KR101436149B1 - cultivation greenhouse for vegetation - Google Patents

Abstract

The present invention relates to a plant growing greenhouse, and more particularly, to a plant growing greenhouse capable of emitting durability by making wall and floor as loess, heating the wall and floor, will be.
The plant growing greenhouse of the present invention comprises a cultivation room having a wall and a bottom made of yellow clay and having a projection roof at the top thereof, a support tray installed inside the cultivation room for supporting the planting container for planting the plant, And heating means for heating the floor to emit far-infrared rays into the cultivation chamber and adjusting the temperature of the cultivation chamber.

Description

Cultivation greenhouse for vegetation}

The present invention relates to a plant growing greenhouse, and more particularly, to a plant growing greenhouse capable of emitting durability by making wall and bottom as loess, heating the wall and floor, and emitting far infrared rays useful for plant growth with temperature control will be.

In general, greenhouses are used to grow various fruits and vegetables regardless of season.

Such a greenhouse is made of a vinyl material such as a vinyl chloride film, a polyethylene film, and a vinyl acetate film, and the frame of a greenhouse is made of a steel material such as a zinc-molten round steel pipe, a square pipe, a spring steel diaphragm, And assembly materials. It is a facility that is widely used in farmhouses because the installation cost is low and it can be easily constructed.

Greenhouse has less light transmittance, warmth, environmental control and safety compared to glass greenhouse. It is able to grow crops such as fruit trees, sidelights and flowers by heating and keeping warm in summer and winter. It is used in the whole country.

However, there is a problem that the plastic house is easily damaged or deformed by external factors such as strong wind due to its low structural strength.

The present invention provides a plant growing greenhouse capable of radiating far-infrared rays useful for plant growth with temperature control by heating walls and floors to increase durability by making wall and floor as loess, It has its purpose.

To achieve the above object, a plant growing greenhouse of the present invention comprises: a cultivation room having a wall and a floor made of yellow soil and having a projection roof at the top; A support tray installed inside the cultivation room for supporting a planting container in which plants are planted; And heating means for heating the wall and bottom of the cultivation room to emit far-infrared rays into the cultivation room and adjusting the temperature of the cultivation room.

The heating means includes a heater embedded in the wall and a floor, and a power supply unit for supplying power to the heater.

The heating means includes a hot water pipe embedded in the wall and the floor, and a hot water supply unit for supplying hot water to the hot water pipe.

The cultivation room further includes a moisture barrier cover for covering the floor to prevent water from penetrating into the floor.

The support tray is provided with pillars provided at regular intervals, a guide rail fixed to the pillars and horizontally installed, a bed slidably movably mounted on the guide rail to seat the food preparation container, And a heating unit for transferring heat to the planting container.

The planting container includes a base portion that is formed in a cylindrical shape so that the soil can be filled in the planting container, a top portion of which is opened, a tubular cover portion that is opened at the bottom, and a cover portion that is joined to the top portion of the base portion, A cover portion and a base portion, the cover portion and the base portion being rotatable with respect to each other in such a way that the cover portion and the base portion can rotate with each other; And a means for harvesting the seedlings.

As described above, according to the present invention, it is possible to increase the durability of the greenhouse by making the wall and the floor of the greenhouse as loess, and the temperature can be controlled by heating the wall and the floor.

In addition, it is a plant that cultivates inside the greenhouse when the wall and the floor are heated, and radiates far-infrared rays, thereby promoting the biological function of the plant, which can be useful for cultivation and growth.

1 is a cross-sectional view illustrating a plant growing greenhouse according to an embodiment of the present invention,
Fig. 2 is an exploded perspective view showing a main part of the plant growing greenhouse applied to Fig. 1,
FIG. 3 is a cross-sectional view of a plant growing greenhouse according to another embodiment of the present invention,
Fig. 4 is an exploded perspective view showing the cultivation vessel applied to Fig. 3,
5 is a cross-sectional view of the cultivation vessel applied to Fig.

