KR101835681B1 - Greenhouse - Google Patents

Abstract

According to an embodiment of the present invention, a greenhouse includes: an inner frame unit which is arranged on the ground surface while forming a cultivation space; an outer frame unit which is installed on the exterior of the inner frame unit to correspond to the inner frame unit on the ground surface; a frame back unit which is arranged between the inner and outer frame units and has a storage space for partially storing a bubbling liquid therein while being expanded or contracted; and a bubble generating unit which is connected to the frame back unit to be inserted into the storage space and generating bubbles with the bubbling liquid. The bubble generating unit supplies air to the storage space of the frame back unit to expand the frame back unit and generate bubbles with the bubbling liquid to fill the frame back unit with the bubbles. The bubbles generated with the bubbling liquid in the frame back unit are stored in the frame back unit. The greenhouse has simple configuration elements for generating the bubbles for thermal insulation, easily recovers the bubbling liquids for generating the bubbles to enable reuse, and cultivates plants during winter while maintaining the room temperature without using hot air.

Description

Greenhouse {GREENHOUSE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a greenhouse, and more particularly, to a greenhouse for storing a foam liquid and generating foam to improve insulation and insulation.

The greenhouse is a structure that can freely grow plants by artificially controlling light, temperature, humidity and so on. Such a greenhouse can be maintained at a high internal temperature because the external surface of the single layer is surrounded by a transparent material such as a synthetic resin film, glass, etc. to transmit sunlight and solar heat and external air is not introduced into the interior. Within the greenhouse, plants can be grown throughout the year, and plant harvests can be regulated.

On the other hand, in winter, the outside temperature is lowered, and the greenhouse has a lowered internal temperature due to the loss of internal heat. In addition, due to the intense direct sunlight and the high temperature of the outside temperature in the summer, the greenhouse has an internal temperature which is higher than necessary. As a result, the greenhouse is provided with heating facilities (for example, a fireplace, a boiler, etc.) or a cooling facility (for example, an air conditioner, etc.) so that the internal temperature of the greenhouse is maintained at an appropriate level. However, these facilities require significant installation and maintenance costs.

In addition, a heat shield is applied to the greenhouse. The heat shield is located on the outer surface of the greenhouse to cover the greenhouse and provide the warmth and shade function to the greenhouse. Such a heat cover can be easily applied to a relatively small greenhouse, but it is cumbersome to unfold and open when applied to a relatively large greenhouse. In a relatively large greenhouse, a separate mechanism is installed to open and close the cover. However, the thermal cover is bulky and can be spread smoothly by the machine, it may not be opened, and it may not work properly when it is snowy or rainy.

The greenhouse consists of a dual structure, and a protective layer is formed between the structures. The protective layer is filled with air to provide temperature control and thermal effect. It is difficult to achieve temperature control and thermal effect by using only air, and the protective layer may be filled with bubbles. In general, bubbles are generated using foam liquid and air. However, the foam generator has a complicated structure for supplying and recovering the foam liquid.

Technical Solution According to the technical idea of the present invention, a greenhouse is to provide a greenhouse which simplifies the components generating bubbles for insulation and insulation.

The technical problem to be solved by the greenhouse according to the technical idea of the present invention is to provide a greenhouse which can easily recover the foam liquid used for generation of foam and reusable.

The technical idea of the greenhouse according to the present invention is to provide a greenhouse for maintaining indoor temperature so that plants can be cultivated in winter without using hot air.

The technical problem to be solved by the greenhouse according to the technical idea of the present invention is not limited to the above-mentioned problems, and another problem which is not mentioned can be clearly understood by the ordinary skilled in the art from the following description.

According to an aspect of the present invention, there is provided a greenhouse comprising: an inner frame part positioned on a ground surface while forming a cultivation space; An outer frame portion located on the outside of the inner frame portion to correspond to the inner frame portion on the ground; A frame bag positioned between the inner frame part and the outer frame part, the frame bag part having a storage space partially storing foam liquid and expanding and contracting; And a foam generating unit inserted into the storage space and connected to the frame bag unit to generate a foam liquid. The foam generator supplies air to the storage space of the frame bag unit to expand the frame bag unit, And the foam liquid changed from the foam in the frame bag portion is stored inside the frame bag portion.

Each of the inner frame portion and the outer frame portion is composed of a pair of wall frame portions positioned along the longitudinal direction of the cultivation space while forming a cultivation space on the ground surface; And a roof frame portion positioned to connect the upper end of the wall frame portion and closing an upper surface of the cultivation space, the frame bag portion comprising: a wall bag portion forming a storage space corresponding to the wall frame portion; And a roof back which can be brought into contact with the wall back and forms a storage space to correspond to the roof frame part.

The greenhouse may further include a backrest portion which is positioned between the inner frame portion and the outer frame portion and supports the frame bag portion and on which a part of the frame bag portion storing the foam liquid is laid.

In addition, the backrest portion includes: a wall-mounted backrest portion which is positioned on the ground between the inner frame portion and the outer frame portion and which supports the lower surface of the wall back portion and on which the lower portion of the wall back portion is placed; And a roof backrest which is supported by the wall frame portion and supports the lower surface of the roof back portion and on which the lower portion of the roof back portion is laid.

Further, the foam generating portion may be connected to the inside of the lower portion of the wall back portion, and may be connected to the inside of the lower portion of the roof back portion.

