouse structure in accordance with the climatic conditions, when the summer temperature is high or low, the purpose of maintaining the internal temperature to maintain the proper temperature by fully opening or lowering the structure.

In addition, it is an object of the user to provide a simple maintenance by replacing only the damaged cells when the partial damage of the greenhouse structure.

In addition, the broken cell is intended to be made of glass or plastic material to be recycled after replacement.

In addition, when strong wind pressure is generated, the purpose of reducing the greenhouse structure by lowering the greenhouse structure and by increasing the wind direction by the operation of the wind pressure controller provided on the outside.

In addition, the purpose is to provide an appropriate volume by varying the greenhouse structure according to the type and purpose of crops or livestock.

The present invention for achieving the above object in the construction method for installing a variable greenhouse structure (10) for growing crops or raising livestock, the construction method perforated to form a first vertical frame insertion groove 220 in the ground Step S100;

In order to embed the vertical frame cylinder 400, roof frame cylinder 410, wind pressure cylinder 411 on the ground, vertical frame cylinder groove 200, roof frame cylinder groove 210, wind pressure cylinder cylinder groove ( 211) drilling step (S200);

The vertical frame cylinder groove 400, the roof frame cylinder groove 210, and the wind pressure regulator cylinder groove 211 are installed in the vertical frame cylinder 400, the roof frame cylinder 410, and the wind pressure regulator cylinder 411. Step (S300);

The cylinder case 300 is installed on the ground, and the installation step of fixing the flexible pipe 412 to the upper surface of the first vertical frame 100 and the cylinder case 300 in the first vertical frame insertion groove 220 (S400). ;

Coupling a second vertical frame (110) and a third vertical frame (111) coupled to the installed first vertical frame (100) (S500);

The first vertical frame 100, the second vertical frame 110, the third vertical frame 111 is coupled, the upper surface of the third vertical frame 111 and the bottom of the roof frame 112 is coupled (S600) It is characterized by including the configuration.

In addition, the step of drilling the first vertical frame insertion groove 220 (S100) is to form a first vertical frame insertion groove 220 to fix the first vertical frame 100 to the ground in accordance with the crop cultivation or livestock size. It is characterized by.

In addition, the vertical frame cylinder groove 200, the roof frame cylinder groove 210, the wind pressure adjusting cylinder cylinder 211 drilling step (S200) is the vertical frame cylinder 40 and the roof frame cylinder 410, wind pressure adjusting table The groove is formed so that the cylinder 411 is partially embedded.

In addition, the vertical frame cylinder 400, the roof frame cylinder 410, the wind pressure adjusting cylinder 411 installation step (S300) is the vertical frame cylinder groove 200, roof frame cylinder groove 210, wind pressure adjusting table Part of the cylinders 400, 410, 411 are embedded in the groove formed in the drilling step (S300) of the cylinder groove 211, it is characterized in that the anchor bolt 40 is fixed to the groove bottom surface.

In addition, the cylinder case 300, the first vertical frame 100, the flexible pipe 412 in the installation step (S400), the cylinder case 300 is a fixed plate 50 is formed on the lower outer side anchor bolt (40) It is fixed to the ground, the first vertical frame 100 is inserted into the first vertical frame insertion groove 220, a plurality of fixing plate 50 is formed in the lower side of the first vertical frame 100, the anchor bolt ( 40) is fixed to the ground.

In addition, the rubber protrusion 130 is formed on the outer surface of the first vertical frame 100 fixed to the ground by the anchor bolt 40 in the second vertical frame 110 and the third vertical frame 111 coupling step (S500). The transfer guide 121 formed on the outer side of the second vertical frame 110 and coupled to the second vertical frame guide groove 230 formed in the cylinder case 300 by being in close contact with the inside of the second vertical frame 110. And it is characterized in that coupled to the transfer projection 120 formed on the lower inner surface of the third vertical frame (111).

