KR102626686B1 - Greenhouse structure for smart farm system with high functional fluororesin film applied - Google Patents

Abstract

The present invention relates to a smart farm greenhouse structure to which an automation system is applied. More specifically, it is composed of horizontal bars and vertical bars that vertically and horizontally connect the tips of vertical supports arranged at regular intervals, and between adjacent vertical bars. In the greenhouse frame in which the roof bars are arranged upward and the vertical bars and roof bars are connected through a plurality of downwardly sloping roof arms, the roof arms are firmly connected and fixed to each other by separately provided angle brackets, as well as the roof bars. The bar is extended and connected through supporting bars, and at the same time, the high-performance fluoropolymer film is tensioned and firmly fixed using these loop bars and loop arms.
It not only blocks ultraviolet and infrared rays, which are the unique characteristics of high-performance fluoropolymer films, but also allows light to pass through to maintain an optimal environment suitable for crop growth, while also simplifying the bonding structure between roof arms to form the roof part of the greenhouse structure. By increasing durability, the convenience of construction and work efficiency can be greatly improved, and not only can construction in a tight tension state for the high-performance fluoropolymer film installed on the entire loop be done simply and quickly, but also the high-performance fluoropolymer film is It is easy to maintain, repair or replace, improving the overall management efficiency of the greenhouse structure and significantly increasing its service life.

Description

Greenhouse structure for smart farm system with high functional fluororesin film applied}

The present invention relates to a smart farm greenhouse structure to which an automation system is applied, and more specifically, to a greenhouse structure in the form of a frame by horizontal bars and vertical bars connecting the tops of vertical supports, and roof bars and loop arms to form an inclined loop. Wow, when constructing a high-performance fluoropolymer film under tension on the entire roof of a greenhouse structure, an efficient and solid connection is installed between the roof bar and the roof arm, as well as fast and stable fixation of the high-performance fluoropolymer film fixed to the entire roof in a state of tension. This relates to a greenhouse structure for a smart farm system that allows installation.

The existing type of greenhouse for growing crops consists of a square-shaped building made of vinyl, glass, or plastic, and is generally installed with a simple control device to control temperature, humidity, and soil moisture, relying on manpower. It becomes. In addition, crops are managed manually and manpower is absolutely necessary. Although these greenhouses can be built at a relatively low price, they have the disadvantage of making it difficult to control the environment according to weather conditions.

Accordingly, recent greenhouses are equipped with more advanced technologies, and the latest technology is to introduce a systematic automation system to measure temperature, humidity, sunlight, soil moisture, etc. according to weather conditions through sensors, and to create a complex environment. It is automatically controlled through a control device. In addition, more systematic and efficient crop management is possible by using LED lighting to control light sources, supply water, and manage water quality. These greenhouses require high initial costs, but as automation progresses, operating costs are reduced and productivity is increased. There is a tendency to increase.

In particular, recently, unlike existing greenhouses, smart farm greenhouses have emerged that enable automated complex environment control using advanced technologies such as LED lighting and CO2 concentration control. These smart farm greenhouses are equipped with various technologies such as big data, artificial intelligence, and robot technology. By using technology, we can optimize the growth environment of crops and increase productivity.

The structure of this smart farm greenhouse is similar to a regular greenhouse, but additional equipment such as IoT sensors, control systems, and LED lighting are installed. These devices detect and analyze environmental factors to provide optimal growth conditions for crops. Big data and artificial intelligence technology are used to collect and analyze crop growth information to enable more accurate environmental control and crop production.

In addition, the operation form of smart farm greenhouses is usually remote control using cloud technology, through which farmers around the world can monitor and manipulate the situation inside the greenhouse through their smartphones or computers. These technologies play a significant role in improving agricultural productivity by enabling real-time monitoring of production and quality, thereby increasing productivity and improving quality.

In the case of a greenhouse that enables such a smart farm, it is equipped with supports that are installed continuously in all directions, and loops that form an inclined surface using these supports are installed by combining them with the ends of the supports, and the loop is an extruded member. By cutting and forming divided sections to have predetermined intervals, a light-transmitting film or hard film of a size corresponding to each divided space is attached or fixed, thereby providing sufficient and even coverage to the entire interior of the greenhouse by the light-transmitting film. It not only makes it more beneficial to the growth of plants by enabling the lighting function to be achieved, but also serves to reduce the amount of electrical energy source used to achieve appropriate illuminance.

