KR100348529B1 - Apparatus for generating hot wind - Google Patents

Abstract

The present invention provides a support frame provided in the longitudinal direction along the bottom; A water drainage passage and an air spray tube having both ends fixed by a fixing tool and a wedge-shaped gripper in a vinyl fixing groove of a pipe provided at both sides of the upper end of the support frame; A water supply pipe provided with the water drainage passage so as to be supported by a support having fixed ends; It relates to a low temperature wind generating device provided in the inside of the air injection tube and composed of a fibrous material tube repeatedly arranged so that a large circular ring and a spray nozzle maintain a constant interval.

The present invention, such as in summer or winter to adjust the temperature inside the greenhouse to the growth conditions of the horticultural plants and to control the moisture and temperature of the ground where the roots grow, as well as the oxygen supply appropriately to promote the healthy growth of cultivated plants. In this way, the root development, stems and leaves of the plant can be grown without pests to produce a good quality fruit and at the same time have the effect of increasing the yield.

Description

Low temperature wind generator {Apparatus for generating hot wind}

The present invention relates to a low-temperature wind generator, and more particularly to a low-temperature wind generator that can promote the growth of cultivated plants by adjusting the temperature in the greenhouse to suit the growing conditions of horticultural plants in summer or winter. .

In general, the greenhouse is divided into a tunnel type single-acting type with one roof and interlocking type by connecting several roofs together.

The single-acting greenhouse, as shown in Figure 1, provides a plurality of double arc-shaped frame 910 and interconnected their ends to create a single unit domed frame. The domed frame is arranged in a plurality at regular intervals along the longitudinal direction to form a greenhouse skeleton 900 having a tunnel form and is completed by covering the outer surface with vinyl.

The greenhouse skeletal 900 provided side windows 920 for ventilation at the lower sides of both sides, and the front and rear doors 930 for the workers to enter.

The side window 920 is provided to guide each hand hoist 921 provided with a handle 922 up and down by a guide rod 924, as shown in Figure 2, the handle 922 to the hand hoist 921 The rotary pipe 923 which rotates according to the direction of rotation of was provided.

In the single-acting greenhouse provided with the side window 920 as described above, first, when the handle 922 is rotated in the selected direction, the hand hoist 921 is guided by the respective guide rods 924 according to the rotational direction thereof. The rotating pipe 923, which is interlocked and rotated by the hand hoist 921, opens and closes the side window 920 by winding or unwinding the vinyl.

Thus, the single-acting greenhouse may be better than opening and closing the door 930 only by opening and closing the door 930 even when the side windows 920 provided at both sides of the lower arc-shaped frame 910 are not opened. This also did not vent enough to satisfy the air in the greenhouse, because of this there is a problem that the temperature does not decrease if the internal temperature of the greenhouse increases in summer.

As a result, the growth of horticultural plants grown in the greenhouse is not only enormous, but also the temperature inside the greenhouse is too high than the temperature in the atmosphere, causing the plant to grow and die (hereinafter referred to as "drying phenomenon").

The single-acting greenhouse proposed to prevent the drying phenomenon of the plant by the high temperature is provided with a sprinkler 940 on the outer upper surface of the greenhouse, as shown in Figure 3 and 4 by spraying water on the outer surface of the greenhouse The sprayed water flows along the outer surface of the greenhouse, reducing the temperature inside the greenhouse.

However, the temperature reduction method of the greenhouse using the sprinkler 940 is a plant that needs to lower the temperature, but the effect of the temperature of the greenhouse near the greenhouse where the water flowing down the outer surface of the greenhouse forming a boundary of the greenhouse There was a problem that the temperature is not evenly lowered up to the inner central part of the greenhouse, which is this growing zone.

Therefore, there is a problem that the income is lowered due to the reduction in yield as well as causing a huge obstacle to the growth of the horticultural plants grown in the greenhouse.

In addition to the problems described above, the temperature reduction method inside the greenhouse using the conventional sprinkler 940, because the water sprayed from the sprinkler 940 continuously flows down the outer surface of the greenhouse, causing a severe temperature difference inside and outside the greenhouse. As dew condensation occurs on the vinyl inside the greenhouse, the amount of sunlight transmitted is lowered, which in turn causes great disruption to the growth of horticultural plants.

In addition, the conventional method of lowering the temperature inside the greenhouse, since water sprayed from the sprinkler 940 flows down the vinyl on the outer surface of the greenhouse and then permeates to the ground, the ground in the region always has excessive moisture and the edge of the greenhouse There was a problem that the horticultural plants do not grow normally due to adverse effects on the plants located in the part.

On the other hand, unlike the above-mentioned single-acting greenhouses, the interlocking greenhouses connect the greenhouse skeletons to the width as desired by the consumer. However, the dome-type greenhouses using only arc-shaped frameworks have cultivated areas as much as the connecting portions occupy due to the connection portions between the greenhouses. This was reduced and the efficiency of the interior space of the greenhouse was lowered, making it impractical.

Therefore, the interlocking greenhouse connects a plurality of double arc-shaped frames 912 in the same manner as the single-acting greenhouse on the double strut as shown in FIG. The domed frame is arranged continuously in the longitudinal direction as desired by the consumer to form a greenhouse skeleton 900, and then finished by covering the outer surface with vinyl.

The greenhouse framework 900 of the interlocking greenhouse is vertically erected vertically framed 911 used as a pillar (pillar) and arc-shaped frame 912 connected to the top of the linear frame 911 to form a roof 910 Consists of, the straight frame 911 and arc-shaped frame 912 is fixed by welding.

