JP3916245B2 - Fully automatic roof opening and closing system for multi-storey vinyl greenhouse - Google Patents

Description

  More particularly, the present invention relates to a fully automatic roof open / close system for a multi-storey vinyl greenhouse that can be automatically opened and closed by adjusting the tension of a support band surrounding the vinyl roof.

  In general, vinyl greenhouses must produce crops of excellent quality by cultivating crops in an optimal state by freely adjusting the internal temperature, humidity, and lighting.

  As shown in FIG. 1, the conventional vinyl greenhouse is continuously installed at equal intervals, and is provided with a plurality of arch-shaped frames 1 covered with the vinyl roof 2a and the upper surface of the vinyl roof 2a at equal intervals. And a support band 3 for fixing the vinyl roof 2a. Therefore, the vinyl greenhouse supports the roof by the vinyl roof 2a.

  A lower end portion of the vinyl roof 2a is fixed to the lower portion of the roof 2, and a winding rod 5 that opens and closes the roof 2 by winding the vinyl roof 2a by the rotational driving force of the winding motor M1 provided at the end portion. Is provided. Thereby, indoor air can be circulated outside.

  In order to wind up the vinyl roof 2a, the winding rod 5 is provided inside the support band 3 as shown in the figure, and opens and closes the roof 2 while moving up and down by a winding force generated during winding.

  The winding rod 5 automatically rotates by driving the winding motor M1 and winds the vinyl roof 2a. The winding bar 5 not only moves up and down along the roof 2 by this winding operation, but also can prevent a fall by a hanging action by the wound vinyl roof 2a.

  On the other hand, the rotary links 6 are provided at both ends of the take-up bar 5 shown in the drawing, so that the take-up bar 5 can be prevented from falling and the elevation can be smoothly guided.

  As shown in the drawing, a structure in which at least one vinyl greenhouse configured as described above is installed side by side is called a multi-building vinyl greenhouse. The multi-building vinyl greenhouse is installed so as to be connected to each other on the side surface of the roof 2.

  In the valley V between the roofs 2 connected in this way, a rain gutter 4 for draining rain water is provided.

  However, according to the conventional vinyl greenhouse, the support band 3 pressurizes the outer peripheral surface of the winding bar 5, so that the winding bar 5 does not rise to the upper part of the roof 2 and a part of the lower end portion of the roof 2. Open and close only. Since the opening / closing height h of the roof 2 thus opened and closed is only about 1 m, there is a problem that only a part of the indoor air in the vinyl greenhouse is circulated without being circulated. Therefore, it is difficult to cultivate crops in the high temperature season such as summer.

  Moreover, since the vinyl roof 2a wound around the winding rod 5 is stretched and damaged by friction with the support band 3 pressurized from the outside, there is also a problem that the vinyl roof 2a must be discarded and newly replaced ( This is a frequent problem).

  Further, since the winding motor M1 is provided at one end of the winding rod 5, the rotational driving force transmitted to both ends of the winding rod 5 is different, and the end of the winding rod 5 close to the winding motor M1. Rotates smoothly, but the opposite end is not sufficiently rotated, so that both ends of the winding rod 5 rise to different heights. Thereby, a difference arises in the height of the both ends of the winding-up bar 5, and there exists a problem that not only the vinyl roof 2a is wound up diagonally but the winding-up bar 5 bends.

  Therefore, the present invention has been made to solve the above-mentioned conventional problems, and automatically adjusts the tension of the support band that supports the vinyl roof of the continuous vinyl greenhouse, and when winding the winding rod. Not only does the support band prevent the winding rod from being pressed, but the winding rod can be lifted up to the top of the roof to open the entire roof, and both ends of the winding rod can be lifted while drawing the same circumference. An object of the present invention is to provide a fully automatic roof opening / closing system for a multi-storey vinyl greenhouse that can be moved up and down while winding the vinyl roof in a horizontal state.

