KR101795449B1 - Manufacturing method for hybrid greenhouse, and hybrid greenhouse for household manufacturing by the same - Google Patents

Abstract

The present invention relates to a method of manufacturing a hybrid domestic small greenhouse and a hybrid domestic small greenhouse manufactured through the same. The present invention comprises: a first step of setting a place for the installation of a hybrid domestic small greenhouse (100) and adjusting the horizontality of the place; a second step of installing a set number of first height control devices (160) in a set position; a third step of installing a lower reinforcement frame (150); a fourth step of installing a vertical frame (111) and a horizontal frame (112) by using a square groove of the lower reinforcement frame (150), and completing a greenhouse body (110) by installing greenhouse body vinyl (113); a fifth step of installing an upper frame (130) on the front and rear sides of the greenhouse body (110); a sixth step of installing a set number of second height control devices (140) in a set position of the upper part of the upper frame (130); a seventh step of installing a vertical roof frame (121) and a horizontal roof frame (122); an eighth step of completing a greenhouse roof (120); a ninth step of installing a directional illuminance sensor module (194) on the greenhouse roof (120); a tenth step of installing an openable solar cell module array (120a) in the upper part of the second height control devices (140); and an eleventh step of connecting a control device (190) with power supply and communication lines for the first height control devices (160), the second height control devices (140), the directional illuminance sensor module (194), and the openable solar cell module array (120a). As such, the present invention is capable of enabling the sale of domestically produced power like a domestic power generator.

Description

Technical Field [0001] The present invention relates to a method for manufacturing a hybrid green house, and a hybrid green house produced by the hybrid house,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of manufacturing a compact greenhouse for a hybrid home, and a hybrid greenhouse for a hybrid home manufactured thereby. More specifically, the present invention can concentrate solar light and utilize a self- The present invention relates to a method of manufacturing a compact greenhouse for a hybrid home, and a hybrid greenhouse for a hybrid home, which is capable of efficiently constructing a small-sized green house for preventing a breakdown of the greenhouse due to precision during elevation control.

In general, the greenhouse began to be used in agriculture for vinyl films from around 1954, and house tunnels were spread. The greenhouse was rapidly developed and is now used as the most important gardening facility in the whole country.

Greenhouses are most commonly used for the cultivation of vegetables, and are also used for the cultivation of flowers and fruit trees.

Conventional greenhouses are constructed in such a way that a large-scale frame is formed on a farmland and then the outside of the frame is covered with vinyl.

In other words, since the conventional greenhouses are built in a large scale in farmland, there is a disadvantage that they can not be used in each family such as Hyundai. Therefore, farmers who have been growing vegetables have washed the vegetables while they have shipped them.

However, in modern times, when pesticides are planted in the cultivation of vegetables, consumers can not eat them safely. As a result, the vegetable is washed for a long time, resulting in a waste of unnecessary water.

Accordingly, in the technology field, it is required not only to provide a small-sized greenhouse at home, but also to develop the technology to utilize the beneficial effects of the own energy supply and environment and to minimize the unfavorable effects.

Korea Utility Model Application No. 20-1998-0024126 "Home gardening greenhouse"

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an electric power supply system that can concentrate sunlight and utilize its own power supply system, The present invention provides a method for manufacturing a hybrid green house greenhouse for providing a greenhouse manufacturing method capable of selling home-produced electric power as a generator concept, and a hybrid green house for hybrid home produced thereby.

The present invention also provides a method for manufacturing a greenhouse for a hybrid home, which provides a method of manufacturing a greenhouse capable of preventing the bottom surface from being damaged when lifting or descending, The present invention provides a hybrid greenhouse for a home.