The straight frame 911 and arc frame 912 is firmly fixed by welding, but because the climatic conditions unique to greenhouses for growing horticultural plants are high temperature and high humidity, the straight frame 911 and arc frame 912 made of steel are It is easy to corrode, and in particular, the welded portions of the straight frame 911 and the arc frame 912 may be severely corroded and vulnerable.

On the other hand, in winter, the inner temperature of the greenhouse should be maintained at a constant temperature to prevent the growth of horticultural plants as well as from the company. The method is to cover the insulation cover on the outside of the greenhouse and to install the stove in the greenhouse. There is this.

The former method of using a heat insulating cover has the trouble of covering the heat insulating cover at night when the temperature drops sharply and kicking it to receive sunlight during the day, and the latter method using a stove is economically enormous due to excessive fuel consumption. There was a costly problem.

The present invention has been researched and developed in order to solve the above problems, and its object is to provide a low-temperature wind generator that can adjust the temperature in the greenhouse to suit the growing conditions of horticultural plants regardless of summer or winter. have.

1 is a perspective view showing a conventional single-acting greenhouse skeleton

Figure 2 is a perspective view of a part of the side window installed in a conventional single-acting greenhouse

3 is a perspective view of a state in which a sprinkler is installed on a conventional single-acting greenhouse top

Figure 4 is a front sectional view of the sprinkler is installed on the conventional single-acting greenhouse top

5 is a front view showing a conventional interlocking greenhouse skeleton

Figure 6 is a front sectional view of the single-acting greenhouse for horticulture plant cultivation of the present invention

Figure 7 is a side view of the single-acting greenhouse for gardening plants cultivation of the present invention

Figure 8 is a front view of the interlocking greenhouse for gardening plants cultivation of the present invention

Figure 9 is a plan view of the interlocking greenhouse for gardening plants cultivation of the present invention

10 is a cross-sectional view of the greenhouse skeleton for horticulture plant cultivation of the present invention

11 is a cross-sectional view of a greenhouse skeleton for growing a horticultural plant in another state of the present invention

Figure 12 is an exploded perspective view extracting the intermediate connection of the greenhouse skeleton for horticulture plant cultivation of the present invention

Figure 13 is a cross-sectional view of the combination of the present invention Figure 12

Figure 14 is an exploded perspective view extracting the upper connection portion of the greenhouse skeleton for horticulture plant cultivation of the present invention

Figure 15 is a cross-sectional view of the combination of Figure 14 of the present invention

Figure 16 is an exploded perspective view showing a fixing means for fixing the vinyl in the greenhouse framework of the present invention

17 is a cross-sectional view of the present invention Figure 16

Figure 18 is an exploded perspective view of the vinyl fixing means of the present invention different from Figure 16

19 is a cross-sectional view of the present invention Figure 18 combined

Figure 20 is an exploded perspective view of the vinyl fixing means of the present invention different from Figure 18

Figure 21 is a cross-sectional view of the present invention Figure 20

Figure 22 is an exploded perspective view of the vinyl fixing means of the present invention different from Figure 20

Figure 23 is a cross-sectional view of the present invention Figure 22

Figure 24 is an exploded perspective view of the vinyl fixing means of the present invention different from Figure 22

25 is a cross-sectional view of the present invention Figure 24 combined

Figure 26 is a front view showing the support means for supporting the three or four vinyl layer in the greenhouse of the present invention

27 is a front view showing a fixing frame for supporting a vinyl layer of 3,4 in the greenhouse of the present invention

Figure 28 is a partial front view of the open ceiling window installed in the interlocking greenhouse of the present invention

29 is a plan view of a part of the open ceiling window installed in the interlocking greenhouse of the present invention

Figure 30 is an excerpt of the main portion of the ceiling window opened in the interlocking greenhouse of the present invention

Figure 31 is a partial plan view of the ceiling window closed state installed in the interlocking greenhouse of the present invention

32 is an excerpt of an essential part of a ceiling window closed in an interlocking greenhouse according to the present invention;

Figure 33 is an excerpt of the main portion of the present invention different from Figure 28

34 is an exploded perspective view of a part of the rain gutter device installed in the interlocking greenhouse of the present invention

35 is a perspective view of the rain gutter device installed in the interlocking greenhouse of the present invention

36 is a front view of the rain gutters installed in the interlocking greenhouse of the present invention

37 is a perspective view of a dew treatment waterway installed in the interlocking greenhouse of the present invention

38 is a cross-sectional view of the coupling of the dew treatment water installed in the interlocking greenhouse of the present invention

39 is a cross-sectional view showing the fixing means of the vinyl installed in the dew treatment channel of the present invention.

40 is a partially cutaway perspective view of a low-temperature wind generator that is a horticultural plant cultivation apparatus of the present invention

41 is a cross-sectional view of the low temperature wind generator of the present invention.

Figure 42 is an exploded perspective view of the air injection port installed in the air spray tube of the present invention

43 is an exploded perspective view of an injection nozzle installed in a fiber material tube of the present invention

Figure 44 is a perspective view of another state of the injection nozzle installed in the fiber material tube of the present invention

45 is a partially cutaway perspective view of the low-temperature wind generator of FIG. 40 according to the present invention.

46 is a partially cutaway perspective view of the low-temperature wind generator in a state different from that of FIG. 45 of the present invention.