Hereinafter, a plant growing greenhouse according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the plant growing greenhouse of the present invention includes a cultivation chamber 80, a support tray 100, and a heating means.

In the cultivation room 80, the wall 81 and the bottom 83 are formed of a loess material. A light transmitting roof 86 is formed on the upper part. Plants such as vegetables, fruit trees, flowers, and the like are grown inside the cultivation room (80).

The cultivation room 80 has the wall 81 and the bottom 83 made of loess. The wall 81 and the bottom 83 can be made by stacking loam bricks or by blending loam dough. The outer surface of the wall 81 and the bottom 83 may be provided with a heat insulating material 93 for preventing heat loss during heating by the heating means.

At least one drainage passage (84) is formed long in the front and rear of the cultivation room (80). A support bar 91 is provided at both ends of the drainage passage 83 at regular intervals and a lid 90 covering the drainage passage 84 is provided at an upper portion of the support bar 91. The lid 90 is spaced apart from the drainage passage 84 by the height of the support bar 91.

And a moisture barrier cover 85 covering the bottom 83 is provided to prevent moisture from penetrating into the bottom 83 made of loess. A thin plate made of stainless steel can be used as the moisture barrier cover 85.

In the illustrated example, the wall 81 is not provided with the moisture barrier cover, but it is needless to say that the water barrier barrier can be formed on the inner wall of the wall body 81 like the floor.

The translucent roof 86 forming the upper part of the cultivation room 80 is made of a material through which light can be transmitted so that sunlight can enter into the interior. The light transmitting roof 86 is formed in a dome shape by being supported by the wall 81 at the bottom. One example of the light projecting roof 86 includes support pipes 87 having both ends embedded in the wall 81 and installed at a predetermined interval, horizontal pipes 88 crossing the support pipes 87, And a vinyl 89 surrounding the outside of the first and second rollers 87 and 87. Alternatively, the light transmitting roof may be formed of glass or resin.

The heating means heats the wall 81 and the bottom 83 of the cultivation room 80 to emit the far infrared rays into the cultivation room 80 and adjust the temperature of the cultivation room 80.

As one example of the heating means, a heater 82 embedded in the wall 81 and the bottom 83 and a power supply unit (not shown) for supplying power to the heater 82 are provided. Hot wire can be applied to the heater 82. Commercial power can be used as the power supply. A temperature sensor (not shown) for measuring the internal temperature of the cultivation room 80 may be installed in the cultivation room 80. In this case, a controller that controls the supply of power from the power supply unit to the hot wire 82 by a signal output from the temperature sensor may be installed inside or outside the cultivation room 80.

Although not shown, another example of the heating means includes a hot water pipe embedded in the wall 81 and the bottom 83, and a hot water supply unit for supplying hot water to the hot water pipe. The boiler can be applied to the hot water supply.

The hot water supply unit includes a heat storage tank filled with water, a heat exchanger provided inside the heat storage tank, a heat collecting plate connected to the heat exchanger through a circulation pipe and passing through a heat exchange medium flowing through the heat exchanger, And a pump for pumping with a pipe. In this case, the heat exchange medium passing through the heat collecting plate is heated by the solar heat and circulated to the heat exchanger, and the heat exchanging medium passing through the heat exchanger conveys heat to the water filled in the heat storage tank to heat the water stored in the heat storage tank. The heated water in the heat storage tank is transferred to the hot water pipe by the pump to heat the wall 81 and the bottom 83 of the cultivation room 80.

The inside of the cultivation room 80 can be raised by heating the wall 81 and the bottom 83 made of loess with the above-described heating means. At the same time, far-infrared rays emitted from the wall 81 and the bottom 83 during heating provide useful help for plant growth in the cultivation room 80.