The present invention also relates to a hybrid greenhouse for providing a greenhouse manufacturing method capable of providing a self-balancing function for maximizing the sunlight condensing efficiency on a directional basis, A method for manufacturing the same, and a hybrid green household small house produced thereby.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a method for manufacturing a hybrid greenhouse for a home, the method comprising: a first step of setting a place for installing a hybrid greenhouse for a home 100; A second step of adjusting the height of the piston by the hydraulic cylinder control so that the height of the piston is controlled by the controller 190, A third step of installing a lower end reinforcement frame 150 having square grooves for installing the body frames 111 and 112 and the body vinyl body 113 on the upper portion of the first height adjusting device 160; A fourth step of installing the body vertical frame 111 and the body horizontal frame 112 by using the rectangular grooves of the lower reinforcing frame 150 and completing the greenhouse body 110 by installing the body- ; A fifth step of installing the upper frame 130 on the front surface and the rear surface of the upper end of the greenhouse main body 110; A sixth step of installing a second height adjusting device 140 on the upper side of the upper frame 130 by a specified number of positions; A seventh step of installing a roof vertical frame 121 using a connecting member 110a at an end of a body vertical frame 111 constituting the greenhouse main body 110 and installing a roof horizontal frame 122; An eighth step of completing the greenhouse roof 120 by installing greenhouse roof veneers 123; A ninth step of installing a directional illuminance sensor module 194 on the top of the greenhouse roof 120; A tenth step of arranging the openable and closable solar module array 120a on the upper portion of the second height adjusting device 140 in accordance with the opening of the greenhouse roof 120; And a control device 190 for connecting the power line and the communication line to the first height adjusting device 160, the second height adjusting device 140, the directional illuminance sensor module 194, and the opening and closing type solar cell module array 120a, Step 11; And a control unit.

In the second step, the first height adjusting devices 160a-1, 160a-2, 160a-3, 160b-1, 160b-2 and 160b- 6 in total, i.e., two in the width direction Wf and three in the row and two in the vertical direction, are installed to perform a common height control by receiving a primary height adjustment command from the control device 190. [

In the third step, at least one water discharge hole adjustable in a valve type is formed on the lower surface of the lower reinforcement frame 150.

A method for manufacturing a hybrid green house for a hybrid home according to an embodiment of the present invention, and a hybrid greenhouse for a home produced thereby, provide an effect of condensing solar light and utilizing a power supply system of its own, And the remaining power can be used for domestic use, thereby providing a greenhouse manufacturing method capable of selling domestic production electric power by the concept of a household generator.

In addition, the method for manufacturing a hybrid greenhouse for a hybrid home according to another embodiment of the present invention, and the hybrid greenhouse for a home made therefrom, can be raised and lowered independently in the event of prevention of flood or water damage, A greenhouse manufacturing method can be provided.

In addition to the above, a method for manufacturing a hybrid greenhouse for a hybrid home according to another embodiment of the present invention, and a hybrid greenhouse for a home made therefrom, have a self-balancing function for maximizing the efficiency of sunlight focusing on a directional basis, It is possible to provide a greenhouse manufacturing method capable of providing its own energy supply and demand system based on optical power.

FIG. 1 is a flowchart illustrating a method of manufacturing a hybrid green house for a hybrid home according to an embodiment of the present invention.
FIG. 2 is a front view and a side view showing a hybrid greenhouse 100 according to the embodiment of the present invention shown in FIG. 1, which is manufactured in accordance with the method for manufacturing a hybrid green house.
FIG. 3 is a view for explaining the installation of the first height adjusting device 160 and the second height adjusting device 140 among the hybrid greenhouses 100 shown in FIG.
FIG. 4 is a perspective view illustrating a connection member 110a (FIG. 4A) fastened to the end of the body vertical frame 111 of the hybrid home small greenhouse 100 of FIG. 2, (FIG. 4B) between the module arrays 120a.
5 is a flowchart illustrating a process of performing a height control (Figs. 5A and 5B) for the open-close type solar cell module array 120a on the greenhouse roof 120 and a process of performing height control (FIG. 5C and FIG. 5D) by the first height adjusting device 160 with respect to the height adjusting device 160 shown in FIG.
FIG. 6 is a diagram showing a relationship between a control device 190 for controlling the hybrid green house 100 of FIG. 2 and a main control object.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a flowchart illustrating a method of manufacturing a hybrid green house for a hybrid home according to an embodiment of the present invention. Referring to FIG. 1, a place for installing a hybrid greenhouse 100 for a small household is set and the place is leveled (S110). It is possible to set the installation place in the home garden and the first floor veranda. In the case of the garden garden, the level can be adjusted by leveling the floor surface. On the other hand, in the case of a veranda on the first floor, it is possible to add a process of fixing the noise preventing agent such as a sound insulating material and a soundproofing material so as to align them horizontally.