47 is a schematic view showing the horticultural plant cultivation apparatus of the present invention

48 is a schematic view of an enlarged state by extracting a part of the horticultural plant cultivation apparatus of the present invention

49 is an excerpt perspective view of a pipe that is a horticultural plant cultivation apparatus configuration of the present invention

※ Explanation of main parts of drawing ※

100a, 100b: greenhouse skeleton 110: roof

120: prop 200a, 200b: skeleton

210, 210a, 210b, 210c: pipe 211: reinforcing member

220: vinyl fixing groove 230: fixing plate

231: unevenness 240,260: auxiliary fixing plate

250: fixing plate 270, 270a, 274: fixture

271,271a: Euiji District 272,272a: Bolted fastening groove

273,273a: Supports 275,286: Toothed

280,280a, 280b, 285: Gripping strip 281,281a: receiving part

282,282a: arc groove 283: rail

285: wedge-shaped grip hole 300: rainwater inflow prevention means

310: support frame 320: support

330: cover 400: switchgear

410,480: ceiling window 420: actuator

430,430a: moving bar 431: rack

440,450,450a, 460: Roller 451: Pinion

470: wire 490: pipe

500: rain gutter device 510: extension

520 body 530 flange

540: reinforcing piece 550: support plate

551: hole 600: dew treatment

610: citron frame 620: extension rod

630,640: Triple and quadruple vinyl layer 650,650a: Wire rope

660: channel 670: fixed frame

680: rotating bar 690: support means

691: Extension 692: Support

700: low temperature wind generator 710: support frame

720: Water drainage path 730,730a: Water supply pipe

740: support 750: air injection tube

760,760a Spray nozzle 761 Hollow pipe

762: fastening portion 763,771: spray hole

770,770a: Ring 780,780a: Fiber tube

790: air jet 791: inner cap

792: outer cap 793: mesh

800: horticultural plants 810: pipe

811 hole 820 heating pipe

821: fixture 812: drainage

830 fine gravel 840 protection net

850: spray pipe 851: sprayer

860: cover 870: land

880: Blower

Brief description of the technical features of the present invention having such an object is as follows.

Low temperature wind generating device provided on the ground of the present invention, the support frame provided in the longitudinal direction along the bottom; A water drainage passage and an air spray tube having both ends fixed by a fixing tool and a wedge-shaped gripper in a vinyl fixing groove of a pipe provided at both sides of the upper end of the support frame; A water supply pipe provided with the water drainage passage so as to be supported by a support having fixed ends; A large circular ring and a spray nozzle are provided inside the air spray tube and are composed of a tube of fiber material repeatedly arranged to maintain a constant interval.

Referring to the specific configuration and embodiment of the present invention having such a feature in detail with reference to the accompanying drawings as follows.

The single-acting greenhouse of the present invention, as shown in Figures 6 to 7 to arrange a double dome-shaped frame (200a) by a predetermined amount at regular intervals to provide a single-acting greenhouse skeleton (100a), the greenhouse skeleton The front surface of 100a is covered with vinyl.

Here, since vinyl is a transparent material, reference numerals of vinyl will be omitted in FIGS. 6 and 7, and a fixed state of vinyl will be described later with reference to FIGS. 16 and 17.

At the top of the center of the greenhouse skeleton 100a, a pointed triangular ceiling window 480 is provided. The ceiling window 480 has a pipe 490 connected to both ends of the vinyl covered over its front surface. At one end of the), a forward / reverse motor M driven in the forward / reverse rotation direction is provided.

As described above, when the ceiling window 480 drives the forward / reverse motor M when the inside of the greenhouse is to be ventilated or controlled in the greenhouse, the pipe 490 is interlocked and rotated according to the rotation direction. As the 490 is rotated, the ceiling window 480 is opened and closed by winding and releasing the vinyl.

The dome-shaped frame 200a constituting the greenhouse skeleton 100a is provided with triple and quadruple vinyl layers 630 and 640 over its entire surface to be located inside the greenhouse skeleton 100a, and the triple and quadruple vinyl layers. 630 and 640 are fixed to the fixing frame 670 and the support means 690 installed from the domed frame 200a.

The reason for providing the triple and quadruple vinyl layers (630,640) in the greenhouse as described above is to obtain a better insulation effect so that the temperature inside the greenhouse does not decrease during the winter, thereby preventing the cultivated plant verbs Increases productivity by promoting growth.

8 and 9, the interlocked greenhouse of the present invention, using both the roof frame (200b) of the both sides of the roof 110 and both ends of the roof 110 formed to have the same inclination angle on both sides from the center. Consists of a support 120 to form a greenhouse skeleton (100b), and then formed by covering the outside of the vinyl.

However, the roof 110 may be provided in a dome shape such as a single-acting greenhouse instead of the roof 110 formed to have the same inclination angle on both sides of the center.

Both roof-like frameworks 200b of the greenhouse framework 100b constituting the interlocking greenhouse are provided with triple and quadruple vinyl layers 630 and 640 across the entire surface of the interior of the greenhouse skeleton 100b. The layers 630 and 640 are fixed by the fixing frame 670 and the support means 690 extending from both the roof frames 200b.

The domed frame 200a and the roof frame 200b of both roof types used in the single-acting and interlocking greenhouses are arranged in parallel with two pipes 210 and 210a at regular intervals as shown in FIGS. 10 to 11. The reinforcing member 211 is fixed by welding between the pipes 210 and 210a in consideration of the rigidity of the frameworks 200a and 200b.

On the other hand, the pipes 210 and 210a of the frameworks 200a and 200b are formed in a flat shape having two parallel surfaces.