In addition, in the coupling step (S600) of the third vertical frame 111 and the roof frame 112, the insulation groove 150 formed on the upper surface of the third vertical frame 111 and the insulation projection formed on the lower surface of the roof frame 112. The 140 is coupled to maintain the internal temperature.

The present invention provides the following effects.

The present invention relates to a variable greenhouse structure, and provides an effect that can control the greenhouse structure without great effort by automating the variable of the greenhouse structure due to the aging of the rural population.

In addition, by automatically opening and closing the greenhouse structure according to the climatic conditions, it provides an efficient energy efficiency by fully opening or lowering the height when the summer temperature is high and the winter temperature is low.

In addition, maintenance is effective by removing and replacing only broken cells during partial damage of the greenhouse structure, and the replaced cells are made of glass or plastic material to provide an effect of recycling.

In addition, when strong wind pressure is generated, it lowers the greenhouse structure and increases the wind direction by the operation of the wind pressure controller provided outside, thereby reducing the damage of the greenhouse structure, thereby providing an effect of preventing disasters such as typhoon damage.

In addition, by varying the greenhouse structure according to the type and purpose of crops or livestock, it provides the effect of the appropriate volume.

1 is a construction state diagram for a method for constructing a variable greenhouse structure according to the present invention.
Figure 2a, Figure 2b is a drilling step of the first vertical frame insertion groove for the construction method of the present invention variable greenhouse structure.
Figure 2c is a vertical frame cylinder, roof frame cylinder, wind pressure adjustment cylinder buried groove drilling step for the variable greenhouse structure construction method of the present invention.
Figure 2d is a vertical frame cylinder, roof frame cylinder, wind pressure adjustment cylinder buried and wind pressure adjustment step installation step for the variable greenhouse structure construction method of the present invention.
Figure 2e is a cylinder case, a first vertical frame and a flexible pipe installation step for the variable greenhouse structure construction method of the present invention.
Figure 2f is a coupling step with the first vertical frame after combining the second vertical frame and the third vertical frame for the construction method of the variable greenhouse structure of the present invention.
Figure 2g is a roof frame and the third vertical frame coupling step for the variable greenhouse structure construction method of the present invention.
Figure 3 is a cross-sectional view of the greenhouse structure for the present invention variable greenhouse structure construction method.
Figure 4 is a construction block diagram for the construction method of the present invention variable greenhouse structure.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a construction state diagram of the present invention, Figure 2 is a cross-sectional view of the greenhouse structure of the construction state diagram shown in Figure 1, Figure 3 is a construction flow diagram of the construction of the greenhouse structure of the construction state diagram shown in Figure 1, Figure 4 The construction block diagram for constructing the greenhouse structure of the construction state diagram shown in FIG.

The construction step of the greenhouse structure 10 according to the present invention comprises a first vertical frame insertion groove 220 drilling step (S100); Vertical frame cylinder 400, roof frame cylinder 410, wind pressure adjustment cylinder 411 buried groove drilling step (S200); Vertical frame cylinder 400, roof frame cylinder 410, wind pressure control cylinder 411 buried and wind pressure control unit 30 installation step (S300); Cylinder case 300, the first vertical frame 100 and the flexible pipe 412 installation step (S400); Combining the second vertical frame 110 and the third vertical frame 111 and then combining the first vertical frame 100 with the first vertical frame 100 (S500); Roof frame 112 and the third vertical frame 111 is made of a coupling step (S600).

The construction method will be described in detail with reference to the respective steps and drawings.

As shown in Figure 2a and 2b, the first vertical frame insertion groove 220 drilling step (S100) is a first vertical frame for fixing the first vertical frame 100 on the ground on which the greenhouse structure 10 is constructed The frame insertion groove 220 is formed.