After the step S110, the first height adjusting device 160 is installed at a designated position (S120). Here, the first height adjusting device 160 may be formed so that the height of the upper end of the piston can be adjusted by controlling all of the hydraulic cylinders.

3A, the three height adjustment devices 160 (160a-1, 160a-2, 160a-3, 160b-1, 160b-2 and 160b-3) ), Three rows and two columns are formed in total, so that a common height control can be performed by receiving a primary height adjustment command from the control device 190. [

After the step S120, the lower end reinforcing frame 150 having the square grooves for mounting the body frames 111 and 112 and the greenhouse body vinyl 113 on the upper portion of the first height adjusting device 160 installed in the step S120, (S130). In the present invention, the lower reinforcing frame 150 is a flat plate frame formed on the lower surface of the greenhouse body 110. The weight of the hybrid greenhousing 100 for hybrid households when the hybrid greenhouse 100 is raised / Thereby preventing the main body 110 from being broken.

More specifically, it is preferable that the lower reinforcement frame 150 is formed with at least one or more water release holes adjustable in a valve type on the lower surface thereof. The lower reinforcement frame 150 includes a greenhouse main body 110 and a greenhouse formed on the greenhouse main body 110 It is preferable that the roof 120 is formed of a metal so that the roof 120 can be seated.

The rectangular groove has a first groove through which the body vertical frame 111 of the greenhouse main body 110 can be inserted and a second groove into which the lower end of the greenhouse body vinyl 113 attached to the outer surface of the body vertical frame 111 is inserted When the main body vertical frame 111 and the greenhouse main body vinyl 113 are inserted into the first groove and the second groove respectively and the carbon fiber and the flame retardant are added to the reclaimed polypropylene The greenhouse main body 110 can be fixed to the lower reinforcing frame 150 by mixing the polypropylene resin and the lightweight foamed concrete in a weight ratio of 1: 0.5 to 0.6. More specifically, the recycled polypropylene resin used in the present invention is obtained by adding a carbon fiber to regenerated polypropylene, which is a waste synthetic resin, to obtain a polypropylene resin which is a carbon fiber reinforced plastic (CFRP) Reinforced polypropylene resin is stronger than iron, lighter than aluminum, has no rust, and has excellent processability.

Here, 10 to 15 parts by weight of a flame retardant and 5 to 7 parts by weight of an ultraviolet screening agent are added to and mixed with 100 parts by weight of a mixture containing 5 to 15 parts by weight of carbon fibers in 85 to 95 parts by weight of polypropylene, By adding carbon fibers with excellent fracture strength, it is possible to obtain fracture strength required for greenhouses. By adding flame retardancy to polypropylene which is a flammable material, it is possible to provide flame retardancy to fire that may occur in the construction process and afterwards, The recycled polypropylene resin is used in comparison with the function of the polypropylene resin.

In the present invention, the flame retardant is one selected from the group consisting of antimony molybdate, aluminum hydroxide, molybdenum oxide, and magnesium hydroxide or a mixture of two or more thereof. Particularly, aluminum hydroxide (Al (OH) ₃ ) is formed in the form of foam to be described later, and heat is applied. When the temperature exceeds 500 ° C., the micropores are changed into a large number of activated alumina, and adsorption performance is obtained. Therefore, It absorbs harmful substances such as gas (HCl) and endothermic reaction during thermal decomposition. It also has a cooling effect. It is nonflammable and has excellent water resistance and acid resistance. In addition, the flame retardant effect can be expected to be improved by using the above flame retardants in combination.

After step S30, the body vertical frame 111 and the body horizontal frame 112 are installed using the rectangular grooves of the lower reinforcing frame 150 (S140).

After step S140, the greenhouse body 110 is completed by installing the greenhouse body vinyl 113 (S150).