The bubble generating unit may include a supply pipe portion having a tubular shape, a plurality of supply holes formed on an outer circumferential surface thereof, a supply pipe portion inserted into a storage space of the frame bag portion and immersed in the foam liquid; A connection pipe portion connected to one longitudinal end face of the supply pipe portion; And an air supply unit connected to the connection piping unit and supplying air to the supply piping unit. When the air supply unit supplies air to the supply piping unit through the connection piping unit, the air passes through the supply hole and bubbles the foam liquid And bubbles can fill the storage space.

The greenhouse further includes a foam liquid guiding portion connecting the wall back portion and the roof back portion to guide the foam liquid from the roof back portion to the wall back portion and to guide the foam liquid from the wall back portion to the roof back portion, To the wall back portion, and when the air supply portion supplies air to the roof back portion of the frame back portion, the foam liquid can be guided from the wall back portion to the roof back portion.

The foam liquid guiding portion includes a recovery pipe portion for guiding the foam liquid from the roof back portion to the wall back portion; An induction pump portion accommodated in the storage space of the wall back portion and immersed in the foam liquid; And an induction pipe portion connecting the induction pump portion and the roof back portion. When the air supply part supplies air to the roof back part of the frame back part, the recovery pipe part is closed, and the induction pump part sucks the foam liquid and sends the foam liquid to the roof back part through the induction pipe part Can supply.

In addition, a check valve is provided in the induction pipe portion so that the check valve can prevent the foam liquid from flowing back from the roof back portion to the wall back portion through the induction pipe portion.

The greenhouse may further include an opening / closing part connected to the frame bag part to move at least a part of the frame bag part to open / close the cultivation space.

The opening and closing part is connected to an upper surface of the wall back part and opens and closes the wall frame part of the outer frame part and the wall frame part of the inner frame part by expanding or folding the wall back part by moving the upper surface of the wall part back and forth. The roof frame portion of the outer frame portion and the roof frame portion of the inner frame portion are separated from each other by separating the roof frame portion and the roofing bag portion from the upper end of the roofing bag portion into two along the longitudinal direction of the roofing bag portion, And a roof opening and closing part that opens and closes the space.

The wall opening / closing portion includes a wall connecting shaft portion formed in a bar shape and connected to the upper surface of the wall back portion along the upper surface of the wall back portion; A rotatable wall driving unit which is formed in a bar shape and is located on the cultivation space side so as to be in parallel with the wall connection shaft portion; A wall guide portion positioned on the upper side of the wall driving portion and in parallel with the wall driving portion; And a wall rope portion extending from the wall connecting shaft portion and connected to the wall driving portion through a wall guiding portion and wound or unwound to the wall driving portion. When the wall rope is wound on the wall driving portion, the wall connecting shaft portion moves upward, When the wall rope is released from the wall driving portion, the wall connecting shaft portion is moved downward, and the wall back portion is folded so that the wall frame portion of the outer frame portion and the wall portion of the inner frame portion It is possible to open the space between the wall frame portions.

Further, the roof frame portion is formed in an arch shape, and the roof opening / closing portion includes a pair of roof connecting shaft portions which are formed in a pair and which are formed in a bar shape and which are located between the roof back portions separated from each other, ; A rotatable roof driving part positioned between the inner frame part and the outer frame part between the roof connecting shaft parts and parallel to the roof connecting shaft part; A roof guiding part located at a lower side of the roof driving part and installed at a roof frame part of the inner frame part; And a roof rope portion extending from the roof connecting shaft portion and wound around the roof driving portion and connected to the roof connecting shaft portion through the roof guide portion, wherein the roof driving portion is rotated to wind or unwind the roof rope portion, To move it closer or further away, and to fold or fold the roof back.

Further, the roof rope portion includes a first rope portion wound on the roof driving portion when the roof connecting shaft portions are close to each other; And a second rope portion connected to the first rope portion and wound on the roof driving portion when the roof connecting shaft portions are moved apart from each other, wherein when the first rope portion is wound on the roof driving portion, And the roof connecting parts move along the frame part to close each other and the roof back part unfolds to close the roof frame part of the inner frame part and the roof frame part of the outer frame part and when the second rope part is wound on the roof driving part, The roof frame portion of the inner frame portion and the roof frame portion of the outer frame portion can be opened while the roof back portion is folded.

The bag opening / closing part closes the storage space. When the foam generating part supplies the air to the storage space and the inner pressure of the frame bag is equal to or more than the set value, the bag opening / Is opened to be discharged from the storage space, and when the inner pressure of the frame bag reaches a set value, the bag opening and closing part can be closed.

The greenhouse according to the embodiments of the technical idea of the present invention has the following effects.

(1) The components that generate foam for insulation and insulation are simple.

(2) The foam liquid used for the generation of foam can be easily recovered and reused.

(3) Room temperature is maintained so that plants can grow in winter without using hot air.

However, the effects that the greenhouse according to an embodiment of the present invention can achieve are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description .

BRIEF DESCRIPTION OF THE DRAWINGS A brief description of each drawing is provided to more fully understand the drawings recited herein.
1 is a perspective view illustrating a greenhouse according to a preferred embodiment of the present invention.
FIG. 2 is a perspective view showing a state in which the frame bag portion of the greenhouse shown in FIG. 1 is filled with bubbles.
Fig. 3 is a view showing a state in which the foam generator is coupled to the inside of the frame bag in the greenhouse shown in Fig. 1. Fig.
4 is a view showing a state in which the greenhouse shown in Fig. 1 is closed by an opening / closing part.
Fig. 5 is a view showing a state in which the greenhouse shown in Fig. 1 is opened by an opening / closing part.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the intention is not to limit the invention to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In addition, numerals (e.g., first, second, etc.) used in the description of the present invention are merely an identifier for distinguishing one component from another.