Hereinafter, for convenience, it will be described with an example of the two-frame roof frame (200b) of the frame of the interlock greenhouse.

The frame 200b of FIG. 10 is a vinyl fixing groove 220 is formed in the pipe 210 on one side and the pipe 210a on the other side is formed in a flat circular shape and arranged in parallel to each other, the frame of FIG. The 200b was produced by arranging the pipes 210 having the vinyl fixing grooves 220 at both ends outside in parallel.

As shown in FIGS. 12 to 13, the framework 200b of the present invention has the unevenness 231 to fit the ends of the framework 200b adjacent to each other between the pipes 210 at the ends of the framework 200b. The fixing plate 230 is provided, and the fixing plate 230 is fastened by bolts and nuts which are fastening members with the auxiliary fixing plate 240 padded on both sides thereof.

Thus, the fastened frame 200b is fitted with the concave-convex 231 formed at the end of the fixing plate 230, and then the auxiliary fixing plate 240 is padded on both sides thereof to be secure and secure.

The upper middle joint of the roof 110 (see FIGS. 8 and 9) constituting the greenhouse skeleton 200b of the present invention, as shown in FIGS. 14 to 15, the pipe 210 at the end of the frame 200b has a straight line in plan view. A plate-shaped fixing plate 250 is provided so that the ends of the frame 200b overlap each other, and the fixing plate 250 is fastened by bolts and nuts which are fastening members with the auxiliary fixing plate 260 padded on both sides thereof. have.

In other words, in the state in which the fixing plate 250 is overlapped with each other, the auxiliary fixing plate 260 is positioned on both sides of the fixing plate 250, and is configured to be fastened by bolts and nuts.

Thus, the fastening frame 200b is secured and secured because the fixing plate 260 is padded and fastened to both sides of the fixing plate 250.

The configuration of fixing the vinyl (V) to the vinyl fixing groove 220 of the pipe 210 forming the frame 200b of the present invention is shown in Figure 16 to 17, the vinyl fixing groove ( The fastener 270 seated on the 220 and the plastic (V) on the fastener 270 and consists of a gripper 280 fixed by a fastening screw.

The fastener 270 has an arc-shaped support sphere 271 is formed long at both ends so as to be caught by the lower edge of the vinyl fixing groove 220, and a support 273 having a bolting groove 272 at the center thereof. It is formed in the shape of a rail raised upward.

The gripper 280 has a receiving portion 281 for receiving the support 273 of the fixture 270 in the center of the lower end of the plate is formed on both sides of the inlet edge of the vinyl fixing groove 220 of the pipe 210 The arc-shaped groove 282 that is pressed is formed in a fine rail shape.

The fixing of the vinyl structure as described above is inserted into the lower edge of the vinyl fixing groove 220 of the pipe 210 so that both ends of the support sphere 271 of the fastener 270 is put and put the vinyl (V) thereon The receiving portion 281 of the earth 280 is coupled to fit outside the support 273 of the fixture 270.

At this time, the arc-shaped groove 282 of the gripper 280 is in close contact with the vinyl (V) to the inlet corner of the vinyl fixing groove 220 of the pipe (210).

The fastener 280 assembled as described above is fastened to the fastening screw from the gripper 280 to the bolt fastening groove 272 of the fastener 270 so as not to be separated from the fastener 270.

Accordingly, the vinyl V is fixed by the support 273 of the fixture 270 and the receiving portion 281 of the grip 280, and at the same time, the arc-shaped groove 282 and the pipe 210 on both sides of the grip 280. Vinyl fixing groove 220 of the inlet edge because it is coupled to each other has a firm coupling force.

Another configuration for fixing the vinyl of the present invention is a fastener 270a seated in the vinyl fixing groove 220 of the pipe 210 and the vinyl (V) on the fastener 270a, as shown in Figs. It consists of the holding | gripping tool 280a put up and fixed by a fastening screw.

The fastener 270a is formed with an arc-shaped support sphere 271a to be in close contact with the inclined side surface of the vinyl fixing groove 220, and a supporter 273a having a bolt fastening groove 272a is raised upward. It is formed in a rail shape.

The gripper 280a has a receiving portion 281a deeply formed at the bottom center of the plate for accommodating the support 273a of the fixture 270a. An arc-shaped groove 282a pressing the edge is formed in a fine rail shape.

In the fixing configuration of the vinyl structure configured as described above, the process of fixing the vinyl is the same as described with reference to FIGS. 16 and 17, and thus a detailed description thereof will be omitted.

The grippers 280a are illustrated as shown in FIGS. 18 and 19, but as shown in FIGS. 20 and 21, the rails 283 are disposed on the upper surface of the gripper 280a at an upper side of the position biased to one side within the range where the fastening screws are not disturbed. Can be formed into a raised grip 280b.

Such a gripper 280b is for preventing the vinyl V from having any effect even when the ceiling window 410 provided on the roof 110 of the greenhouse framework 100b is seated and slips.

Another configuration for fixing the vinyl according to the present invention is a fastener 270b for fixing the vinyl (V) in the vinyl fixing groove 220 of the pipe 210, as shown in Figs. 22 and 23 and the fastener 270b. It is comprised by the holding | gripping tool 280c which fits inside and is fixed.

The fastener 270b is formed in a dovetail shape having a predetermined thickness so as to be inserted into the vinyl fixing groove 220 of the pipe 210 to fix the vinyl V, and teeth 274 are formed on both inner surfaces thereof. .