After step S150, the upper frame 130 is installed on the front and rear surfaces of the upper end of the greenhouse main body 110 (S160). Here, a total of two upper frames 130 are provided, one at the front area and one at the rear area of the upper end of the greenhouse 110, and the first upper frame installed on the front side and the second upper side frame installed on the rear side, Shaped frame extending to the side surface and the second side surface so that the second height adjusting device 140 installed in step S170 is installed not only in the reinforcing strength of the entire greenhouse main body 110, Thereby providing a place where it can be fixed.

After the step S160, the second height adjusting device 140 is installed at a designated position on the upper frame 130 (S170). Here, both the inner height adjusting portion 141 (see FIG. 3B) and the outer height adjusting portion 142 that constitute the second height adjusting device 140 are formed so that the height of the upper end of the piston can be adjusted by controlling the hydraulic cylinder .

That is, the second height adjusting device 140 includes two outer height adjusting portions 142 formed on the outer sides of the two openable and closable solar cell module arrays 120a installed in Step S210, And two inner height adjusting portions 141, so that a total of eight can be formed in one hybrid small household greenhouse 100.

After step S170, a roof vertical frame 121 is installed using a connecting member 110a at the end of the body vertical frame 111 constituting the greenhouse main body 110, and a roof horizontal frame 122 is also installed (S180 ). 5A, the connecting member 110a has a hole having a hexagonal cross section, so that the body vertical frame 111 can be fastened to the lower portion and the roof vertical frame 121 can be fastened to the upper portion. The roof horizontal frame 122 can be installed utilizing the roof vertical frame 121 fastened in a form extending from the roof horizontal frame 122. [

After step S180, the greenhouse roof 120 is completed by installing the greenhouse roof vinyl 123 (S190). That is, the green roof vinyl 123 can be attached to the outer surface composed of the roof vertical frame 121 and the roof horizontal frame 122, and can be further attached to the inner surface.

After step S190, a directional illuminance sensor module 194 is installed on the top of the greenhouse roof 120 (S200). More specifically, the directional illuminance sensor module 194 may be formed in the upper central region of the greenhouse roof 120, but is not limited thereto. By providing five illuminance sensors so as to have a five- The control unit 190 controls the height and the angle of the openable and closable solar module array 120a installed in step S210 by controlling the illuminance of the five directions and transmitting the respective illuminance values to the control unit 190 .

After step S200, the openable solar module array 120a is installed on the upper portion of the second height adjusting device 140 in accordance with the opening of the greenhouse roof 120 (S210). For this purpose, the fastening structure between the inner height adjusting portion 141 and the outer height adjusting portion 142 and the openable and closable solar module array 120a is such that the end of the piston 140b is connected to the rotary shaft 140c, 140d may be additionally formed and the rotary port cover 140d may be bolted to the lower surface of the openable and closable solar module array 120a.

After step S210, power lines and communication lines for the first height adjuster 160, the second height adjuster 140, the directional illuminance sensor module 194, and the openable solar module array 120a are connected to the controller 190 (S220).

FIG. 2 is a front view and a side view showing a hybrid greenhouse 100 according to the embodiment of the present invention shown in FIG. 1, which is manufactured in accordance with the method for manufacturing a hybrid green house. FIG. 3 is a view for explaining the installation of the first height adjusting device 160 and the second height adjusting device 140 among the hybrid greenhouses 100 shown in FIG.

FIG. 4 is a perspective view illustrating a connection member 110a (FIG. 4A) fastened to the end of the body vertical frame 111 of the hybrid home small greenhouse 100 of FIG. 2, (FIG. 4B) between the module arrays 120a.

5 is a flowchart illustrating a process of performing a height control (Figs. 5A and 5B) for the open-close type solar cell module array 120a on the greenhouse roof 120 and a process of performing height control (FIG. 5C and FIG. 5D) by the first height adjusting device 160 with respect to the height adjusting device 160 shown in FIG. FIG. 6 is a diagram showing a relationship between a control device 190 for controlling the hybrid green house 100 of FIG. 2 and a main control object.

2 to 6, a hybrid greenhouse 100 for a hybrid household completed by the manufacturing method of FIG. 1 includes a greenhouse body 110, a greenhouse roof 120, an upper frame 130, a second height adjuster 140 may include a lower reinforcement frame 150, a first height adjuster 160, a front access door 170, a side accessor 180, and a controller 190.