Also, in this specification, when an element is referred to as being "connected" or "connected" with another element, the element may be directly connected or directly connected to the other element, It should be understood that, unless an opposite description is present, it may be connected or connected via another element in the middle.

In addition, an element represented by '~' in the present specification may be a structure in which two or more elements are combined into one element, or one element may be divided into two or more functions according to a finer function. In addition, each of the components to be described below may additionally perform some or all of the functions of the other components in addition to the main functions of the component itself, and some of the main functions And may be performed entirely by components.

Hereinafter, exemplary embodiments of the present invention will be described in detail.

FIG. 1 is a perspective view showing a greenhouse 100 according to a preferred embodiment of the present invention. FIG. 2 is a perspective view showing a state in which a frame bag portion 103 of a greenhouse 100 shown in FIG. 1 is filled with bubbles And FIG. 3 is a view showing a state where the foam generating unit 105 is coupled to the inside of the frame bag 103 in the greenhouse shown in FIG. 1. FIG. 4 is a view showing the greenhouse 100 shown in FIG. Fig. 5 is a view showing a state in which the greenhouse 100 shown in Fig. 1 is opened by the opening / closing part 106. Fig.

1 to 5, a greenhouse 100 according to a preferred embodiment of the present invention includes an inner frame portion 101, an outer frame portion 102, a frame bag portion 103, a backrest portion 104, And a foam generation unit 105, and controls the state of the frame bag unit 103 according to the external environment of the greenhouse 100. [ The bubble generating unit 105 generates bubbles in the frame bag unit 103 to fill the frame bag unit 103 and to control the heat insulating and insulating performance of the greenhouse 100.

The inner frame portion 101 is placed on the ground while forming the cultivation space 100a. The cultivation space 100a is formed in a tunnel shape, and accommodates plants. The cultivation space 100a is shown in a tunnel shape as shown in FIGS. 1 and 2. However, the present invention is not limited thereto, and it is possible to form the cultivation space 100a in various shapes (for example, a dome shape, etc.) have. Further, the inner frame portion 101 is made of a framework.

The outer frame portion 102 is located on the ground and is located outside the inner frame portion 101 and spaced from the inner frame portion 101 and corresponds to the inner frame portion 101. The outer frame portion 102 is also made of a frame like the inner frame portion 101.

Further, the outer frame part 102 is covered with a frame cover made of a synthetic resin film or the like, and the frame cover can keep the cultivation space 100a closed. On the other hand, the frame cover can be folded and unfolded as needed, and can be used for opening and closing the cultivation space 100a.

The inner frame portion 101 includes the wall frame portion 111 and the roof frame portion 113 and the outer frame portion 102 includes the wall frame portion 121 and the roof frame portion 123 . Since the inner frame portion 101 and the outer frame portion 102 are the same in size and position except for the difference, the present embodiment can be applied to the wall frame portion 111 included in the inner frame portion 101, The frame unit 113 will be described.

The wall frame parts 111 are formed as a pair, and are positioned on the ground along the longitudinal direction of the cultivation space 100a. The cultivation space 100a is located between the wall frame parts 111. [

The roof frame part 113 connects upper ends of the wall frame part 111 with each other. The roof frame part 113 is positioned to close the upper surface of the cultivation space 100a and is formed in an arch shape.

The wall frame portion 121 and the roof frame portion 123 of the outer frame portion 102 are positioned so as to correspond to the wall frame portion 111 and the roof frame portion 113 of the inner frame portion 101, respectively.

The frame bag portion 103 is located between the inner frame portion 101 and the outer frame portion 102 and has a closed storage space 103a. The frame bag portion 103 may be inflated and contracted. The frame bag portion 103 may have a form of a bag made of a synthetic resin film or a form of a pair of synthetic resin films joined together.

The bubble liquid is stored in the storage space 103a. At this time, the foam liquid occupies the lower portion of the storage space 103a. The upper part of the storage space 103a is empty. Part of the foam generating part 105, which will be described in detail later, is inserted into the lower part of the storage space 103a to be in contact with the foam liquid. The foam generating unit 105 supplies air to the lower portion of the storage space 103a to bring the air into contact with the foam liquid. At this time, bubbles are generated in the storage space 103a and filled in the upper part of the storage space 103a. Here, the bubble is an aggregate of air bubbles, and after a lapse of a predetermined time, the bubble disappears or bursts in the upper part of the storage space 103a and turns into a bubble liquid. Such foam liquid may be introduced into the lower portion of the storage space 103a and may be generated as foam in the storage space 103a. Here, the foam liquid is a solution in which a solute such as a soap solution, glycerin, starch syrup, sugar, etc. is dissolved in a solvent such as water. As the amount of solute in the foam liquid is controlled, the foam can be generated from the foam liquid and held for more than one hour.

For example, when air is supplied to the storage space 103a, the frame bag portion 103 is inflated and brought into close contact with the inner frame portion 101 and the outer frame portion 102, (102). Since the foam liquid is stored in the lower part of the storage space 103a, the foam liquid comes into contact with the air and is generated as foam. Therefore, the frame bag portion 103 functions as a heat insulating and insulating layer in the greenhouse 100 due to the combination of the air supplied to the storage space 103a and the foam generated in the storage space 103a. The frame cover covering the outer frame portion 102 protects the frame bag portion 103 by blocking wind generated from the outside of the greenhouse 100 so that the frame bag portion 103 can be maintained in a constant shape.