In particular, the fixing structure for the translucent film or hard film as described above has been disclosed by Registration Patent No. 10-1799020, and the hard film is secured using the first and second binding members and a cover member without using any fastening screws, etc. Since it is tightly and firmly coupled and fixed, it can be fastened and easily separated from each other, which greatly reduces work time, manpower, and related costs, as well as the first and second binding members and covers. A hard film fixing device for greenhouses has been developed and registered, which has the following benefits: it has a beautiful appearance and greatly improves durability and marketability by not drilling holes for screwing materials and hard films.

However, due to the difficulty of field application, the fixing structure for light-transmitting films or hard films, such as the patent mentioned above, is actually fixed using fastening screws in the field. As the proportion of work at heights on site is high, safety accidents such as falls of workers are also raised. It is inherent.

In addition, the existing greenhouse structure for smart farms is one in which the traditional installation structure and installation method of the past has been effectively applied to this day. It is sturdy by using countless support arms connected vertically and horizontally, including props, crossbars, and vertical bars. After installing the structure, a greenhouse with excellent lighting is being built by covering and fixing the structure with a light-transmitting hard film. Such a greenhouse structure for smart farms requires a lot of time, equipment, and manpower for construction. It is uneconomical, and interconnections, fastening parts, and fixing parts have the disadvantage of being vulnerable to natural disasters such as strong winds or heavy snow, leading to problems such as reduced tension and damage caused by water leaks.

In particular, hard films are materials that have a large deformation in response to tension, and cause large deformations in response to snow and wind loads, and frequently change shape depending on changes in load. The structure to which hard film is applied is stabilized by maintaining overall rigidity by introducing a uniform tensile state throughout the roof, which cannot resist compression or bending, and is a structure that withstands external loads such as typhoons, heavy snow, and heavy rain. am. Accordingly, the tension introduced into hard films, etc. causes stress relief over time due to the elongation change characteristics, causing the phenomenon of the film fluttering in strong winds (floating) or the phenomenon of rainwater accumulating on the film surface due to snow or rain (ponding). This can lead to rupture of the film.

In other words, while hard films have the advantage of guaranteeing excellent lighting properties, they are less durable and have unnecessarily excessive elasticity, so the lighting properties decrease after a certain period of time after installation, which reduces the greenhouse effect and makes it difficult to maintain indoor temperature. It has the disadvantage of gradually increasing energy usage, which requires periodic replacement. Tension cannot be applied uniformly to the entire roof initially, and sagging or sagging occurs gradually, so it is also necessary to conduct periodic inspections and maintain tension. Time, effort and cost will continue to occur.

In addition, each fastening part that connects and fixes the strut, horizontal bar, vertical bar, and support arm, etc., suffers water leakage damage due to the on-site construction method using fastening screws, and is gradually connected to each other as it is continuously exposed to wind, rain, or snow. As the fastening force is weakened or lost, it acts as a cause of shortening the lifespan of the entire frame that makes up the greenhouse structure, and it is inevitable because the scale is expanded without structural improvement in such mutual fastening parts. As a result, the size, length, thickness, and strength of each component inevitably increase excessively, making construction of structures and facilities, including frames, more difficult and requiring a lot of cost and time. As a result, constructability and economic efficiency are reduced. It will have significantly lower negative effects.

Republic of Korea Patent No. 10-1799020 (registered on November 13, 2017)

The present invention improves the problems described above, and consists of horizontal and vertical bars that vertically and horizontally connect the ends of vertical supports arranged at regular intervals, and a roof bar is arranged upward between adjacent vertical bars to move downwards. Regarding the greenhouse frame in which vertical bars and roof bars are connected through a plurality of inclined roof arms, the roof arms are firmly connected and fixed to each other by separately provided angle brackets, and the roof bars extend through supporting bars. At the same time as it is connected, the high-performance fluoropolymer film is tensioned and firmly fixed using these loop bars and loop arms.