As shown in Figure 2c, the vertical frame cylinder 400 and the roof frame cylinder 410, the wind pressure adjusting cylinder 411 to bury the ground to bury the vertical frame cylinder groove 200 and the wind pressure control cylinder groove ( 211) to form a roof frame cylinder 410, wind pressure adjusting cylinder 411 buried groove drilling step for forming a roof frame cylinder groove 210 for raising and lowering the roof frame 112 in the center (S200) Is done.

In addition, as shown in FIG. 2D, the vertical frame cylinder 400, the roof frame cylinder 410, and the wind pressure control cylinder 411 are partially embedded in the perforated grooves by drilling the ground, and the cylinders 400, 410 and 411. The anchor bolt 40 is fixed to the bottom surface to support the external wind pressure or the weight of the greenhouse structure 10.

In addition, the wind pressure control unit 30 is installed in the installed wind pressure control cylinder 411 vertical frame cylinder 400, the roof frame cylinder 410, the wind pressure control cylinder provided to change the direction of the wind direction 411 is made of buried and wind pressure control unit 30 installation step (S300).

In addition, each of the cylinders 400, 410, and 411 is installed, and as shown in FIG. 2E, the cylinder case 300 surrounds the vertical frame cylinder 400, and a fixing plate 50 is formed below the outer side of the cylinder case 300. Is fixed to the ground by the anchor bolt 40, the first vertical frame 100 is inserted into the first vertical frame insertion groove 220, a plurality of fixing plates 50 on the lower side of the outer side of the first vertical frame 100 Is formed is fixed to the ground by the anchor bolt (40), in order to protect the shaft of the vertical frame cylinder 400 from the outside of the cylinder case 300, the flexible tube 412 is coupled to the upper cylinder case 300, the first The vertical frame 100 and the flexible pipe 412 consists of the installation step (S400).

In addition, the first vertical frame 100 is installed, as shown in Figure 2f, a rubber protrusion 130 is formed on the outer upper surface of the first vertical frame 100 fixed to the ground by the anchor bolt 40, The inner side of the second vertical frame 110 is in close contact with the second vertical frame guide groove 230 formed in the cylinder case 300, the transfer guide 121 and the first formed on the outer surface of the second vertical frame 110 The second vertical frame 110 is coupled to the transfer protrusion 120 formed at the bottom of the inner side of the vertical frame 111 and the height is adjusted by moving the third vertical frame 111 by the lifting and lowering operation of the vertical frame cylinder 400. ) And the third vertical frame 111 is combined with the first vertical frame 100 and the coupling step (S500).

In addition, the first vertical frame 100, the second vertical frame 110, the third vertical frame 111 is coupled, the insulating groove 150 and the roof frame formed on the upper surface in the third vertical frame 111 The roof frame 112 and the third vertical frame 111 are combined with each other (S600), and the greenhouse structure 10 is constructed as shown in FIG. 2G. will be.

In addition, as shown in Figure 3, a cross-sectional view of the greenhouse structure 10, and operates the third vertical frame 111 by the lifting and lowering operation of the vertical frame cylinder 400, the third vertical frame 111 The second vertical frame 110 is moved according to the operation of the movement, and is inserted into the second vertical frame guide groove 230 and the third vertical frame guide groove 240 formed in the cylinder case 300 when descending, It consists of adjusting the height according to the operation of the roof frame cylinder 410 to raise and lower the roof frame 112 according to the selection.

10. Greenhouse Structure 30. Wind Rock Control Panel
40. Anchor Bolt 50. Mounting Plate
100. 1st vertical frame 110. 2nd vertical frame
111. Third Vertical Frame 112. Roof Frame
120. Feeding protrusion 121. Feeding guide
130. Rubber projection 140. Insulation projection
150. Insulation groove
200. Vertical frame cylinder groove 210. Roof frame cylinder groove
211. Wind pressure adjustment cylinder groove 220. First vertical frame insertion groove
230. 2nd vertical frame guide groove 240. 3rd vertical frame guide groove
300. Cylinder Case
400. Vertical Frame Cylinder 410. Roof Frame Cylinder
411. Air pressure cylinder 412. Flexible pipe