The gripper 280c is formed in a wedge shape that gradually opens as it enters the inner surface of the fixture 270b, and teeth 284 coupled to the teeth 274 of the fixture 270b are formed on both outer sides thereof.

The configuration of fixing the vinyl of the present invention configured as described above is to put the vinyl (V) on the vinyl fixing groove 220 of the pipe 210 and press the fixing fixture 270b thereon by inserting the vinyl fixing groove 220 and the fixture Fixing the vinyl (V) by the (270b), and then put the gripper 280c into the interior of the fixture 270b to be assembled so that the teeth 274, 284 of the fixture 270b and the gripper 280c are coupled to each other. To complete.

Since the fastener 270b assembled as described above is opened toward the outside as the gripper 280c is inserted, the fastener 270b is more closely attached to the vinyl fixing groove 220, and thus, the fastener 270b and the vinyl V are made of the vinyl fixing groove ( Decoupling from 220 is prevented.

In addition, another configuration for fixing the vinyl according to the present invention, as shown in Figure 24 and 25, the fixing fixture 270c for fixing the vinyl in the vinyl fixing groove 220 of the pipe 210, and this fixture 270c The gripper (280d) is fixed while seated on the upper portion of the fastener (270c) and the vinyl is positioned on the upper portion of the fastener (270c), the elastic fixing the vinyl located on the upper portion of the gripper (270d) The clip 290 is comprised.

The fixture 270c is inserted into the vinyl fixing groove 220 of the pipe 210 to fix the vinyl, and both ends of the bottom of the fixture 270c are in intimate contact with both inner surfaces of the vinyl fixing groove 220. Will support 271b is provided long and the upper side is formed with a fitting groove 276 is fitted into the vinyl.

In addition, an elastic body 275 protruding from the bottom to the top is provided at the center of the fixture 270c, and the elastic body 275 contracts and expands when an artificial force is applied to the opening of the bottom.

The gripper 280d is provided with a fixing part 285 having a flat surface so that the bottom part is seated on the elastic body 275 of the fixing part 270c, and one side thereof has a close contact with an upper part of one side of the vinyl fixing groove 220. An arc shaped accommodating portion 281b is elongated, and a fitting groove 286 into which a vinyl is fitted is formed at an upper portion thereof.

Means for fixing the vinyl of the present invention configured as described above is put vinyl on the vinyl fixing groove 220 of the pipe 210, as shown in Figure 24 by pressing the fastener 270c on the vinyl fixing groove 220 ) And the fastener 270c to fix the vinyl.

After that, the vinyl is placed on the upper part of the fastener 270c and the fixing part 285 of the gripper 280d is placed on the upper surface of the elastic body 275 provided at the center of the fastener 270c. The accommodating part 281b provided at one side receives the upper portion of the vinyl fixing groove 220.

When the above process is completed and fixed to penetrate the fixture 270c and the gripper 280d by using a screw which is a fastening member, the bottom of the elastic body 275 is opened to both sides by the diameter of the screw and the supporting sphere 271b. ) Is in intimate contact with both inner sides of the vinyl fixing groove 220. Accordingly, the vinyl placed on the vinyl fixing groove 220 of the pipe 210 is firmly fixed by the support sphere 271b.

In addition, the vinyl placed on the fixture 270c is firmly fixed by generating a close contact force between the upper portion of the accommodating portion 281b and the vinyl fixing groove 220 and the elastic body 275 and the fixing portion 285.

In addition, the fitting groove 276 provided in the upper portion of the fixing tool 270c and the fitting groove 286 provided in the gripper 280d are used to fix another vinyl. In this case, the fixing tool 270c and the wave The vinyl is placed on top of the earth 280d and fixed using the elastic clip 290.

However, the object to be fixed by the elastic clip 290 may be fixed to the cloth of the fiber material that covers the mesh or other greenhouses, not vinyl.

The trilayers and quadruple vinyl layers 630 and 640 inside the framework 200b constituting the greenhouse framework 100b of the present invention, as shown in FIGS. 26 and 27, to maintain a constant distance from the roof 110. Is provided in the pipe 210 of the support frame 692, which is a fixed frame 670 and the support means 690, which are installed at the extension frame, and the fixing fixture 270 and the wave described above in the vinyl fixing groove 220 of the pipe 210. The vinyl V is fixed by the earth 280.

The vinyl (V) is located on the wire rope (650,650a) and the rotary bar 680 is fixedly installed at the end thereof, and the rotary shaft of the forward and reverse motor (M) is provided with a braking force at one end of the rotary bar (680) It is fixed.

When the vinyl layers 630 and 640 of the 3 and 4 are driven by applying power to the stationary motor M, the rotation bar 680 is rotated together with the rotation axis thereof, and the vinyl is rotated according to the rotation direction of the rotation bar 680. Winding or unwinding (V) is moved on the wire rope (650,650a).

Accordingly, the vinyl (V) constituting the three or four vinyl layers (630, 640) can be walked or covered.

In addition, as shown in FIGS. 28 to 32, an upper portion of the roof 110 of the greenhouse frame 100 has a support frame 310 in which the support 320 is raised upward from the upper sides of the frame 200 of the roof 110. ) And the support 320 of the support frame 310 is covered with a cover 330 extending from the corner of the upper end of the roof 110 to the lower side to provide rainwater inflow prevention means (300).

In this way, since the cover 330, which is the rainwater inflow prevention means 300, is covered on the upper edge portion of the roof 110, water does not flow into the greenhouse even if it rains or snows.