Not only can the roof part of the greenhouse structure be connected and installed quickly and firmly, but the connection and fixing structure between the roof arms is simplified, so construction convenience is excellent, and the fastness and ease of fixing the high-performance fluoropolymer film and high-performance fluoropolymer film are very convenient. The purpose of the present invention is to provide a greenhouse structure for a smart farm system employing a high-performance fluoropolymer film that allows the film to be quickly and fixedly installed under tension.

In order to achieve the above-described object, the present invention connects the ends of vertical supports arranged at regular intervals to each other in the longitudinal and transverse directions by horizontal bars and vertical bars, and an upwardly spaced roof bar is provided between adjacent vertical bars. It forms a greenhouse frame in which vertical bars and roof bars are connected and fixed at an angle through separately provided roof arms, and a high-performance fluoropolymer film is adhered to the entire loop of the structure including the vertical bars, roof bars, and roof arms of the greenhouse frame. Constructed by fixing,

The above-described roof bars are placed between the ends of the mutually opposed roof arms, and the ends of both roof arms, which are disposed in a downward slant based on the above-described roof bars, are coupled and fixed through separately provided angle brackets, and the ends of the roof arms are fixed together through separately provided angle brackets. The roof bar is configured to be extended and connected by a separately provided support bar disposed between the ends of the roof arm.

The present invention not only maintains an optimal environment suitable for growth through high light transmittance, which is a unique feature of high-performance fluoropolymer film, but also simplifies the coupling structure between roof arms to form the roof portion of the greenhouse structure, while improving durability. By increasing this, the convenience of construction and work efficiency can be greatly improved, and by introducing equal tension to the high-performance fluoropolymer film installed on the entire loop, construction in a tight tension state can be carried out simply and quickly, as well as high-performance fluoropolymer film. It is easy to maintain, repair or replace the resin film, improving the overall management efficiency of the greenhouse structure and significantly increasing its service life.

Figure 1 is an overall upper perspective view of the greenhouse structure for a smart farm system of the present invention.
Figure 2 is a lower overall perspective view of the greenhouse structure for a smart farm system of the present invention.
Figure 3 is an overall front view of the greenhouse structure for a smart farm system of the present invention.
Figure 4 is a perspective view of a loop excerpt of the greenhouse structure for a smart farm system of the present invention
Figure 5 is an enlarged perspective view of the loop arm coupling portion of the greenhouse structure for the smart farm system of the present invention.
Figure 6 is an enlarged, separated view of the loop arm coupling portion of the greenhouse structure for the smart farm system of the present invention
Figure 7 is a front view of the roof arm coupling portion of the greenhouse structure for the smart farm system of the present invention.
Figure 8 is an enlarged front view of the roof arm coupling portion of the greenhouse structure for the smart farm system of the present invention.
Figure 9 is a front, separated view of the roof arm coupling portion of the greenhouse structure for the smart farm system of the present invention.
Figure 10 is an enlarged front view of the roof arm coupling portion of the greenhouse structure for the smart farm system of the present invention
Figure 11 is a diagram illustrating the connection between the loop arm and the angle bracket for the greenhouse structure for the smart farm system of the present invention.
Figure 12 is a cross-sectional view of the connection between the loop arm and the angle bracket for the greenhouse structure for the smart farm system of the present invention.
Figure 13 is a cross-sectional view showing the coupling between the roof arm and the high-performance fluoropolymer film for the greenhouse structure for the smart farm system of the present invention.

Additional objects, features and advantages of the present invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to a detailed description of the present invention, it should be noted that the present invention is capable of various modifications and may have various embodiments, and the examples described below and shown in the drawings are not intended to limit the present invention to specific embodiments. No, it should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Additionally, when a component is referred to as being “connected” or “connected” to another component, it may be directly connected or connected to the other component, but other components may also exist in between. It must be understood that there is. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Next, the terms used in this specification are only used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

In addition, terms such as "... unit", "... unit", and "... module" used in the specification refer to a unit that processes at least one function or operation, which is hardware or software or hardware and It can be implemented through a combination of software.