On the other hand, when the frame bag portion 103 is contracted, the bubble is reduced or burst into a foamy liquid and stored in the lower portion of the storage space 103a, and the air is discharged from the upper portion of the storage space 103a. As a result, the heat insulating and insulating layer for the greenhouse 100 is reduced.

Further, the frame bag portion 103 includes a wall bag portion 131 and a roof bag portion 133.

The wall back part 131 forms a storage space 103a to correspond to the wall frame parts 111 and 121 and the roof back part 133 forms a storage space 103a to correspond to the roof frame parts 113 and 123 do. At this time, the wall back part 131 and the roof back part 133 are separated from each other, and the upper surface of the wall back part 131 is positioned adjacent to the side surface of the arch roof part 133.

Further, the frame back portion 103 is provided with a back opening and closing portion 103b. The back opening and closing unit 103b opens and closes the storage space 103a of the frame bag unit 103. [

When warming is required, the bag opening / closing part 103b closes the storage space 103a. At this time, when air is supplied to the storage space 103a, the frame bag portion 103 is inflated by air, and the bubbles are generated in the storage space 103a. Further, the internal pressure of the frame bag portion 103 increases.

When the inner pressure of the frame bag portion 103 exceeds the set value by the air and the foam, the bag opening / closing portion 103b is opened to discharge the air outside the frame bag portion 103. [ That is, the air is discharged from the storage space 103a of the frame bag portion 103 through the bag opening / closing portion 103b. At this time, the inner pressure of the frame bag 103 decreases. When the air is discharged from the storage space 103a of the frame bag portion 103 and the internal pressure of the frame bag portion 103 reaches the set value, the back opening / closing portion 103b is closed. On the other hand, when the frame bag portion 103 is retracted, the back opening / closing portion 103b is opened to discharge air from the storage space 103a of the frame bag portion 103. [ Therefore, the bag opening / closing part 103b can adjust the internal pressure of the frame back part 103 to prevent the frame back part 103 from being excessively inflated and damaged due to air and bubbles.

Here, the back opening / closing portion 103b is formed in the form of a thin and flexible vinyl hose, closed in a folded state, and can be opened while being released from a folded state. When the inner pressure of the frame bag portion 103 exceeds the set value, the back opening / closing portion 103b is released while being released, so that air can be discharged from the storage space 103a through the back opening / closing portion 103b. When the inner pressure of the frame bag 103 reaches the set value, the bag opening / closing part 103b is folded and closed to close the storage space 103a. At this time, the air is not discharged from the storage space 103a. Since the bag opening / closing part 103b is formed in the form of a thin and flexible vinyl hose, the opening and closing of the storage space 103a can be realized with low cost.

The back opening / closing portion 103b is preferably provided at the upper end of the wall back portion 131 so as not to discharge the foam liquid due to the back opening / closing portion 103b in the state that the frame back portion 103 stores the foam liquid, And is installed on the upper surface of the upper portion of the roof bag portion 133. [ That is, the back cover portion 103b is provided on the upper portion of the wall back portion 131 and the roof back portion 133, and is used for discharging air.

The back support portion 104 supports the frame back portion 103 between the inner frame portion 101 and the outer frame 102. [ Further, the backrest portion 104 is bent to form a predetermined space, and is positioned along the longitudinal direction of the cultivation space 100a. At this time, since the frame bag portion 103 stores the foam liquid, a portion of the bag back portion 103 storing the foam liquid can be placed on the backrest portion 104. [ Therefore, the frame bag section 103 can be stably stored with the foam liquid by the bag-receiving section 104. [ The backrest portion 104 includes a wall backrest portion 141 and a roof backrest portion 143. [

The wall backrest part 141 is positioned on the ground between the wall frame part 111 of the inner frame part 101 and the wall frame part 121 of the outer frame part 102, Lt; / RTI > The wall back part (131) is placed on the wall backrest part (141).

The roof back receiving portion 143 is supported by the wall frame portion 111 of the inner frame portion 101 and the wall frame portion 121 of the outer frame portion 102 so that the roof frame portion of the inner frame portion 101 113 and the roof frame part 123 of the outer frame part 102. [ The lower surface of the roof bag portion 133 is supported by the roof backrest portion 141. [ The shrunken roof bag 133 is laid on the roof backrest 143 while only the lower portion of the expanded roof bag 133 is laid on the roof backrest 13. [ That is, the lower portion of the roof back portion 133 is held on the roof back receiving portion 143.

The foam generating unit 105 is connected to the frame bag unit 103 and supplies air to the storage space 103a of the frame bag unit 103 to generate foam liquid stored in the lower portion of the storage space 103a. The generated bubbles fill the upper portion of the storage space 103a, thereby providing insulation and a warming effect for the greenhouse 100. The foam generation section 105 includes a supply pipe section 151, a connection pipe section 152, and an air supply section 153.

The supply pipe portion 151 is formed in a tubular shape and is inserted into the storage space 103a of the frame bag portion 103. [ Particularly, the supply pipe portion 151 is located below the wall back portion 131 and below the roof back portion 133. Further, the supply pipe portion 151 is immersed in the foam liquid stored in the frame bag portion 103, that is, the foam liquid in the storage space 103a.

A plurality of supply holes 151a are formed on the outer circumferential surface of the supply pipe portion 151. [ The supply hole 151a connects the inside of the supply pipe portion 151 with the outside. Here, the supply hole 151a is formed along the longitudinal direction of the cultivation space 100a.