The roof 110 of the lower position of the cover 330 is provided with a rectangular ceiling window 410 formed along the longitudinal direction of the roof 110 to be opened and closed in the width direction of the roof 110 by the opening and closing device 400. The opening and closing device 400 is provided with a moving bar 430 in the longitudinal direction of the roof 110 so as to be guided by a pair of rollers 440 and 450, and an actuator 420 which is a cylinder at one end of the moving bar 430. Is connected to the piston rod.

In addition, both ends of the wire 470 wound on the rollers 450 and 460 arranged in the width direction of the roof 110 with one wire 470 are fixed to the movable bar 430, and a predetermined portion of the wire 470 is fixed. The ceiling window 410 is fixed in position.

In the ceiling window 410 of the present invention configured as described above, as shown in FIGS. 31 and 32, when the actuator 420 is operated while the ceiling window 410 is closed, the movement bar 430 of the end of the piston rod is moved in the direction of the arrow. While moving, the wire 470 is guided by the rollers 450 and 460 as shown in FIGS. 28 to 30 so that the ceiling window 410 is moved by opening in the width direction of the roof 110.

On the contrary, when the ceiling window 410 is to be closed in an open state, when the actuator 420 is operated again, the moving bar 430 at the end of the piston rod is guided by a pair of rollers 440 and 450. As the wire 470 fixed to the moving bar 430 is moved, the ceiling window 410 is moved to the center of the roof 110 and closed as shown in FIGS. 31 and 32.

In addition, the ceiling window 410 is shown and described, as shown in Figures 28 to 32, but the rack 431 is formed in the longitudinal direction at the bottom of the moving bar 430a as shown in Figure 33 and the moving bar ( The pinion 451 meshed with the rack 431 was formed on one roller 450a of the pair of rollers 440 and 450a for 430a.

Between the roof 110 and the end portion of the roof 110 in the interlocking greenhouse of the present invention, as shown in Figure 34 to 36, the rain gutter 500 for receiving rain water in the longitudinal direction of the roof 110 It is provided long.

The rain gutter device 500 is formed with an extension piece 510 bent outward at the upper end of the elongated body 520 having a yuja-shaped cross section and a plurality of holes 550 in the upper part of the body 520. The support plate 550 is provided, and the flange 530 is formed on the outside of the body 520 at regular intervals.

The reinforcing piece 540 fixed to the end of the frame 200b is firmly fastened to the flange 530 by a screw, which is a fastening member.

Rain gutter device 500 is configured as described above is the water flowing down the roof 110 is collected into the support plate 550 and the collected rain water into the body 520 through the hole 551 of the support plate 550. After falling, it is guided along the body 520 to be discharged to both ends.

The support plate 550 and the flange 530 of the body 520 serves to maintain the original shape to prevent deformation by the reinforcement of the body 520.

In the interlocking greenhouse of the present invention, the roof 110 and the roof 110 are in contact with each other, as shown in FIGS. 37 to 39, and dew formed on the vinyl layers 630 and 640 in the greenhouse skeleton 100b. The dew processing water path 600 which collects is provided.

The dew treatment channel 600 is a frame 610 of the U-shaped are arranged at regular intervals between the adjacent pillars 120 and the extension rods 620 are extended from both ends of the frame 610 to both sides. The pipe 210b having the vinyl fixing grooves 220 at both ends of the frame 610 is fixed horizontally long and the vinyl fixing grooves 220 at one end of the extension rod 620. The pipe 210 is fixed horizontally long.

The vinyl fixing groove 220 of the pipe 210b is covered with vinyl (V) on its inner surface on both sides of the upper end of the frame 610, and the pipe 210 of the extension rod 620 at the upper end of the frame 610. ) To cover the vinyl (V) to each of the fixture 270 and the gripper 280 by fixing the channel 660 is formed to serve to receive the dew.

The process of fixing the vinyl (V) to the pipe 210b having the vinyl fixing grooves 220 formed at both sides and the pipe 210 having the vinyl fixing grooves 220 formed at one side thereof has been described with reference to FIGS. 18 to 19. Since the same, detailed description thereof will be omitted.

In addition, a plurality of wire ropes 650 and 650a forming three or four vinyl layers 630 and 640 are fixed to each of the pipes 210 and 210b at regular intervals, and vinyl (V) is formed on the wire ropes 650 and 650a. The vinyl (V) is covered with a rotary bar 680 is fixed to the end thereof so as to be wound or unwound by the stationary motor (M).

The above description relates to a greenhouse, and hereinafter, a control device for controlling growth conditions of various horticultural plants grown in a greenhouse will be described.

As shown in FIGS. 40 to 46, the low temperature wind generating device 700 for controlling the greenhouse internal temperature of the present invention includes a pipe 210c having a vinyl fixing groove 220 at both ends of the long support frame 710. Both ends of the sheet member forming the water drainage path 720 and the air spray tube 750 to form a tube in the vinyl fixing groove 220 of the pipe (210c) is formed long in the longitudinal direction fasteners (270b) And a gripper 280c.

A water supply pipe 730 is provided at an upper portion of the water drainage path 720 along the longitudinal direction, and the water supply pipe 730 is positioned a plurality of supports 740 positioned slightly apart from the bottom of the water drainage path 720. The support 740 is fixed by a fixture 270b and a gripper 280c to have a constant distance in the longitudinal direction of the water supply pipe 730.