In addition, when describing with reference to the accompanying drawings, identical components will be assigned the same reference numerals regardless of the reference numerals, and overlapping descriptions thereof will be omitted. In describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

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

Figure 1 is an overall upper perspective view of the greenhouse structure for a smart farm system of the present invention, Figure 2 is an overall perspective view of the lower part of the greenhouse structure for a smart farm system of the present invention, and Figure 3 is a greenhouse structure for a smart farm system of the present invention. FIG. 4 is a perspective view of a loop extract of the greenhouse structure for a smart farm system of the present invention, FIG. 5 is an enlarged perspective view of the roof arm coupling portion of the greenhouse structure for a smart farm system of the present invention, and FIG. 6 is an enlarged perspective view of the roof arm coupling portion of the greenhouse structure for a smart farm system of the present invention. Figure 7 is an enlarged, separated view of the roof arm coupling part of the greenhouse structure for a smart farm system of the present invention, Figure 7 is a front view of the loop arm coupling part of the greenhouse structure for a smart farm system of the present invention, and Figure 8 is a greenhouse structure for a smart farm system of the present invention. This is an enlarged front view of the roof arm joint.

As shown in the figure, the greenhouse structure for a smart farm system according to the present invention has the ends of the vertical supports (100) (100') arranged at regular intervals formed by horizontal bars (200) (200') and vertical bars (300) (300'). ) are connected to each other in the vertical and horizontal directions, and roof bars 400 spaced upward are placed between adjacent vertical bars 300 and 300' to provide separately provided roof arms 500 and 500'. Through this, the greenhouse frame (F) can be completed by connecting and fixing the vertical bars (300) (300') and the roof bar (400) at an angle.

Next, a high-performance fluororesin film ( 600) is tightly fixed.

Here, the vertical supports 100 and 100' are installed at equal intervals in the vertical and horizontal directions on a plane according to the size of the greenhouse structure to be constructed using metal steel pipes, and are compared to existing greenhouse structures. The greenhouse structure of the present invention, which has a structure that reduces the roof load, can relatively widen the spacing between the vertical supports (100) (100'), thereby maximizing the internal usable area, as well as reducing the amount of steel used and reducing the construction period. It will produce various advantages such as shortening.

In addition, the horizontal bars 200 (200') and vertical bars (300) (300') connecting the ends of the vertical supports (100) (100') as described above in the longitudinal and transverse directions, respectively, are vertical. It serves to support the load on the greenhouse structure of the present invention, including the struts 100 and 100', and distributes and supports the load on the entire roof while providing stability to the greenhouse structure against wind, rain, or snowfall. This ensures that the installation status can be maintained continuously.

Next, the roof bar 400, which constitutes the loop of the greenhouse structure of the present invention, is arranged to be spaced upward from the middle of the vertical bars 300 (300'), and these vertical bars 300 (300') The roof bar 400 is connected and fixed by roof arms 500 and 500' fixed in a downwardly inclined form. The roof bar 400 and the roof arms 500 and 500' of the present invention The greenhouse structure can be completed with a roof with repeated slopes. In addition, by tightly fixing the high-performance fluororesin film 600 to the entire loop, excellent lighting and durability as a roof finishing material will be achieved.

Here, the high-performance fluororesin film 600 described above is a thin film made using light scattering technology, unlike general scattering films, and uses the phenomenon that occurs in the process of scattering light in a thin film made using fluorine atoms. Because fluorine atoms are very small, they are known to be very effective in scattering light. The high-performance fluoropolymer film 600 made using these characteristics is used in various fields such as solar cells, LED and LCD displays, and the high-performance fluoropolymer film has high transmittance and low reflectance, thereby improving the efficiency of solar cells. It is also being applied to increase .

In addition, this high-performance fluoropolymer film 600 transmits a portion of the light generated from the solar cell rather than reflecting it, thereby enabling maximum use of the power generated by the cell, and is also used in LED and LCD displays, etc. Film is applied to create a brighter and clearer screen and is used in various fields.

When such a high-performance fluororesin film (600) is applied to a greenhouse structure for a smart farm system as in the present invention, the excellent characteristics of the high-performance fluororesin film (600) itself allow for even lighting throughout the entire crop and around the roots. This is very effective in the growth of crops, and has excellent durability that does not change its inherent characteristics over a long period of time, so it will provide a very advantageous action and effect in terms of greenhouse maintenance and management.