The supply pipe portion 151 may be in the form of a vinyl tube. Thus, the supply pipe portion 151 can be easily carried for installation in the frame bag portion 103. Further, since the supply pipe portion 151 is made of vinyl, it can be floated on the surface of the foam liquid without being immersed in the foam liquid in the storage space 103a. Here, a guide shaft (not shown) may be inserted into the supply pipe portion 151. As a result, the supply pipe portion 151 can be held in a state of being immersed in the foam liquid by contacting the bottom surface of the storage space 103a.

The connection pipe portion 152 is connected to one longitudinal end face of the supply pipe portion 151. Here, the connection pipe portion 152 is positioned adjacent to the backrest portion 104. [ For example, when the supply pipe portion 151 is inserted into the lower portion of the wall back portion 131, the connection pipe portion 152 is located at the lower portion of the wall back portion 131 so as to be adjacent to the wall back portion 141 And is connected to the supply pipe section 151. When the supply pipe portion 151 is inserted into the lower portion of the roof back portion 133, the connection pipe portion 152 is connected to the supply pipe portion 151 located at the lower portion of the roof back portion 133 so as to be adjacent to the roof back portion 143. [ (151).

The air supply unit 153 is connected to the connection pipe unit 152 and is located outside the frame bag unit 103 and outside the cultivation space 100a. The air supply unit 153 supplies air to the supply piping unit 151 through the connection piping unit 152. At this time, air is supplied to the supply pipe portion 151, passes through the supply hole 151a, is divided and deformed in the form of air bubbles by the supply hole 151a, and is coupled with the foam liquid. As a result, bubbles are generated and filled in the storage space 103a of the frame bag portion 103.

On the other hand, the foam filled in the upper portion of the storage space 103a may be distorted or burst into a foamy liquid, and the foamy liquid may be guided to the lower portion of the storage space 103a and stored in the frame bag 103 as it is. When the air supply unit 153 supplies air to the supply piping unit 151, such foam liquid can be generated by bubbling again by air and used to fill the upper part of the storage space 103a.

The foam generating unit 105 of this embodiment generates air bubbles by supplying air to the foam liquid in the storage space 103a and fills the upper portion of the storage space 103a with foam. The foam liquid that has changed from the foam can be used again to generate foam by being introduced into the supply pipe portion 151 of the foam generating portion 105. [ That is, the foam generating unit 105 can be used in combination with the frame bag unit 103 to continuously generate foam liquid in the storage space 103a by bubbling.

In the greenhousing 100 of the present embodiment, the frame bag portion 103 stores the foam liquid in a state of being supported by the backrest portion 104. The foam generating part 105 is inserted into the frame bag part 103 and supplies air to the storage space 103a of the frame bag part 103. [ At this time, the air passes through the supply hole 151a of the supply pipe portion 151 of the foam generating portion 105, and the foam liquid is foamed. These bubbles are filled in the upper part of the storage space 103a. Further, in the upper part of the storage space 103a, the bubbles are reduced or burst into bubble liquids and stored in the lower part of the storage space 103a. These foam liquids can be used to generate foam again. Accordingly, the greenhouse 100 of the present embodiment can generate bubbles in a state in which the bubble liquid is stored in the frame bag 103, and does not need to supply or recover the bubble liquid after generating bubbles. A bubble that has collapsed or bursts in the storage space 103a can be used as a bubble liquid. That is, the foam liquid can be continuously used in the storage space 103a.

In addition, the greenhouse 100 of the present embodiment may further include an opening /

The opening and closing part 106 is connected to the frame back part 103 to move a part of the frame back part 103 particularly the upper end part of the wall back part 131 and the upper end part of the roof back part 133 upward, The cultivation space 100a is kept closed by using the frame bag portion 103 when the warming of the cultivation space 100a is required. The foam generator 105 generates bubbles in the frame bag 103 to fill the upper portion of the storage space 103a. Thus, the frame bag portion 103 can provide heat insulation, heat insulation, and light shielding function for the cultivation space 100a. In a state in which the lower portion of the wall bag portion 131 and the lower portion of the roof bag portion 133 are fixed, the opening and closing portion 106 realizes opening and closing of the cultivation space 100a.

The opening and closing part 106 moves the part of the frame back part 103, in particular, the upper end of the wall back part 131 and the upper end part of the roof back part 333 downward to open the cultivation space 100a, ). At this time, the foam drops or comes into contact with the inner surface of the frame bag portion 103 to become a foam liquid, and the foam liquid is stored in the storage space 103a of the frame bag portion 103.

The opening and closing part 106 includes a wall opening and closing part 161 and a roof opening and closing part 163.

The wall opening / closing part 161 is connected to the upper surface of the wall back part 131 of the frame back part 103. The upper surface of the wall back part (131) moves up and down by the wall opening / closing part (161). As a result, the wall bag portion 131 opens and closes a part of the wall in the greenhouse 100 while unfolding and folding. The wall opening and closing portion 161 includes a wall connecting shaft portion 161a, a wall driving portion 161b, a wall guide portion 161c, and a wall rope portion 161d.

The wall connection shaft portion 161a is formed in a bar shape and is positioned on the upper surface of the wall back portion 131 and connected thereto. The wall connection shaft portion 161a is located between the wall frame portion 111 of the inner frame portion 101 and the wall frame portion 121 of the outer frame portion 102 along the upper surface of the wall back portion 131. [

The wall driving portion 161b is formed in a bar shape and is disposed in the wall space frame portion 111 of the inner frame portion 101 so as to be in parallel with the wall connecting shaft portion 161a and located on the side of the growing space 100a. The wall driving part 161b is rotated about the central axis along the longitudinal direction of the wall driving part 161b.