Claims (7)

In the construction method for installing a variable greenhouse structure (10) for growing crops or raising livestock,
The construction method includes a drilling step (S100) for forming a first vertical frame insertion groove 220 on the ground;
In order to embed the vertical frame cylinder 400, roof frame cylinder 410, wind pressure cylinder 411 on the ground, vertical frame cylinder groove 200, roof frame cylinder groove 210, wind pressure cylinder cylinder groove ( 211) drilling step (S200);
The vertical frame cylinder groove 400, the roof frame cylinder groove 210, and the wind pressure regulator cylinder groove 211 are installed in the vertical frame cylinder 400, the roof frame cylinder 410, and the wind pressure regulator cylinder 411. Step (S300);
The cylinder case 300 is installed on the ground, and the installation step of fixing the flexible pipe 412 on the upper surface of the first vertical frame 100 and the cylinder case 300 in the first vertical frame insertion groove 220 (S400). );
Coupling a second vertical frame (110) and a third vertical frame (111) coupled to the installed first vertical frame (100) (S500);
The first vertical frame 100, the second vertical frame 110, the third vertical frame 111 is coupled, the upper surface of the third vertical frame 111 and the bottom of the roof frame 112 is coupled (S600) );
Variable greenhouse structure construction method characterized in that configured to include.
The method of claim 1,
The first vertical frame insertion groove 220 drilling step (S100) is to form a first vertical frame insertion groove 220 to fix the first vertical frame 100 on the ground to fit the crop cultivation or livestock size Variable greenhouse structure construction method characterized in that.
The method of claim 1,
The vertical frame cylinder groove 200, roof frame cylinder groove 210, wind pressure cylinder cylinder groove 211 drilling step (S200) is the vertical frame cylinder 400 and roof frame cylinder 410, wind pressure cylinder ( 411) is a variable greenhouse structure construction method characterized in that the groove is formed to be partially embedded.
The method of claim 1,
The vertical frame cylinder 400, the roof frame cylinder 410, wind pressure adjustment cylinder 411 installation step (S300) is the vertical frame cylinder groove 200, roof frame cylinder groove 210, wind pressure cylinder cylinder groove Part 2, each of the cylinders (400, 410, 411) is embedded in the groove formed in the drilling step (S300), the variable greenhouse structure construction method, characterized in that fixed to the groove bottom surface with an anchor bolt (40).
The method of claim 1,
In the cylinder case 300, the first vertical frame 100, and the flexible pipe 412 installation step (S400), the cylinder case 300 has a fixed plate 50 formed on the lower side of the outer surface, and the ground is anchor bolt 40. It is fixed to, the first vertical frame 100 is inserted into the first vertical frame insertion groove 220, a plurality of fixing plate 50 is formed in the lower side of the first vertical frame 100 anchor bolt 40 Variable greenhouse structure construction method characterized in that fixed to the ground.
The method of claim 1,
A rubber protrusion 130 is formed on an outer upper surface of the first vertical frame 100 fixed to the ground by the anchor bolt 40 in the second vertical frame 110 and the third vertical frame 111 coupling step (S500). The inner side of the second vertical frame 110 is in close contact with the second vertical frame guide groove 230 formed in the cylinder case 300, the transfer guide 121 formed on the outer surface of the second vertical frame 110 and Method of constructing a greenhouse structure, characterized in that coupled to the transfer projections 120 formed on the lower inner surface of the third vertical frame (111).
The method of claim 1,
Insulating grooves (150) formed on the upper surface of the third vertical frame (111) and the lower surface of the roof frame (112) in the coupling step (S600) of the third vertical frame (111) and the roof frame (112). ) Is a method of construction of a variable greenhouse structure, characterized in that to maintain the internal temperature.

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