Next, the roof bar 400 described above is placed between the ends of the mutually opposed roof arms 500 and 500', and both roof arms are disposed at a downward slope based on the roof bar 400 as described above. The ends of (500) (500') are coupled and fixed through a separately provided angle bracket (700), and the roof bar (400) is separately provided and placed between the ends of the roof arm (500) (500'). It is configured to be extended and connected by the support bar 800.

That is, the roof bar 400 serves to connect each end of the high-performance fluoropolymer film 600 disposed on both sides, and is located between the ends of the roof arm 500 and 500' to form the loop arm 500. It serves to form a natural and repetitive inclined loop by the connection between (500') and the loop arm (500) (500'), and the angle bracket (700) is formed separately from the loop arm (500). It will play the role of firmly fixing (500') and at the same time ensuring that the roof arm (500) (500') is fixed at a constant and uniform angle, and the support bar (800) is the roof bar. It serves to support the load on 400 and to continuously connect and fix the roof bar 400 having a certain length.

Accordingly, the above-mentioned roof bar 400 has outwardly protruding locking wings 401 and 401' located at the lower portions of both sides along the longitudinal direction and outwardly protruding film fixing grooves 402 and 402' located at the upper portions of both sides. and an upper locking protrusion 501 inserted into the lower side of the locking wings 401 and 401' at the ends of the roof arms 500 and 500' arranged oppositely on both sides of the roof bar 400. By forming, the above-described stopping wings (401) (401') are placed on the upper stopping protrusion (501), and the film fixing grooves (402) (402') are formed at the ends of the high-performance fluororesin film (600). It may be configured to insert an EPDM-Ring (Ethylene-Propylene Diene Monomer; 610) with a curled structure.

Therefore, the roof arms 500 and 500' are arranged to be inclined downward on both sides of the roof bar 400, which is fixed in the longitudinal direction of the vertical bars 300 and 300'. , by assembling the upper locking protrusion 501 of the roof arm 500 (500') to be inserted into the lower side of the locking wing 401 (401') of the roof bar 400, the roof arm ( 500) (500') can prevent separation or separation in the upward direction, and in the process of fixing the high-performance fluoropolymer film (600) using these roof bars (400) and roof arms (500) (500'), The roof bar (610), which is embedded in a rolled form at the tip of the high-performance fluoropolymer film (600), is pushed into the film fixing grooves (402) (402') through a pressurized carbon bond or sliding coupling method. Locking and fixing of the roof arms 500 and 500' by 400) and fixing the tip of the high-performance fluororesin film 600 can be performed simultaneously.

Next, a separately provided support bar 800 is inserted into the lower part of the roof bar 400 as described above, so that the roof bar 400 is supported and connected and fixed by the support bar 800, A downwardly opening T groove 403 is formed on the lower side of the roof bar 400, and a vertically penetrating fastening hole 801 is formed in the support bar 800, and a fastening bolt 404 is inserted into the T groove 403. ) is configured to penetrate downward through the fastening hole 810, so that the roof bar 400 and the support bar 800 are coupled and fixed by the combination of the fastening nut 405.

In addition, an upper resting groove 802 is formed on the upper side of the supporting bar 800 in which the lower part of the roof bar 400 is placed, and on the lower side of the supporting bar 800, two sides protruding downward along the longitudinal direction are formed. Lower supports 803 and 803' are formed so that the fastening nut 405 is accommodated between the lower supports 803 and 803', and a loop arm corresponding to the lower supports 803 and 803' is provided. 500) A lower resting ledge 502 may be formed at the tip of (500') so that the lower supports 803 and 802' of the above-mentioned support bars 800 are mounted on the lower resting ledge 502. There is.

Accordingly, when the support bar 800 is first placed between the ends of the roof arms 500 and 500' disposed on both sides to be inclined downward as shown in FIGS. 8 to 10, both sides of the support bar 800 The lower supports 803 and 803' are stably mounted on the lower resting ledges 502 of each roof arm 500 and 500' opposed to each other, and the long supporting bars 800 are used. When the shaped roof bar 400 is placed between the ends of the roof arms 500 and 500' arranged on both sides, the lower part of the roof bar 400 is stably placed in the upper resting groove 802 of the supporting bar 800. At the same time as it is inserted, the upper locking protrusion (501) of the roof arm (500) (500') comes into close contact with the lower side of the locking wings (401) (401') formed on the roof bar (400), creating a close assembly state between them. It will happen.