The wall guide portion 161c is located on the upper side of the wall driving portion 161b and is installed on the wall frame portion 111 of the inner frame portion 101 so as to be parallel to the wall driving portion 161b. A plurality of wall guide portions 161c are formed in the form of rollers, and are spaced apart from each other along the wall driving portion 161b.

The wall rope portion 161d extends from the wall connection shaft portion 161a to connect the wall guide portion 161c to the wall drive portion 161b. That is, one end of the wall rope portion 161d is connected to the wall connecting shaft portion 161a, and the other end portion of the wall rope portion 161d is wound around the wall driving portion 161b. Here, the wall driving portion 161b is rotated to wind or unwind the wall rope portion 161d.

The wall opening / closing unit 161 operates as follows to open / close the cultivation space 100a.

When the wall rope portion 161d is wound around the wall driving portion 161b, the wall connecting shaft portion 161a moves upward, and the wall back portion 131 is unfolded to close the wall of the greenhouse 100. [ As a result, the cultivation space 100a is closed.

On the other hand, when the wall rope portion 161d is released from the wall driving portion 161b, the wall connecting shaft portion 161a moves downward, and the wall back portion 131 is folded to open the wall of the greenhouse 100. [ As a result, the cultivation space 100a is opened.

When the wall rope portion 161d is wound or unwound by the wall drive portion 161b, a part of the wall rope portion 161d contacts the wall guide portion 161c to rotate the wall guide portion 161c. The wall guide portion 161c can minimize the friction with the wall rope portion 161d while keeping the wall rope portion 161d between the wall connection shaft portion 161a and the wall drive portion 161b constant in length have.

The roof opening and closing part 163 is connected to the center of the roof back part 133 along the longitudinal direction of the frame back part 103 to separate the roof back part 133 into two along the longitudinal direction of the frame back part 103. [ At this time, each first side face of the roof back part 133 is supported by the roof back receiving part 143. The roof opening / closing portion 163 adjusts the spacing between the two roof back portions 133 separated into two. At this time, the gap between the roof back portions 133 is adjusted based on the center of the roof frame portion 113 of the inner frame portion 101. [ That is, the roof opening / closing portion 163 moves along the width direction of the cultivation space 100a. Thus, the roof bag portion 133 opens and closes a part of the roof in the greenhouse 100 while opening and closing the top portion of the greenhouse 100, thereby opening and closing the uppermost portion of the greenhouse 100. The roof opening and closing portion 163 includes a roof connecting shaft portion 163a, a roof driving portion 163b, a roof guide portion 163c, and a roof rope portion 163d.

The roof connecting shaft portions 163a are formed as a pair, and are formed in a bar shape and located between the roof back portions 133 separated from each other. At this time, the roof connecting shaft portions 163a are positioned and connected to the respective second side surfaces of the roof back portion 133, and are positioned so as to correspond to each other. The roof connecting shaft portion 163a is located between the roof frame portion 113 of the inner frame portion 101 and the roof frame portion 123 of the outer frame portion 102 along the longitudinal direction of the cultivation space 100a.

The roof driving portion 163b is formed in a bar shape and is disposed between the roof frame portion 113 of the inner frame portion 101 and the roof frame portion 123 of the outer frame portion 102 between the roof connecting shaft portions 163a And is installed in the roof frame part 123 of the outer frame part 102. [ At this time, the roof driving part 163b is rotated about the central axis parallel to the roof connecting shaft part 163a and along the longitudinal direction of the roof driving part 163b.

The roof guide portion 163c is positioned below the roof driving portion 163b and is installed in the roof frame portion 113 of the inner frame portion 101. [ A plurality of roof guide parts 163c are formed in the form of rollers, and are spaced apart from each other along the roof driving part 163b.

The roof rope portion 163d extends from the roof connecting shaft portion 163a and is wound around the roof driving portion 163b and connected to the roof connecting shaft portion 163a through the roof guide portion 163c. That is, both ends of the roof rope portion 163d are connected to the roof connecting shaft portion 163a, with the roof rope portion 163d being positioned over the roof driving portion 163b and the roof guide portion 163c. The roof driving portion 163b is rotated so as to wind or loosen the roof rope portion 163d. Here, the roof rope portion 163d is formed in the first rope portion 163d 'and the first rope portion 163d' wound on the roof driving portion 163b when the distance between the roof connecting shaft portions 163a is reduced And the second rope portion 163d 'wound around the roof driving portion 163b when the distance between the roof connecting shaft portions 163a is increased in the connected state. That is, when the first rope portion 163d 'is wrapped around the roof driving portion 163b, the second rope portion 163d' 'is unwound from the roof driving portion 163b and the first rope portion 163d' The second rope portion 163d "is wound on the roof driving portion 163b.

The roof opening / closing unit 163 operates as follows to open / close the cultivation space 100a.

The roof connecting shaft portions 163a move closer to each other along the roof frame portion 113 of the inner frame portion 101 when the first rope portion 163d 'is wound around the roof driving portion 163b. Further, the roof connecting shaft portion 163a pulls the second rope portion 163d ", and the second rope portion 163d "is released from the roof driving portion 163b. When the roof connecting shaft portions 163a come into contact with each other, the roof bag portion 133 unfolds and closes the roof of the greenhouse 100. [ As a result, the cultivation space 100a is closed.

On the other hand, when the second rope portion 163d "is wound around the roof driving portion 163b, the roof connecting shaft portion 163a pulls the first rope portion 163d ', and the first rope portion 163d' The roof connecting shaft portions 163a are moved away from each other along the roof frame portion 113 of the inner frame portion 101. The roof back portion 133 is folded to the greenhouse 100 Thereby opening the cultivation space 100a.