The inside air of the cultivation room (80) is purified by the anti-microbial and deodorizing function of far-infrared rays. In addition, the far-infrared rays activate the cell tissue and activate the water molecules, thereby promoting the vital functions of the plants, thereby helping the cultivation and growth of the plants. In order to enhance the far-infrared effect, the wall 81 and the bottom 83 may further contain powder obtained by pulverizing minerals such as germanium, monazite, elvan, tourmaline and gneiss.

A support tray (100) is installed inside the cultivation room (80). The support tray 100 includes support posts 101 installed at regular intervals, guide rails 105 fixed to the support posts 101 and installed horizontally, and guide rails 105 installed to be slidable on the guide rails 105 And a bed 110 on which the planting container is placed.

The column 101 is vertically installed with its lower portion fixed to the water blocking cover 83. A plurality of pillars 101 are installed at regular intervals. The guide rails 105 are fixed to the support posts 101 and installed horizontally. The guide rail 105 can be installed by fixing the side surface of the U-shaped steel to the column 101 by welding or the like. The guide rails 105 are installed at regular intervals from the lower portion of the column 101.

The bed 110 is slidably mounted on the guide rail 105. For this purpose, a slider 115 is installed at the lower part of the bed 110. The slider 115 is coupled to the guide rail 105 and can move back and forth. The bed 110 is provided with a food container to be described later.

Preferably, a heating section capable of transferring heat to the food preparation vessel is provided. Such a heating unit can promote the germination of seeds sown on the planting container, the rooting of the root and the growth of the plant and prevent the cold weather.

The heating unit includes a heating wire 113 buried in a zigzag shape in the bed 110 and a power supply unit (not shown) for supplying power to the heating wire 113. When power is supplied from the power supply unit to the heating wire 113, the heating wire 113 heats and the bed 110 is heated. A commercial power source may be used as a power supply unit, or a battery installed in a lower portion of the bed 110 may receive power.

On the other hand, a water supply unit for regulating the water content in the cultivation room 80 and supplying water to plants is provided.

The water supply unit is composed of a water storage tank 99 provided outside the cultivation room 80, a spray pipe 95 installed inside the cultivation room 80, a spray pipe 95 connected to the water storage tank 99 (Not shown). The connection pipe 96 is provided with a pump 97 and a valve (not shown) for pumping water to the spray pipe 95. The spraying pipe 95 can be supported on the upper part of the cultivation room 80 by a support bar connected to the support pipe 87 of the projection roof 86. [ A plurality of spray holes are formed in the spray pipe 95 to spray water downward.

FIG. 3 illustrates a support tray according to another embodiment of the present invention.

The support tray shown in FIG. 3 is provided with an artificial illumination unit 120 for irradiating artificial light in the direction of the food container 9 installed on the bed 110. The components other than the artificial illumination unit are the same as those in the above-described embodiment, and thus a detailed description thereof will be omitted.

The artificial illumination section 120 is installed on the side of the column 101. The artificial illumination unit 120 includes a case 123 fixed to the strut 101, a lens unit 121 of a transparent material coupled to one side of the case 123, and a light source 125 installed inside the case 123 Respectively. A light emitting diode that generates red light of 600 to 700 nm or a blue light of 400 to 500 nm may be applied to the light source 125. Such a light emitting diode is artificially created by artificially creating an environment involved in the growth of plants such as red light (600 to 700 nm) used for photosynthesis reaction of plants and blue light (400 to 500 nm) Growth can be promoted.

The artificial light generated in the artificial illumination unit 120 is irradiated to the plants growing inside the planting container 9 installed in the bed 110. A plurality of planting vessels (9) are arranged on the bed (110).

The food container can be implemented in various forms. For example, the planting container 9 shown in Figs. 3, 4, and 5 has a base portion 10, a cover portion 20, an engaging portion, and harvesting means.

The base portion 10 is formed in a cylindrical shape with an open top. The soil (1) is filled in the base portion (10). A plurality of flow-through holes 13 are formed in the bottom of the base portion 10. Drainage or ventilation is performed through the flow-through hole 13. The flow hole 13 may be formed on the side surface of the base portion 10 as well.