In addition, after inserting the fastening bolt 404 slidingly coupled to the lower T groove 403 of the roof bar 400 into the fastening hole 801 of the support bar 800, attach it to the downwardly protruding fastening bolt 404. By screwing the separately provided fastening nut 405, a firm fastening state is achieved between the roof bar 400 and the support bar 800. Although the roof bar 400 is continuously extruded, it has a length of There will be a limit, and this limit on length will not extend to the entire longitudinal direction of the greenhouse structure. Therefore, in the end, continuous construction can be performed in the form of connecting the roof bar 400 with a certain length through the support bar 800 described above. will be.

Therefore, the above-mentioned supporting bars 800 not only serve to continuously connect the roof bars 400, but also support the load acting on the roof bars 400 and allow the roof arms 500 and 500' on both sides to move. It simultaneously performs the role of suppressing what is happening. In addition, if necessary, the vertical bars 300 and 300' and the roof bar 400 may be additionally fixed using various fixing means such as welding or bolt fastening.

Next, in the case of the above-described loop arms 500 and 500', fastening grooves 503 and 503' are formed along the longitudinal direction on both lower sides as shown in FIGS. 11 and 12 to form the fastening grooves 503 (503'). It is configured so that the tip of the pair of loop arms 500 and 500' is firmly fixed by a separately provided angle bracket 700 coupled through 503').

In addition, the angle bracket 700 is provided with a front plate 701 and a rear plate 702 by moving the metal plate upward, and the front end of the front plate 701 and the rear plate 702 of the angle bracket 700 On both sides, downward inclined surface portions 703 and 703' are formed, and the ends of the front plate 701 and the rear plate 702 are bent in opposite directions on the inclined surface portions 703 and 703'. By forming bent ends (704) (704'), the bent ends (704) (704') are inserted into the fastening grooves (503) (503') on both sides of the loop arms (500) (500'), respectively, A plurality of tightening holes 705 and 705' are formed through the front plate 701 and the rear plate 702, and tightening bolts 706 and tightening nuts are inserted and fastened into the tightening holes 705 and 705'. (707) to form an inclination angle for fixing the roof arms (500) (500') by the angle bracket (700) and assembling the roof arms (500) (500') by the inclined surface parts (703) (703'). You will be able to configure it.

Accordingly, the roof arms 500 and 500', the ends of which are inserted and locked on both sides of the roof bar 400 in a separated state, have an independent interlocking structure applied through the angle bracket 700, Both bent ends 704 (70') formed at the front ends of the front plate 701 and the rear plate 702 of the bracket 700 are connected to the fastening grooves 503 and 503' of the roof arms 500 and 500'. When inserted, the loop arms (500) (500') are temporarily assembled with the angle bracket (700) and are naturally aligned by the inclined surfaces (703) (703') formed on both sides downward on the upper part of the angle bracket (700). A pair of loop arms 500 and 500' maintain a consistent angle and have an inclined assembly form.

In this temporary assembly state, if the tightening bolts 706 and tightening nuts 707 inserted into the tightening holes 705 and 705' of the front plate 701 and the rear plate 702 are strongly tightened, the front plate (701) 701) and the rear plate 702 become closer to each other, and at the same time, the bent ends 704 and 704' are inserted deeper into the fastening grooves 503 and 503' of the loop arms 500 and 500', forming a pair. The roof arms 500 and 500' and the angle bracket 700 that secures them will be able to maintain a firm connection with each other.

Therefore, by using the angle bracket 700, a natural and constant angle can be formed for the roof arms 500 and 500', as well as solid fixation between the roof arms 500 and 500', which are opposed to each other. The roof bar 400 and the support bar 800 located between the upper locking ledge 501 and the lower resting ledge 502 can also be produced in a solidly assembled state without separation.