When the roof rope portion 163d is wound or unwound by the roof driving portion 163b, a part of the roof rope portion 163d contacts the roof guide portion 163c to rotate the roof guide portion 163c. The roof guide portion 163c can minimize the friction with the roof rope portion 1613 while keeping the length of the roof rope portion 163d between the roof connecting shaft portion 163a and the roof driving portion 163b constant. have.

Further, when the roof frame part 113 is formed in an arch shape, the roof connecting shaft parts 163a can be further moved away from each other more easily along the roof frame part 113. [

The greenhouse 100 of the present embodiment moves the upper end of the wall back part 131 and the upper end of the roof back part 133 by the opening and closing part 106 to open and close the cultivation space 100a. At this time, the bubble of the frame bag portion 103 turns into bubble liquid, and is stored in the frame bag portion 103.

In addition, the greenhouse 100 of the present embodiment may further include a foam liquid guiding portion 107.

The foam liquid guiding portion 107 connects the wall back portion 131 and the roof back portion 133 in the frame back portion 103. [ Generally, the foam liquid guiding portion 107 guides the foam liquid from the roof bag portion 133 to the wall bag portion 131. When the air supply unit 153 supplies air to the supply pipe unit 151 through the connection pipe unit 152, the foam liquid guiding unit 107 conveys the foam liquid from the wall bag unit 131 to the roof bag unit 133 . Therefore, the foam liquid can be generated as foam even if it is not stored in the storage space 103a of the roof bag part 133. [ The load due to the foam liquid stored in the roof bag portion 133 is reduced, and deformation of the wall frame portions 111 and 121 due to the foam liquid can be prevented.

The foam liquid guiding portion 107 includes a recovery pipe portion 171, an induction pump portion 172, and an induction pipe portion 173.

The recovery piping section 171 connects the wall bag section 131 and the roof bag section 133 together. The foam liquid is led from the roof back part 133 to the wall back part 131 through the recovery piping part 171. As a result, the foam liquid may not be stored in the roof bag portion 133.

The induction pump unit 172 is in the form of an underwater pump, is accommodated in the storage space 103a of the wall back part 131, and is immersed in the foam liquid.

The induction pipe portion 173 connects the induction pump portion 172 and the supply pipe portion 151 housed in the roof back portion 133. [ The induction pump unit 172 sucks the foam liquid and supplies the foam liquid to the supply pipe unit 151 inserted into the roof bag part 133 through the induction pipe unit 173. [ At this time, the air supply unit 153 supplies air to the supply pipe unit 151 housed in the roof bag unit 133. Thus, the air can be generated as foam by passing through the supply hole 151a of the supply pipe portion 151. [ Bubbles are generated in the storage space 103a of the roof bag part 133. [

On the other hand, when the air is not supplied to the supply pipe portion 151 accommodated in the roof bag portion 133, the induction pipe portion 173 is closed. As a result, the foam liquid may not be introduced into the roof bag portion 133 where no foam is generated. When the air is supplied to the supply pipe portion 151 accommodated in the roof bag portion 133, the recovery pipe portion 171 is closed and the induction pipe portion 173 is opened, And can be led to the roof bag portion 133. [

Particularly, in order to open and close the induction pipe portion 173, a check valve may be provided in the induction pipe portion 173. [ The bubble liquid may not flow back from the roof back part 133 to the wall back part 131 due to the opening and closing of the guide piping part 173 by the check valve.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Various modifications and variations are possible.

100: Greenhouse
101: inner frame part 102: outer frame part
111, 121: a wall frame part 113, 123: a roof frame part
103: frame back part 131: wall back part
133: Roof bag part 103a: Storage space
103b:
104: backrest part 141: wall backrest part
143: Roof backrest part
105: foam generation unit 151: supply pipe unit
152: connection piping section 153: air supply section
106:
161: wall opening / closing part 163:
161a: wall connecting shaft portion 161b: wall driving portion
161c: wall guide portion 163d: wall rope portion
163a: roof connecting shaft part 163b: roof driving part
163c: roof guide part 163d: roof rope part
107: foam liquid guiding portion 171: return pipe portion
172: induction pump unit 173: induction pipe unit

Claims (14)