A circular nonwoven fabric sheet 17 is provided on the bottom of the base portion 10 to prevent the soil from being lost through the flow hole 13. The nonwoven fabric sheet 17 passes water and blocks the passage of soil. Soil is planted with seeds of various plants.

The cover portion 20 is coupled to the upper portion of the base portion 10. The cover portion 20 is formed in a cylindrical shape with its bottom opened. The outer diameter of the cover portion 20 is formed to be smaller than the outer diameter of the base portion 10. The cover portion 20 is formed in an appropriate size so as to secure a space in which the plant can grow sufficiently. A plurality of through holes (21) through which air can be introduced are formed on the side surface and the upper surface of the cover part (20). In particular, water may be supplied through the through hole formed in the upper surface of the cover portion 20. [ It goes without saying that the cover portion 20 may be formed of a material capable of passing light for mining.

The base portion 10 and the cover portion 20 are coupled to each other by a coupling portion. It is preferable that the coupling portion is formed so that the cover portion 20 and the base portion 10 can rotate in opposite directions in a state where the cover portion 20 is coupled to the base portion 10. [

The illustrated coupling portion has a lip 30 formed at the lower end of the cover portion 20 and a fastener 31 formed at the upper end of the base portion 10 and hooked to the lip 30.

The lip (30) has an outer diameter larger than the outer diameter of the cover portion (20). The outer diameter of the lip 30 is larger than the inner diameter of the base portion 10. When the cover portion 20 is coupled to the base portion 10, the rib 30 is seated on the top of the base portion 10. In this state, the fastener 31 is hooked on the upper portion of the lip 30 to prevent the cover portion 20 from being disengaged from the base portion 10.

A plurality of fixtures 31 are formed at the upper end of the base portion 10. The fastener (31) is provided with a locking step (33) protruding inward of the base part (10). The fastener 31 has an elastic force so as to be able to return to the inside direction again even if it extends in the outward direction.

The fixing member 31 spreads outward in the course of coupling the cover unit 20 to the base unit 10 so that the lip 30 enters the upper end of the base unit 10. When the lip 30 is seated on the upper end of the base portion 10, the fastener 31 is returned and the fastener 33 is positioned on the upper portion of the lip 30. The lips 30 are caught by the latching jaws 33 to prevent the cover portion 20 from being detached from the base portion 10.

Since the above-described coupling portion only prevents the cover portion from being separated from the base portion, the cover portion 20 can be rotated in either direction while the base portion 10 is fixed. Further, the base portion 10 can be rotated in either direction while the cover portion 20 is fixed. Further, the cover portion 20 and the base portion 10 can be simultaneously rotated in the opposite direction.

A first cutting unit 50 coupled to a lower portion of the cover unit 20 as harvesting means and a second cutting unit 70 coupled to an upper portion of the base unit 10. The first cutting unit 50 includes a first net 51 formed with first through holes 52, a first support frame 53 formed at the edge of the first net 51, And a first fixing holder 55 formed on the top of the cover 20 and fixed to the inner surface of the cover 20.

The first support frame 53 is formed in an annular shape. The outer diameter of the first support frame (53) is formed to be smaller than the inner diameter of the cover portion (20). The first netting 51 is formed inside the first support frame 53. A plurality of first through holes 52 are formed in the first net 51. In the illustrated example, the first net 51 has a net structure formed by weaving metal wires. Therefore, the mesh becomes the first through hole 52.

A plurality of first fixed holders 55 are formed at the upper end of the first support frame 53. A total of four may be formed at intervals of 90 degrees as shown in FIG. Each of the first fastening holders 55 is formed with a fastening protrusion 57 protruding outward. The first fixing holder 55 has an elastic force so that it can return to the outward direction even if it is tilted inward.