The control device 190 may be connected to the battery 191.

The controller 190 controls the height of the two openable and closable photovoltaic module arrays 120a formed on the greenhouse roof 120 in which the two panels constituting the upper part of the greenhouse body 110 form a cross- And angle control.

3B, the controller 190 includes two inner height adjusters 141 and two outer height adjusters 142 based on one of the two openable and closable solar cell module arrays 120a , It is possible to control the charging of the battery 191 with respect to electric power produced through solar collection, which is not simply an automatic ceiling-open type as in the prior art.

More specifically, the upper frame 130 includes two inner height adjusters 141 and 142 and a second outer height adjuster 142 on the inner side with respect to one solar cell module array 120a, The control device 190 may control the ventilation mode and the solar light charging mode for the inner height adjuster 141 and the outer height adjuster 142, which function as one set of four, Angle and horizontal (balance) states can be controlled.

The controller 190 measures the illuminance by the five illuminance sensors constituting the five-directional illuminance sensor module 194 (see FIG. 6) as a rectangular parallelepiped excluding the lower surface, It is possible to control the height and angle of the openable and closable photovoltaic module array 120a formed at positions symmetrical with respect to the vertexes of the roof. Hereinafter, for convenience of explanation, the openable and closable solar module array 120a formed on the left side in FIG. 5 will be described with reference to FIG.

The control unit 190 may extract at least one direction from the highest level after arranging the illuminance measurement amount by the directional illuminance sensor module 194 in order, and the extracted direction may be an upper surface, a front surface, a rear surface, Right side.

2A, the controller 190 controls the height of the inner height adjuster 141, which functions as one set by four from the height of the default height of the outer height adjuster 142 as shown in FIG. 2A, The inner height adjuster 141 and the outer height adjuster 142 are set to be equal to each other by transmitting a control command to the inner height adjuster 141 so that the inner height adjuster 141 and the outer height adjuster 142 are positioned in a horizontal (Fig. 5C). The control device 190 raises the positions of the pistons of the inner height adjuster 141 and the outer height adjuster 142 to the maximum position at the same time so that the power condensed by the openable and closable solar cell module array 120a reaches the maximum value (Fig. 5D).

5C, the controller 190 controls the pistons of the inner height adjuster 141 and the outer height adjuster 142 as high as possible, as shown in FIG. 5D, And the position of the piston of the inner height adjusting portion 141 is set to the minimum height, so that the power to be condensed from the first side can be controlled to be the maximum value.

On the contrary, when the second side has the highest illuminance, the controller 190 causes the pistons of the inner height adjuster 141 and the outer height adjuster 142 to be positioned as high as possible, as shown in FIG. 5D, The position of the piston of the height adjusting portion 142 is controlled to be located at the minimum height so that the power to be condensed from the rear face can be controlled to be the maximum value.

5D, when the front surface of the controller 190 has the highest illuminance, the pistons of the inner height adjuster 141 and the outer height adjuster 142 are positioned as high as possible, When the illuminance is strong, the inner height adjusting portion 141 and the outer height adjusting portion 142 arranged in one row are divided into two pairs, and a pair of inner height adjusting portions 141 And the position of the piston of the outer height adjusting portion 142 are respectively set to the minimum height, so that the power to be condensed from the front face can be controlled to be the maximum value. In this case, the minimum height of the piston of the inner height adjuster 141 is the position at the first side condensing, and the minimum height of the piston of the outer height adjuster 142 may be the position at the second side condensing.

On the contrary, when the rear surface has the highest illuminance, the controller 190 places the pistons of the inner height adjuster 141 and the outer height adjuster 142 as high as possible, as shown in FIG. 5D, The positions of the pistons of the pair of the inner height adjuster 141 and the outer height adjuster 142 are controlled to be at the respective minimum heights so that the power to be condensed from the rear face can be controlled to the maximum value.

In another embodiment of the present invention, the control device 190 includes a measurement sensor array capable of measuring the power provided to the storage battery 191 from each cell constituting the open-close type solar cell module array 120a, It is possible to analyze whether there is a pixel whose continuity is out of the image among the spatial coordinate threshold values of the point coordinates included in each coordinate string of the two-dimensional image, by analyzing the two- .