Accordingly, the greenhouse structure of the present invention not only allows quick and constant assembly of the roof arms 500 and 500' using a separately provided angle bracket 700, but also has a sturdy angle bracket 700 and a strong fixation state. The durability and installation stability of the entire roof of the greenhouse structure can be improved by the roof arms 500 and 500', and the roof bar 400 disposed between the ends of the roof arms 500 and 500'. ) and the support bar 800 provide quick and sturdy assembly or fixation to the tip of the high-performance fluoropolymer film 600 as well as extension fastening of the roof bar 400 and stable load bearing capacity, further improving the stability of the entire greenhouse structure. It will have the desired effect.

In addition, in the case of the high-performance fluoropolymer film 600, the tip of which is coupled and fixed using the roof bar 400 as described above, the lower end is fixed to the upper part of the vertical bar 300 (300'), and the side and middle parts are attached to the roof arm as described above. It is fixedly installed using (500) (500'), and is not fixed by a separate pressure fixture and fastening bolt as before, but is coupled to the upper part of the roof arm (500) (500') as shown in Figure 13. The high-performance fluororesin film 600 can be fixed quickly and quickly by using a separately provided pressurizing fixture 510 so that a predetermined tension can be applied.

That is, the loop arm 500 (500') forms a cut-out fitting 504 along the longitudinal direction at the upper center, and the cut-out fitting 504 is used on the upper side of the loop arm 500 (500'). Thus, a separately provided pressure fixture 510 is combined to form a loop arm 500 ( The high-performance fluororesin film 600 placed on the 500') is cut during the process of inserting the burnt district 511 of the pressure fixture 510 into the incision fitting hole 504 of the loop arm 500 (500'). It is inserted together into the inside of the fitting hole 504, and due to the insertion action of the high-performance fluoropolymer film 600, the high-performance fluoropolymer film 600 will produce an effect of being pulled tautly, and the incision fitting hole ( Due to the mutual elastic locking state of the coal district 511 with respect to 504), a strong fixation state of the high-performance fluororesin film 600 with respect to the roof arm 500 (500') can be produced.

Therefore, when it is desired to fix the high-performance fluoropolymer film 600 to the roof arm 500 (500'), the separately provided pressurizing fixture 510 is simply pressed from the upper part of the roof arm 500 (500') to fasten them together. Just by doing this, tension can be applied to the high-functioning fluoropolymer film (600) and the high-functioning fluoropolymer film (600) can be firmly fixed at the same time, greatly improving the convenience of construction, as well as a separate attachment for the high-functioning fluoropolymer film (600). This is very convenient because there is no need to perform the task of providing tension. In addition, even when the high-performance fluoropolymer film 600 needs to be replaced, the high-performance fluoropolymer film 600 can be easily separated from the roof arm 500 (500') by pulling out and removing only the pressurizing fixture 510. Therefore, the convenience of maintaining, managing, or replacing the high-performance fluororesin film 600 can be greatly improved.

In this way, the greenhouse structure of the present invention includes a roof bar (400) that forms a loop of the greenhouse structure from the vertical supports (100) (100'), the horizontal bars (200) (200'), and the vertical bars (300) (300'). Not only can the roof arm (500) (500') be assembled and fixed quickly and firmly through the angle bracket (700), but the high-performance fluororesin film (600) formed on the entire loop of the greenhouse structure can be fixed very quickly and effectively. At the same time, tension is applied during the fixing process of the high-performance fluororesin film 600, thereby providing a high-quality greenhouse structure that prevents sagging or fluttering.

The embodiments described in the present specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so various equivalents and modifications can be substituted for them. It should be understood that there may be examples.

F: Greenhouse frame
100,100': Vertical support
200,200': horizontal bar
300,300': Vertical bar
400: Roof bar 401,401': Hook wing
402,402': Film fixing groove 403: T groove
404: fastening bolt 405: fastening nut
500,500': Loop arm 501: Upper locking jaw
502: Lower resting ledge 503,503': Fastening groove
504: Cut-out fitting
510: Pressure fixture 511: Burnt district
600: High-performance fluororesin film
610: EPDM-Ring
700: Angle bracket 701: Front plate
702: Rear plate 703,703': Slope portion
704,704': Bend end 705,705': Fastener
706: Tightening bolt 707: Tightening nut
800: support bar 801: fastening hole
802: Upper resting groove 803,803': Lower support

Claims (5)