Inside the air spray tube 750, a large circular ring 770 and a spray nozzle 760 are repeatedly arranged, and a fiber material tube 780 having fine holes in a continuous ready-mixed concrete shape is provided. The injection nozzles 760 in 780 are connected to spray water like mist in one or both directions by receiving water from the water supply pipe 730.

As shown in FIG. 42, the air injection tube 790 is arranged to be disassembled so as to be injected in a multi-angle direction of the upper portion, and the air injection hole 790 is disposed on the inner / outer surface of the air injection tube 750. The fixed inner / outer caps 791 and 792 are decomposedly coupled to each other, and the inner / outer caps 791 and 792 are formed with a fine mesh 793 for pulverizing the sprayed water into finer particles.

The injection nozzle 760 is formed of a double hollow pipe 761, which is wider from the center to both ends as shown in FIG. 43, and a fastening part 762 which is circulated with the water supply pipe 730 is formed at both ends thereof. A plurality of spray holes 763 are formed for spraying water supplied from the water supply pipe 730 with fine particles. In addition, the spray nozzle 760a may form a spray hole 763 only at one end as shown in FIG.

The reason why the fiber tube 780 is provided in the ready-mixed concrete type is that the ground water sprayed from the spray hole 763 of the spray nozzle 760 is sprayed with the groundwater when the ground water is injected into the fiber tube 780. Induced by the air pressure to increase the injection pressure and the ground water is injected to the ring 770 wide cross-sectional area so that the pressure is sharply lowered to make it easier to make a fine mist state.

The reason for using the fiber material tube 780 is to grind the fine ground water sprayed from the spray nozzle 760 to minimize the fine particles to be discharged to the air spray tube (750).

One end of the water supply pipe 730 is provided with an underground water pump (not shown) for supplying the ground water and blowers for supplying air to both ends of the air spray tube 750 and the fiber material tube 780. Is provided.

The temperature control apparatus in the greenhouse according to the present invention configured as described above operates the blower and the groundwater pump to supply air to the air spray tube 750 and the fiber material tube 780 and to supply the ground water to the water supply pipe 730. .

As such, the ground water supplied to the water supply pipe 730 is sprayed in a mist-like state in both directions inside the fiber material tube 780 through the spray hole 763 of the spray nozzle 760. Air supplied from the end of the material tube 780 is discharged through the minute hole of the fiber material tube 780 is filled in the air injection tube 750.

As described above, the ground water in the fog state filled in the air spray tube 750 is sprayed into the greenhouse through the air spray hole 790 of the air spray tube 750 due to the air supplied from the end of the air spray tube 750. Decreases.

The principle of lowering the temperature inside the greenhouse is that since the groundwater temperature is usually maintained at 10 to 15 ° C., the groundwater in the fog state, which is lower than the temperature inside the greenhouse, absorbs the heat contained in the greenhouse's internal air. Will be degraded.

In other words, the temperature inside the greenhouse is a temperature suitable for growing horticultural plants with air of high temperature (45-55 ° C.) mixed with groundwater of misty state sprayed from the air injection hole 790 of the air injection tube 750. It is kept at 35 ℃.

As described above, even though the spray nozzle 760 is not sprayed with the fine particles, the water droplets that hit each other or collide with the inner surface of the air spray tube 750 are sprayed through the air spray holes 790 of the air spray tube 750. As it is not discharged into the greenhouse and flows down through the inner surface of the air spray tube 750 and the fiber material tube 780, it is collected in the water drainage path 720 and then drained to the outside.

In addition, the low temperature wind generating device 700 according to another embodiment of the present invention forms the fiber material tube 780a in a cylindrical shape with a constant diameter as shown in FIG. 45, and the ring 770a inside the fiber material tube 780a. 40 and 41 have the same configuration except that a plurality of spray holes 771 are formed to be connected to the water supply pipe 730 and sprayed to the center thereof.

In addition, the low temperature wind generating device 700 according to another embodiment of the present invention is formed in a cylindrical material having a constant diameter of the fiber material tube 780a as shown in Figure 46 and placed in the lower portion of the air injection tube 750 40 and 41, except that a water supply pipe 730a in which numerous spray holes 731 are arranged at the lower end of the fiber material tube 780a is formed.

Greenhouse control device for controlling the temperature and humidity of the ground constituting the greenhouse of the present invention and also supply oxygen to the ground, as shown in Figure 47 to 49, one side to allow air or water to flow in the land 870 of the greenhouse The pipe 810 is buried high on the other side and low on the other side, and a heating pipe 820 is provided at the center portion of the pipe 810 so as not to be in contact with the pipe 810 by a fixture 821 provided at regular intervals. .

The pipe 810 has a myriad of holes 811 formed on the outer surface thereof, and filled with fine gravel 830 to induce a smooth flow of air and water around the pipe 810, and the pipe 810 and the fine gravel 830 of the pipe 810. At the top is a guard net 840 to protect the pipe 810.

The depth of embedding of the pipe 810 should be buried to a depth that the root of the horticulture plant 800, that is, 40 to 60 cm from the ground. The reason is that the pipe 810 is heated by the heating pipe 820, which is heated to raise the ground temperature as necessary, so that the root does not come into contact with the heated pipe 810.

When the roots come into contact with the heated pipe 810, they are burned and the horticultural plant 800 dies.

In addition, the reason why the fine gravure 830 is filled around the pipe 810 is that when the air is ejected to the hole 811 of the pipe 810, the air is easily ejected while the air 811 of the pipe 810 It serves to buffer the pressure of the air blown out at the same time and to drain the moisture quickly when there is too much water in the ground.