If there is a pixel deviating therefrom, the control device 190 determines that the light-condensing performance of the cell corresponding to the analyzed pixel is out of order, and outputs the result through the input / output unit 195 or may transmit it to the external terminal through the communication unit 195 .

Next, the controller 190 receives the first height adjustment command from the external terminal through the input / output unit or from the external unit through the communication unit, so that the first height adjuster 160 (160a-1, 160a-2, 160a-3, 160b -1, 160b-2, and 160b-3.

The control device 190 previously controls a common primary height adjustment for each of the first height adjusters 160 (160a-1, 160a-2, 160a-3, 160b-1, 160b-2, 160a-1, 160a-2, 160a-3, 160b-1, 160b-2, and 160b-3 as the height of the lower reinforcement frame 150 is controlled, 161a-1, 161a-2, 161a-3, 161b-1, 161b-2, and 161b-3 that measure the weight in accordance with the load acting on the lower reinforcement frame 150 ), And then analyzes whether or not there is something exceeding the first weight threshold value from other weight information among the pieces of weight information.

3A, the weight measuring sensors 161 (160a-1, 160a-2, 160a-3, 160b-1, 160b-2 and 160b- 161a-1, 161a-2, 161a-3, 161b-1, 161b-2, and 161b-3.

As a result of the analysis, the controller 190 determines that the first height adjustment device 160 of the first height adjustment device 160 supporting n lower reinforcement frames 150 (n is 4 or more natural numbers, 6 in FIG. After extracting the excess height adjustment device 160 and checking the weight information of the two first height adjustment devices 160 operating as one set with the extracted first height adjustment device 160, It is analyzed whether or not it exceeds the second weight threshold value which is not exceeding the first weight threshold value but smaller than the first weight threshold value.

When the center of gravity of the first weight adjusting unit 160 is shifted to the side of the first height adjusting unit 160 based on the average value of the weight information measured by the weight measuring sensor 161, The second weight threshold may correspond to a minimum weight value that may occur and the first height adjuster 160 adjacent to the first height adjuster 160 that is greater than or equal to the first weight threshold, It is possible to prevent the center of gravity from being sharply shifted and to prevent the center reinforcement member 160 from being deformed due to the simultaneous height correction of the two or three first height adjusting apparatuses 160, Corresponds to a value close to a first weight threshold for preventing and protecting cracks of the first electrode 150 and within a preset numerical range.

Accordingly, when the weight information of the neighboring second height adjusting apparatus that provided the received weight information has at least one or more weight information exceeding the second weight threshold value, 1 height adjusting device 160 is extracted.

Thereafter, the controller 190 simultaneously adjusts the height of the first height adjusting device 160 exceeding the first weight threshold and the first height adjusting device 160 exceeding the neighboring second weight threshold can do.

The control device 190 is configured to simultaneously adjust the height of the first height control device 160 and the first height adjustment device 160 to exceed the first weight threshold value, Or at a different height unit or speed.

In one embodiment of the present invention, the controller 190 may include a first height adjustment device 160 that exceeds the first weight threshold if there is one or two neighboring first height adjustment devices 160 that exceed the second weight threshold 160 to the height of the first height adjusting device 160 exceeding the second weight threshold, and then controls the second and third height adjusting devices 160, which are equal in height, to the second weight Movement control is performed until the same weight information is received from each of the six weight measuring sensors 161 of the first height adjusting device 160 within a range not exceeding the threshold value, You can do the work.

In another embodiment of the present invention, the controller 190 may include a first height adjustment device 160 that exceeds a first weight threshold if there are two neighboring first height adjustment devices 160 that exceed the second weight threshold 160 until the weight information of the remaining three first height adjustment devices 160 is received from the weight measurement sensor 161 prior to the first height adjustment device 160 exceeding the second weight threshold, After the adjustment is performed, the same weight information as the remaining four first height adjustment devices 160 for the first height adjustment device 160 exceeding the second weight threshold is received until the weight information is received from the weight measurement sensor 161 By performing the height adjustment, it is possible to perform a correction operation on the weight threshold while performing weight distribution.