An inner frame part positioned on the ground to form a cultivation space;
An outer frame portion located on the outside of the inner frame portion to correspond to the inner frame portion on the ground;
A frame bag positioned between the inner frame part and the outer frame part, the frame bag part having a storage space partially storing foam liquid and expanding and contracting;
A foam generator connected to the frame bag and inserted in the storage space, the foam generator generating foam liquid; And
And an opening / closing part connected to the frame bag part to open / close the cultivation space by moving at least a part of the frame bag part,
The foam generating part supplies air to the storage space of the frame bag part to inflate the frame bag part, generate the foam liquid as foam, and fill the frame bag part,
The foam liquid, which has changed from the foam in the frame bag portion, is stored inside the frame bag portion,
Each of the inner frame portion and the outer frame portion includes:
A wall frame part formed as a pair and positioned along the longitudinal direction of the cultivation space while forming a cultivation space on the ground; And
And a roof frame portion positioned to connect an upper end of the wall frame portion and closing an upper surface of the cultivation space,
The frame bag,
A wall bag portion forming a storage space corresponding to the wall frame portion; And
And a roof bag portion which can be brought into contact with the wall bag portion and forms a storage space to correspond to the roof frame portion,
The opening /
A wall opening / closing part connected to an upper surface of the wall back part and vertically moving the upper surface of the wall back part so as to expand or fold the wall back part to open / close between the wall frame part of the outer frame part and the wall frame part of the inner frame part; And
The roofing bag portion is separated from the upper end of the roofing back portion in two along the longitudinal direction of the roofing back portion and the gap between the roofing back portions is adjusted to expand or collapse the roofing back portion so that the roof frame portion of the outer frame portion and the roof frame portion of the inner frame portion And a roof opening / closing part for opening /
The roof frame portion is formed in an arch shape,
The roof opening /
A roof connecting shaft portion which is formed as a pair and which is formed in a bar shape and which is located between the roof back portions separated from each other and connected to each of the roof back portions;
A rotatable roof driving part positioned between the inner frame part and the outer frame part between the roof connecting shaft parts and parallel to the roof connecting shaft part;
A roof guiding part located at a lower side of the roof driving part and installed at a roof frame part of the inner frame part; And
And a roof rope portion extending from the roof connecting shaft portion and wound around the roof driving portion to connect the roof guide portion to the roof connecting shaft portion,
The roof drive is rotated to wind or unroll the roof rope to move the roof connection shafts closer or farther from each other, to unfold or fold the roof back,
The roof rope portion,
A first rope portion wound around the roof driving portion when the roof connecting shaft portions come close to each other; And a second rope portion connected to the first rope portion and wound on the roof driving portion when the roof connecting shaft portions are moved apart from each other,
When the first rope portion is wound on the roof driving portion, the roof connecting shaft portions move closer to each other along the roof frame portion of the inner frame portion, and the roof back portion unfolds to close the roof frame portion of the inner frame portion and the roof frame portion of the outer frame portion,
When the second rope portion is wound on the roof driving portion, the roof connecting shaft portions are moved away from each other along the roof frame portion of the inner frame portion, and the roof back portion is folded to open the roof frame portion of the inner frame portion and the roof frame portion of the outer frame portion Features a greenhouse.
delete The greenhouse according to claim 1,
Further comprising a backrest portion positioned between the inner frame portion and the outer frame portion and supporting the frame bag portion and on which a part of the frame bag portion storing the foam liquid is laid.
The backrest according to claim 3,
A wall-mounted backrest positioned on the ground between the inner frame part and the outer frame part and supporting the lower face of the wall back part and having a lower part of the wall back part; And
And a roof back support portion supported on the wall frame portion and supporting the lower surface of the roof back portion and having a lower portion of the roof back portion laid thereon.
The method according to claim 1,
Wherein the foam generating part is connected to the inside of the lower part of the wall back part and is connected to the inside of the lower part of the roof back part.
The bubble generator according to claim 1,
A supply pipe portion formed in a tubular shape and having a plurality of supply holes formed on an outer circumferential surface thereof and inserted into a storage space of the frame bag portion to be immersed in the foam liquid;
A connection pipe portion connected to one longitudinal end face of the supply pipe portion; And
And an air supply unit connected to the connection pipe unit and supplying air to the supply pipe unit,
Wherein when the air supply part supplies air to the supply piping part through the connection piping part, the air passes through the supply hole to generate foam liquid, and the foam fills the storage space.
The greenhouse according to claim 1,
And a foam liquid guiding part connecting the wall back part and the roof back part to guide the foam liquid from the roof back part to the wall back part and guide the foam liquid from the wall back part to the roof back part,
Wherein the foam liquid guiding portion guides the foam liquid from the roof back portion to the wall back portion, and when the air supply portion supplies air to the roof back portion of the frame back portion, the foam liquid is guided from the wall back portion to the roof back portion.
8. The bubble generating device according to claim 7,
A recovery pipe portion for guiding the foam liquid from the roof back portion to the wall back portion;
An induction pump portion accommodated in the storage space of the wall back portion and immersed in the foam liquid; And
And an induction pipe portion connecting the induction pump portion and the roof back portion.
The recovery piping section guides the foam liquid from the roof back portion to the wall back portion,
Wherein the return pipe portion is closed when the air supply portion supplies air to the roof back portion of the frame bag portion and the induction pump portion sucks the foam liquid and supplies the foam back portion to the roof back portion through the induction pipe portion.
delete delete The apparatus according to claim 1, wherein the wall opening /
A wall connection shaft portion formed in a bar shape and connected to the upper surface of the wall back portion along the upper surface of the wall back portion;
A rotatable wall driving part which is formed in a bar shape and is located in a cultivation space so as to be in parallel with the wall connection shaft part;
A wall guide portion positioned on the upper side of the wall driving portion and in parallel with the wall driving portion; And
And a wall rope portion extending from the wall connection shaft portion and connected to the wall drive portion through a wall guide portion and wound or unwound by the wall drive portion,
When the wall rope portion is wound on the wall driving portion, the wall connecting shaft portion moves upward, and the wall back portion unfolds to close the space between the wall frame portion of the outer frame portion and the wall frame portion of the inner frame portion,
Wherein when the wall rope portion is released from the wall driving portion, the wall connecting shaft portion is moved downward, and the wall back portion is folded to open between the wall frame portion of the outer frame portion and the wall frame portion of the inner frame portion.
delete delete The method according to claim 1,
A back opening / closing part is provided in the frame bag part to open / close the storage space,
The bag opening / closing part closes the storage space,
When the foam generating section supplies air to the storage space and the internal pressure of the frame bag portion is equal to or higher than the set value, the bag opening / closing portion is opened to discharge the air from the storage space,
And when the inner pressure of the frame bag reaches the set value, the bag opening / closing part is closed.

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