The ends of the vertical supports (100) (100') arranged at regular intervals are connected to each other in the vertical and horizontal directions by horizontal bars (200) (200') and vertical bars (300) (300'), and adjacent to each other A roof bar 400 spaced upward is placed between the vertical bars 300 and 300', and the vertical bars 300 and the roof bar (300') are provided through separately provided roof arms 500 and 500'. 400) forms a greenhouse frame (F) connected and fixed at an angle, and the vertical bars (300) (300'), roof bars (400), and roof arms (500) (500') of the greenhouse frame (F) A high-performance fluoropolymer film (600) is tightly fixed to the entire loop of the structure including,
The above-mentioned roof bar 400 is placed between the ends of the mutually opposed roof arms 500 and 500', and both roof arms 500 are disposed in a downward slope with respect to the roof bar 400 as described above. ) (500') is coupled and fixed through a separately provided angle bracket 700, and the roof bar 400 is a separately provided spacer disposed between the ends of the roof arm 500 and (500'). In the greenhouse structure for a smart farm system employing a high-performance fluoropolymer film configured to be extended and connected by a support bar 800,
The roof bar 400 forms outwardly protruding stopping wings 401 and 401' located at the bottom of both sides along the longitudinal direction and outwardly protruding film fixing grooves 402 and 402' located at the top of both sides, respectively. And, an upper locking protrusion 501 is formed at the tip of the roof arms 500 and 500' arranged oppositely on both sides of the roof bar 400, and is inserted into the lower side of the locking wings 401 and 401'. , the above-described stopping wings (401) (401') are placed on the upper stopping protrusion (501), and the film fixing grooves (402) (402') are used to form an end-curling structure of the high-performance fluororesin film (600). A greenhouse structure for a smart farm system employing a high-performance fluoropolymer film, characterized in that it is configured to insert an EPDM-Ring (610).
According to clause 1,
A separately provided support bar 800 is inserted into the lower part of the roof bar 400 so that the roof bar 400 is supported and connected and fixed by the support bar 800. A downwardly opening T groove 403 is formed on the lower side, and a vertically penetrating fastening hole 801 is formed in the support bar 800, so that the fastening bolt 404 inserted into the T groove 403 is connected to the fastening hole 810. ), the roof bar 400 and the supporting bar 800 are coupled and fixed by the combination of the fastening nut 405,
An upper resting groove 802 is formed on the upper side of the supporting bar 800 in which the lower part of the roof bar 400 is placed, and lower supports on both sides protrude downward along the longitudinal direction on the lower side of the supporting bar 800. (803) (803') is formed so that the fastening nut (405) is accommodated between the lower supports (803) (803'), and the loop arm (500) corresponding to the lower supports (803) (803') A lower resting ledge 502 is formed at the tip of (500') so that the lower supports 803 and 802' of the support bar 800 are mounted on the lower resting ledge 502. Greenhouse structure for smart farm system using fluoropolymer film.
According to clause 1,
Fastening grooves 503 and 503' are formed along the longitudinal direction on both lower sides of the loop arms 500 and 500', and are connected by angle brackets 700 through the fastening grooves 503 and 503'. The tip of the pair of loop arms (500) (500') is fixed,
The angle bracket 700 is provided with a front plate 701 and a rear plate 702 by moving the metal plate upward, and the front plate 701 and the rear plate 702 of the angle bracket 700 are installed on both sides. Forms downward inclined surface portions 703 and 703', and on the inclined surface portions 703 and 703', bent ends are formed by bending the front ends of the front plate 701 and the rear plate 702 in opposite directions. (704) (704') is formed so that the bent ends (704) (704') are respectively inserted into the fastening grooves (503) (503') on both sides of the loop arm (500) (500'), and the front A plurality of tightening holes 705 and 705' are formed through the plate 701 and the rear plate 702, and a tightening bolt 706 and a tightening nut 707 are inserted and fastened into the tightening holes 705 and 705'. ) is configured so that the fixation of the roof arm (500) (500') by the angle bracket (700) and the assembly inclination angle of the roof arm (500) (500') by the inclined surface portion (703) (703') are formed. A greenhouse structure for a smart farm system employing a high-performance fluoropolymer film characterized by .
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