In yet another embodiment of the present invention, the controller 190 may determine that the first height adjustment device 160, which exceeds the second weight threshold, The first height regulating device 160 is moved downward to the same height as that of the first height regulating device 160 exceeding the second weight threshold value and then the first height regulating device 160 160 at the same height as other neighboring first height adjusters 160 that do not exceed the weight threshold at the same time. Thereafter, the controller 190 controls the position of the first height adjusting device 160 located at the same height until the same weight information as the remaining three first height adjusting devices 160 is received from the weight measuring sensor 161 By performing the downward position control, it is possible to perform a correction operation on the weight threshold while performing weight distribution.

That is, the control device 190 may control the hydraulic cylinders of the first height adjusting device 160, the hydraulic cylinders of the two neighboring first height adjusting devices 160, The position control can be controlled so that the six pistons can be leveled at the same height.

In addition, when performing the height correction operation for one first height adjusting device 160, the control device 190 may transmit weight information about the first height adjusting device 160 exceeding the height to the weight measuring sensor 160 161, it is possible to simultaneously perform an individual downward position correction process in relation to another first height adjusting device 160 which is adjacent in the same manner as described above.

In another embodiment of the present invention, the controller 190 may be configured to pre-condition each of the second height adjusters 160 (160a-1, 160a-2, 160a-3, 160b-1, 160b-2, 160a-1, 160a-2, 160a-3, 160b-1, 160b-1, 160b-1, 160b-1 and 160b- 161a-1, 161a-2, 161a-3, 161b-1, 161a-2, and 161b-3) 161b-2, and 161b-3), weight information generated in real time from other weight information among the weight information, a third weight threshold value (a third weight threshold value equal to or different from the first weight threshold value) And whether there is anything that is not.

The control device 190 determines that the first height adjustment device 160 of n (n is four or more natural numbers, six in the case of FIG. 7) supporting the lower reinforcing frame 150 is below the third weight threshold value After the first height adjuster 160 is extracted, the weight information of the first height adjuster 160 and the neighboring two first height adjusters 160 operating as one set are checked. Then, 3 < / RTI > weight threshold that is less than the third weight threshold but less than the fourth weight threshold that is less than the third weight threshold but not exceeding the third weight threshold.

The third weight threshold value is a distortion of the lower reinforcing frame 150 when the center of gravity is relatively less toward the side based on the average value of the weight information measured by the weight measuring sensor 161 of each first height adjusting device 160 And the fourth weight threshold may correspond to the first height adjuster 160 adjacent to the first height adjuster 160 that is less than the third weight threshold, When the center of gravity is not to be deflected, the height adjustment of the two or three first height adjusting devices 160 is performed simultaneously with the height adjustment of the one height adjusting device 160 150 and the third weight threshold value for preventing and protecting the cracks from occurring in a predetermined range.

Accordingly, when the weight information of the neighboring second height adjusting device providing the received weight information is at least one or more than the fourth weight threshold value, 1 height adjusting device 160 is extracted.

Thereafter, the controller 190 simultaneously adjusts the height of the first height adjuster 160, which is less than the third weight threshold, and the height adjuster 160, which is adjacent to the first height adjuster 160, can do.

The control device 190 simultaneously controls the first height adjusting device 160 exceeding the third weight threshold and the first height adjusting device 160 exceeding the neighboring fourth weight threshold, Or at a different height unit or speed.

In one embodiment of the present invention, the controller 190 includes a first height adjuster 160 that is less than a third weight threshold when there is one or two neighboring first height adjusters 160 that are less than or equal to the fourth weight threshold 160 to the height of the first height adjusting device 160 which is less than or equal to the fourth weight threshold value and then controls the upward and downward movements of the second and third height adjusting devices 160, Movement control is performed until the same weight information is received from each of the six weight measuring sensors 161 of the first height adjusting device 160 within a range not exceeding the threshold value, You can do the work.

In addition, in another embodiment of the present invention, the controller 190 may include a first height adjustment device 160 that exceeds a third weight threshold if there are two neighboring first height adjustment devices 160 that exceed the fourth weight threshold 160 until the weight information of the remaining three first height adjusting devices 160 is received from the weight measuring sensor 161 before the first height adjusting device 160 exceeds the fourth weight threshold, Control is performed until the same weight information as the remaining four first height adjusting devices 160 for the first height adjusting device 160 exceeding the fourth weight threshold is received from the weight measuring sensor 161 By performing the upward height control, it is possible to perform the correction operation on the weight threshold while performing the weight distribution.