The reason for covering the protection net 840 on the top of the pipe 810 and the fine gravel 830 is to prevent the soil from entering the hole 811 of the pipe 810 to close the hole 811.

And, in the surface of the land 870 in the greenhouse according to the present invention, the horticulture plant formed a plurality of sprinkling holes 851 so as to spray the horticultural plant 800 with water supplied from the pump in the longitudinal direction in which the horticultural plant 800 is planted. A pipe 850 is provided and the sprinkling pipe 850 is covered with a cover 860.

The reason why the watering pipe 850 is provided in the longitudinal direction in which the horticultural plant 800 is planted is to supply the insufficient water when the horticultural plant 800 lacks the water, and the cover on the watering pipe 850. The reason for covering the 860 is to prevent spreading to the outside by the water pressure when water is sprayed into the spraying hole (851) of the spraying pipe (850).

In order to supply oxygen to the roots of the horticultural plant 800 using the greenhouse control apparatus of the present invention configured as described above, as shown in FIG. 47, a blower installed at the inlet of the pipe 810 is operated to pipe air in the greenhouse. Infuse me.

At this time, the pressure for blowing air into the pipe 810 should be supplied at a minute pressure such that the soil is not scattered when the air is ejected to the hole 811 of the pipe 810.

When the air in the air is blown into the pipe 810 as described above, the air is injected through the holes 811 of the pipe 810 so that oxygen contained in the air in the air is horticultural plant 800 in the land 870. As well as being supplied to the roots, by stimulating the growth of the microorganisms in the ground, as a promoter for the growth of the horticulture plant 800, as well as the strong horticulture plant 800, of course, it is possible to increase the fruit and yield of good quality.

In addition, the present invention is to operate the boiler to increase the geothermal temperature in the land 870, the garden plant 800 grows, the hot water in the inside is circulated along the heating pipe 820 inside the pipe 810 and Heat of the hot water in the heating pipe 810 circulated together is transferred to the ground through the heating pipe 820 and the pipe 810 to increase the geothermal temperature.

The proper temperature of the geothermal temperature necessary for the growth of the horticultural plant 800 in the greenhouse is appropriately maintained at 26 to 28 ° C. as well as the atmospheric temperature.

Therefore, by embedding a temperature sensor in the ground 870 to detect the temperature of the horticulture plant 800 is a suitable temperature necessary for the growth of 26 ~ 28 ℃ or more, the boiler is automatically turned off (Off), When the temperature is lowered, it is desirable to keep the boiler on automatically at 26 to 28 ° C at all times.

In addition, the present invention is to supply the water through the hole 811 of the pipe 810 in the case of the lack of water in the land 870, the garden plant 800 grows, and conversely, if the water is excessively over the pipe 810 Absorbed through the hole 811 of the drain is smoothly drained through the drainage 812.

As described in detail above, the present invention can easily and easily perform the installation work of a solid greenhouse, and has the effect of easily controlling the temperature and ventilation inside the greenhouse where horticultural plants are grown at any time as needed.

In particular, the present invention is to adjust the temperature inside the greenhouse to suit the growing conditions of horticultural plants in summer or winter, and to control the oxygen supply as well as the moisture and temperature control of the ground where the roots grow to promote healthy growth of cultivated plants. In this way, the root development, stems and leaves of the plant can be grown without pests, thereby producing a high quality fruit and at the same time has an effect of increasing the yield.

Claims (6)

A support frame 710 provided at the bottom in the longitudinal direction; A water drainage path 720 and air spraying both ends of which are fixed to the vinyl fixing groove 220 of the pipe 210c provided on both sides of the upper end of the support frame 710 by a fixing tool 270b and a gripper 280c having a wedge shape. A tube 750; A water supply pipe 730 provided to be supported by a support 740 having both ends fixed thereto together with the water drainage path 720; And a fiber material tube 780 which is provided inside the air spray tube 750 and is arranged repeatedly to maintain a predetermined interval between the large circular ring 770 and the injection nozzle 760. According to claim 1, wherein the fibrous material tube 780 is provided in a continuous ready-mixed concrete form and the injection nozzle 760 arranged inside the fibrous material tube 780 is a plurality of spray holes 763 at both ends of the end Low temperature wind generator, characterized in that is formed. According to claim 1, The air injection tube 750 is provided with an air injection port 790 at a predetermined interval in a number of places and the air injection port 790 is fixed to the inner / outer surface of the air injection tube 750 Low temperature wind generating device, characterized in that the outer cap (791,792) and the inner / outer cap (791,792) is formed in the net body (793) so that the water to be sprayed more fine. The method of claim 1, wherein the injection nozzle 760 is formed of a hollow pipe (761) that extends from the center to both ends in the center is formed with a fastening portion 762 is circulated with the water supply pipe 730 and the hollow pipe ( 761) at the end of the low temperature wind generator, characterized in that the spray hole 763 is formed so that the water supplied from the water supply pipe (730) is sprayed. According to claim 1, wherein the fiber material tube is composed of a cylindrical fiber material tube 780a of a constant diameter and the ring 770a installed inside the fiber material tube 780a is connected to the water supply pipe 730 And a plurality of spray holes 771 are formed in the ring 770a. According to claim 1, wherein the fiber material tube is composed of a cylindrical fiber material tube 780a of a constant diameter and the water supply pipe 730a is formed with a myriad of spray holes 731 formed on the inner bottom Low temperature wind generator.