In order to achieve such an object, the present invention provides a plurality of vinyl greenhouses having a tunnel-shaped roof in which a plurality of support bands surround and fix a vinyl roof covered with a plurality of arch-shaped frames at equal intervals from the outside. A winding rod which is connected continuously on its side and is installed continuously to wind up or down the vinyl roof to open and close the roof; and a band tension adjusting means for adjusting the tension of the support band; In a fully automatic roof opening and closing system of a multi-storey vinyl greenhouse characterized by including
The vinyl lower end fixing portion of the take-up rod is formed so as to be inserted into the lower end portion of the vinyl roof and the vinyl accommodation groove in the axial direction along the outer peripheral surface of the take-up rod. A support piece and a fastening member are sequentially inserted, and the vinyl roof is pressed and fixed by the support piece,
The band tension adjusting means is
A plurality of shafts respectively provided in the longitudinal direction of the roof in the valley formed in the lower part between the adjacent roofs;
A support member fixed to the trough and rotatably supporting the shaft;
A transmission member connected to a drive motor and transmitting a driving force to the plurality of shafts to rotate simultaneously;
A plurality of eccentric disk pulleys attached to the shaft in an eccentric state, and adjusting the tension of the support band by the rotation in the eccentric state when the shaft rotates,
The transmission member is
A drive pinion attached to the drive motor and rotated by the drive motor;
A horizontal rack that meshes with the drive pinion and reciprocates by driving of the drive motor;
A driven pinion that is attached to each end of the plurality of shafts, meshes with the horizontal rack, and rotates by reciprocating movement of the horizontal rack to rotate the plurality of shafts;
The horizontal rack is
In order to prevent floating in both side directions during reciprocating motion, an anti-skid tool that supports both side surfaces of the horizontal rack;
A horizontal plate that supports the vertical load of the horizontal rack;
And a guide roller for rolling movement between said horizontal plate and the horizontal rack provides fully automated roof opening system including Murento vinyl greenhouse.

  In other words, the fully automatic open / close roof system of the multi-storey vinyl greenhouse according to the present invention can automatically adjust the tension of the plurality of support bands by the band tension adjusting means to raise the winding rod to the upper end of the roof. Automatic opening and closing of the entire roof is possible. Therefore, the indoor air is completely ventilated to improve the ventilation efficiency of the greenhouse.

At the time of winding of the roll bar, to prevent the support band from interfering, it is to that effect also prevents damage to the vinyl roof due to friction with the support band.

  Hereinafter, the present invention will be described with reference to the accompanying drawings. In the drawings, substantially the same components are denoted by the same reference numerals.

  2 is a perspective view showing a fully automatic open / close roof system of a multi-building vinyl greenhouse according to the present invention, FIG. 3 is a plan view of the multi-building vinyl greenhouse shown in FIG. 2, and FIG. 4 is a front view of the multi-building vinyl greenhouse shown in FIG. It is.

  5 is a side sectional view showing the configuration of the mounting block and the winding rod shown in FIG. 2, FIG. 6 is a front view of the eccentric disc pulley shown in FIG. 2, and FIG. 7 is the front view of the eccentric disc pulley shown in FIG. FIG. 8 is a conceptual view showing an operation concept of the eccentric disc pulley shown in FIG.

  As shown in the figure, the fully automatic roof open / close system for a multi-storey vinyl greenhouse according to the present invention comprises a plurality of vinyl greenhouses in which the sides of the roof 2 are connected to each other to form a multi-storey building. The vinyl greenhouse has a tunnel-shaped roof 2 in which a plurality of support bands 3 surround and fix a vinyl roof 2a placed on a plurality of arch-shaped frames 1 provided continuously from the front to the rear at equal intervals. Have.

  A valley V is formed between the adjacent roofs 2, and a gutter 4 is provided in the valley V.

  In the present invention, a mounting block 100 for fixing the vinyl roof 2 a and the upper end portions of the support band 3 is fixed on the arch-shaped frame 1 in the longitudinal direction of the roof 2 as shown in FIG. 2. The mounting block 100 can be installed by being fixed to the arched frame 1 using the clamp 101 shown in FIG. 5, or the arched frame 1 and the mounting block 100 can be fixed by welding.