The first fixing holder 55 is inclined inward to insert the first cutting unit 50 into the cover 20 in the process of coupling the first cutting unit 50 to the cover 20. [ The engaging step 57 of the first fixing holder 55 is inserted into the fixing groove formed on the inner surface of the cover part 20 to prevent the first cutting unit 50 from being separated. The first cutting unit 50 coupled to the cover unit 20 rotates together with the cover unit 20 when the cover unit 20 rotates.

The second cutting unit 70 is coupled to the base unit 10 to face the first cutting unit 50. The second cutting unit 70 includes a second net 71 formed with second through holes 72 and located on the top of the soil and a second supporting frame 71 formed on the edge of the second net 71 And a second fixing holder 75 formed at a lower portion of the second supporting frame 73 and fixed to the inner surface of the base portion 10.

The second cutting unit 70 has the same structure as that of the first cutting unit 50 except that the second cutting unit 70 is vertically positioned.

The second fixing unit 75 is inclined inward to insert the second cutting unit 70 into the base unit 10 in the process of coupling the second cutting unit 70 to the base unit 10. The engaging step 77 of the second fixing holder 75 is inserted into the fixing groove 15 formed on the inner surface of the base 10 to prevent the first cutting unit 70 from being separated. The second cutting unit 70 coupled to the base unit 10 rotates together with the base unit 10 while rotating.

The buds of the plant germinated in the planting container mentioned above grow through the second cutting unit 70 and the first cutting unit 50 while growing. Water is supplied through the above-described spray pipe. In this case, the bed 110 disposed in the lower layer of the support tray moves back and forth to prevent the water supply from being blocked by the bed disposed in the upper layer. If the plant is large enough to be harvested, collect the food preparation containers from the support trays. After the collection, a new planting container with seeds seeded is placed in the empty spot. Collected food containers can be distributed and sold with plants planted.

Plants grown in planting containers are harvested through harvesting means. The first cutting unit 50 and the second cutting unit 70 rotate in opposite directions when the base unit 10 is rotated in one direction and the cover unit 20 is rotated in the opposite direction. As a result, the stem of the plant growing through the first net 51 and the second net 51 is twisted and broken. Thus, the stem or leaf of the plant is cleaved off from the root. Thus, the present invention can easily harvest plants, especially vegetables, through harvesting means.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: base portion 20: cover portion
80: cultivation room 100: support tray
101: support 105: guide rail
110: Bed

Claims (6)

delete delete delete A cultivation chamber having a wall and a bottom made of yellow clay and having a projection roof at an upper portion thereof;
A support tray installed inside the cultivation room for supporting a planting container in which plants are planted;
And heating means for heating the wall and bottom of the cultivation room to emit far-infrared rays into the cultivation room and adjusting the temperature of the cultivation room,
Wherein the cultivation room further comprises a moisture barrier covering the floor to prevent moisture from penetrating into the floor. A cultivation chamber having a wall and a bottom made of yellow clay and having a projection roof at an upper portion thereof;
A support tray installed inside the cultivation room for supporting a planting container in which plants are planted;
And heating means for heating the wall and bottom of the cultivation room to emit far-infrared rays into the cultivation room and adjusting the temperature of the cultivation room,
The support tray is provided with pillars provided at regular intervals, a guide rail fixed to the pillars and horizontally installed, a bed slidably movably mounted on the guide rail to seat the food preparation container, And a heating unit for transferring heat to the planting container. A cultivation chamber having a wall and a bottom made of yellow clay and having a projection roof at an upper portion thereof;
A support tray installed inside the cultivation room for supporting a planting container in which plants are planted;
And heating means for heating the wall and bottom of the cultivation room to emit far-infrared rays into the cultivation room and adjusting the temperature of the cultivation room,
The planting container includes a base portion that is formed in a cylindrical shape so that the soil can be filled in the planting container, a top portion of which is opened, a tubular cover portion that is opened at the bottom, and a cover portion that is joined to the top portion of the base portion, A cover part and a base part, the cover part and the base part being rotatable with respect to each other so that the cover part and the base part can rotate with each other; And a harvesting means capable of harvesting the plant.

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