In another embodiment of the present invention, when the first height adjuster 160, which is less than the fourth weight threshold, is one of the two neighboring ones, the controller 190 adjusts the first height adjustment The apparatus 160 is elevated to the same height as the first height adjuster 160 that is less than or equal to the fourth weight threshold, and then the first height adjuster 160, which exceeds the third and fourth weight thresholds, Up position to the same height as another neighboring first height adjuster 160 that does not exceed the weight threshold. Thereafter, the controller 190 controls the position of the first height adjusting device 160 located at the same height until the same weight information as the remaining three first height adjusting devices 160 is received from the weight measuring sensor 161 By performing the upward position control, a correction operation for the weight threshold can be performed while performing weight distribution.

That is, the controller 190 may be configured to increase the weight of at least one of the hydraulic cylinders of the first height adjuster 160, the hydraulic cylinders of the two neighboring first height adjusters 160, The position control can be controlled so that the six pistons can be leveled at the same height.

In addition, when performing the height correction operation for one first height adjusting device 160, the control device 190 transmits weight information about the first height adjusting device 160, 161 and then perform the individual upward position correction process in the same manner as described above in relation to the neighboring first height adjuster 160. [

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they have been used only in a general sense to easily describe the technical contents of the present invention and to facilitate understanding of the invention , And are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100: Small Green House for Hybrid Home
110:
120: Greenhouse roof
130: upper frame
140: second height adjuster
150: Lower reinforcement frame
160: first height adjustment device
170: Front door
180: Side profile
190: Control device

Claims (1)

A first step of selecting a place where the hybrid greenhouse 100 for a home is installed and leveling the selected place;
A second step of installing a first height adjusting device 160, which is adjustable in height of the piston by controlling the hydraulic cylinder, to receive the height control by the control device 190, in a specified number of positions;
A third step of providing a lower end reinforcement frame 150 having square grooves for installing the body frames 111 and 112 and the body vinyl body 113 on the upper portion of the first height adjusting device 160;
A fourth step of installing the body vertical frame 111 and the body horizontal frame 112 by using the rectangular grooves of the lower reinforcing frame 150 and completing the greenhouse body 110 by installing the body- ;
A fifth step of installing the upper frame 130 on the front surface and the rear surface of the upper end of the greenhouse main body 110;
A sixth step of installing a second height adjusting device 140 on the upper side of the upper frame 130 by a designated number of the height adjusting devices 140;
A seventh step of installing a roof vertical frame 121 using a connecting member 110a and installing a roof horizontal frame 122 at an end of a body vertical frame 111 constituting the greenhouse main body 110;
An eighth step of completing the greenhouse roof 120 by installing greenhouse roof veneers 123;
A ninth step of installing a directional illuminance sensor module 194 on the top of the greenhouse roof 120;
A tenth step of arranging the openable and closable solar module array 120a on the upper portion of the second height adjusting device 140 in accordance with the opening of the greenhouse roof 120; And
11, which connects the power line and the communication line to the first height adjusting device 160, the second height adjusting device 140, the directional illuminance sensor module 194, and the open-close solar module array 120a, step; , Wherein the first,
In the third step,
And forming at least one water discharge hole on the lower surface of the lower reinforcement frame 150,
In the fourth step,
The square groove formed in the lower reinforcing frame 150 is formed by a first groove in which the body vertical frame 111 of the greenhouse body 110 can be inserted and a second groove in which the body vertical frame 111 is attached, And a second groove into which the lower end of the second groove 113 is inserted,
When the body vertical frame 111 and the greenhouse body vinyl 113 are inserted into the first groove and the second groove respectively, the mixed concrete is laid in the first groove and the second groove, A method for manufacturing a compact greenhouse for a hybrid home, characterized in that it is a concrete mixed with a regenerated polypropylene resin to which carbon fiber and a flame retardant are added and lightweight foamed concrete.

Images