  The vinyl roof 2a fixed to the mounting block 100 is fixed at the lower side surfaces of the mounting block 100 by vinyl fixing means. The support band 3 fixed to the mounting block 100 is fixed on the upper side surfaces of the mounting block 100 by the band fixing means.

  The vinyl fixing means and band fixing means will be described in detail with reference to FIG. The vinyl fixing means first forms insertion grooves 110 along the longitudinal direction on both side surfaces of the lower portion of the mounting block 100, and inserts the upper end portion of the vinyl roof 2a into this. Then, the insertion groove cover 112 formed so as to be insertable into the insertion groove 110 is inserted and fastened to the mounting block 100 by the fastening member 114. Thereby, the vinyl roof 2a is pressurized and fixed by the insertion groove cover 112.

  At this time, the upper end of the vinyl roof 2a must be inserted into the insertion groove 110 so as to protrude above the mounting block 100. The insertion groove cover 112 preferably extends at least one compression rib R inwardly and in the longitudinal direction as shown in the figure so as to press and fix the vinyl roof 2a in a zigzag shape.

  Of course, the compression ribs R are most preferably formed at the upper and lower ends and the center of the insertion groove cover 112. In this case, the compression rib R formed at the center is inserted into the insertion groove 110, and the compression rib R formed at the upper and lower ends of the insertion groove cover 112 is formed so as to pressurize the outer end portion of the insertion groove 110. The

  In order for the compression ribs R formed at the upper and lower ends of the insertion groove cover 112 to pressurize the outer portion of the insertion groove 110 more strongly, the receiving grooves or protrusions for accommodating the compression ribs R at the upper and lower ends are mounted on the mounting block 100. It is good to provide along both side surfaces.

  Thus, the vinyl roof 2a is integrally fixed to the mounting block 100 by the insertion groove 110, the insertion groove cover 112, and the fastening member 114.

  Next, the band fixing means has a locking bulge portion 122 provided at the tip of the support band 3 and an insertion groove 120 provided along both upper side surfaces of the mounting block 100 and having one end open. ing. The support band 3 is fixed by inserting the locking bulging portion 122 into the insertion groove 120.

  As shown in FIG. 2, the support band 3 is composed of a plurality, and the locking bulging portions 122 of the plurality of support bands 3 are sequentially inserted into the insertion groove 120 on the front side or the rear side of the mounting block 100. In other words, the support band 3 must be arranged along the insertion grooves 120 facing each other of the mounting block 100 at equal intervals.

  Accordingly, the locking bulging portion 122 of the support band 3 is strongly inserted into the insertion groove 120 facing the mounting block 100, so that the support band 3 is integrally fixed to the insertion groove 120 of the mounting block 100. .

  Of course, the shape of the locking bulging portion 122 and the insertion groove 120 of the band fixing means is not limited to the circular cross section as shown in the figure, and depending on the case, the cross section can be variously formed such as a square or a triangle. .

  Further, the support band 3 may be fixed to the mounting block 100 with screws, nails or the like without forming the locking bulging portion 122 and the insertion groove 120 in the mounting block 100.

  Also, the band fixing means may be formed in a ring shape, different from that shown in the figure, and may be fixed by penetrating the support band 3 with this ring.

  This will be described in more detail. A plurality of rings may protrude from the upper surface of the mounting block 100 at equal intervals, and the support band 3 may be fixed by the rings. Such a support band 3 can be fixed without being interlocked with the mounting block 100 by being fixed to the ring.

  The present invention also includes a plurality of winding rods 210. Each winding rod 210 includes a vinyl lower end fixing portion 212 provided along the outer peripheral surface of the winding rod 210 in order to fix the lower end portion of the vinyl roof 2a. The take-up motor M1 is provided at the end of the take-up bar 210 in order to rotate the take-up bar 210. Then, in order to open and close the roof 2, the winding rod 210 moves upward and downward between the upper and both ends of the roof 2 while winding or unwinding the vinyl roof 2 a.

  Here, as shown in FIG. 5, the vinyl lower end fixing portion 212 forms a vinyl housing groove 212 a in the axial direction along the outer peripheral surface of the winding rod 210. Then, the lower end portion of the vinyl roof 2a is inserted into the vinyl receiving groove 212a, and then the support piece 212b formed to be insertable into the vinyl receiving groove 212a is inserted, and then the fastening member 212c is inserted and wound. The take-up bar 210 is fastened. Thereby, the vinyl roof 2a is pressurized and fixed by the support piece 212b.

  At this time, the support piece 212b is preferably formed long along the axial direction of the winding rod 210 so as to press and support the entire lower end of the vinyl roof 2a along the vinyl accommodation groove 212a.

  In this way, the lower end portion of the vinyl roof 2a is pressurized by the support piece 212b and firmly fixed to the vinyl accommodation groove 212a of the winding rod 210.

  Further, in order to more firmly fix the vinyl roof 2a to the winding rod 210, it is only necessary to provide at least one compression rib R 'as shown inside the support piece 212b. 2a is firmly fixed in a wedge shape.

  On the other hand, the reason why the take-up bar 210 has the vinyl housing groove 212 a for fixing the vinyl roof 2 a is to prevent the support piece 212 b and the fastening member 212 c from protruding from the outer peripheral surface of the take-up bar 210.

  If the lower end portion of the vinyl roof 2a is wound around the outer peripheral surface of the winding rod 210 in which the vinyl accommodating groove 212a is not formed and fixed with the support piece 212b and the fastening member 212c, the thickness of the support piece 212b and the fastening member 212c is increased. The vinyl roof 2a wound in a stacked manner is wound while protruding from the support piece 212b and the fastening member 212c. As a result, the protruding portion may be caught by the support band 3 and damaged, or vinyl may be wrinkled.

  However, such a protrusion of the vinyl roof 2a can be prevented by forming the vinyl accommodation groove 212a in the winding rod 210 and fixing the vinyl roof 2a therein. Therefore, the vinyl roof 2a can be prevented from being caught by the support band 3.

  Furthermore, the present invention includes a take-up bar level maintaining means 300 that is provided at both ends of the take-up bar 210 and maintains the horizontal state while guiding the lifting and lowering of the take-up bar 210. As shown in FIGS. 2 to 4, the winder bar horizontal maintaining means 300 is provided with pinions 310 integrally at both ends of the rotating winder bar 210, and the pinions 310 are respectively provided on both sides of the roof 2 at the lower part. An arched rack 320 is provided which meshes while supporting. Thus, when the winding rod 210 rotates, the pinions 310 at both ends run along the circumference of the arched rack 320 and are moved up and down while maintaining the horizontal state at both ends of the winding rod 210. .

  Here, the arched rack 320 can be fixed on the horizontal plate 502 by, for example, installing a vertical column 500 having a horizontal plate 502 as shown at the upper end on the outside of the roof 2. Alternatively, the horizontal plate 502 can be mounted on the already installed arched frame 1 and fixed thereon.

  Of course, without attaching the horizontal plate 502 to the vertical column 500, the arched rack 320 may be directly attached to the upper end of the vertical column 500. In addition, it can be mounted on the top of the arch-shaped frame 1 so as to be integrated with the arch-shaped frame 1, or it is configured to be long downward so that both ends of the arch-shaped rack 320 reach the ground. You can also.

  On the other hand, on both sides of the pinion 310, there are provided guide plates 350 that support both sides of the arched rack 320 and guide traveling while preventing the traveling pinion 310 from being detached.

  At this time, it is preferable that a roller 352 that assists the travel of the pinion 310 is attached to the lower portion of the guide plate 350 by rotating in close contact with the lower surface of the arched rack 320 when the pinion 310 travels. Thereby, the guide plate 350 can guide the travel of the pinion 310 more easily.

  The take-up bar horizontal maintaining means 300 configured as described above travels along the arched rack 320 while the take-up bar 210 is rotated by the take-up motor M1 and the pinions 310 at both ends of the take-up bar 210 are also rotated. Therefore, both ends of the winding rod 210 are moved up and down while maintaining the same height, that is, a horizontal state. The pinion 310 smoothly travels without being separated from the arched rack 320 by the guide plate 350.

  Finally, the present invention constrains a part of the support band 3 and selectively pulls or loosens the support band 3 by the winding operation of the winding rod 210 to adjust the tension of the support band 3. Tension adjusting means 400 is included.

  2 and 3, the band tension adjusting means 400 includes a plurality of shafts 410 respectively provided in the longitudinal direction of the roof 2, with a plurality of valleys V formed in the lower part between the adjacent roofs 2, and And a plurality of support members 420 fixed to the valley V and rotatably supporting the shaft 410.

  The band tension adjusting means 400 is connected to the drive motor M2 and transmits the driving force to the plurality of shafts 410 to be rotated at the same time. The band tension adjusting unit 400 is attached to the shaft 410 in an eccentric state. A plurality of eccentric disc pulleys 450 as shown in FIGS. 2 and 6 adjust the tension by rotating or rotating the shaft 410 in an eccentric state to pull or loosen the support band 3 when the shaft 410 rotates. Including.

  As shown in FIG. 2, the support member 420 is made of a plate material having a circular bearing 422 attached to the center, and is fixed to the rain gutter 4. The shaft 410 passes through the circular bearing 422 and is fixed to the gutter 4 in a rotatable state.

  Of course, the support member 420 may be fixed to the lower end of the arched frame 1 without being fixed to the gutter 4. As another method, a “π” -shaped bending bar that is not a plate material may be applied, and the shaft 410 may be placed on the upper end thereof.

  That is, a π-shaped bending bar may be vertically attached to the bottom of the rain gutter 4 or the arch-shaped frame 1 and the shaft 410 may be placed on the top.

  As shown in FIGS. 2 and 3, the transmission member 430 is coupled to the drive motor M2 to rotate, meshes with the drive pinion 432, and reciprocates toward the shaft 410 by the drive motor M2. The horizontal rack 434 includes a horizontal rack 434 and a driven pinion 436 that is attached to the ends of the plurality of shafts 410 and meshes with the horizontal rack 434 and rotates by the reciprocating motion of the horizontal rack 434 to rotate the plurality of shafts 410.

  As shown in FIGS. 2 and 4, the horizontal rack 434 prevents the floating of the horizontal rack 434 from both sides during the reciprocating motion, and the anti-skid tool 434 a that supports both sides of the horizontal rack 434 and the vertical of the horizontal rack 434. It includes a horizontal plate 502 that supports a load, and a guide roller 434b that is in close contact with the lower surface of the horizontal rack 434 and that rolls between the horizontal plate 502 and the horizontal rack 434.

  Accordingly, when the drive pinion 432 is driven by the drive motor M2, the horizontal rack 434 is prevented from moving to both sides by the anti-skid tool 434a and smoothly reciprocates by the guide roller 434b.

  When the horizontal rack 434 reciprocates in this way, the driven pinion 436 integrally coupled with the shaft 410 is also rotated by the horizontal rack 434. As a result, the shaft 410 also rotates in conjunction with it.

  Of course, the horizontal rack 434 rotates a plurality of shafts 410 in conjunction with each other as shown.

  As described above, when the shaft 410 rotates, the eccentric disc pulley 450 also rotates in an eccentric state to pull or loosen the support band 3.

  That is, the eccentric disk pulley 450 pulls the support band 3 while rotating downward, as shown by a solid line in FIG. 8, and releases the pulling operation while returning to the original position as shown by a dotted line. The tension state of the support band 3 is released. The tension control operation of the eccentric disc pulley 450 will be described in detail later.

  As shown in FIG. 7, an annular idle bearing 455 that rotates idly is provided on the outer peripheral surface of the eccentric disc pulley 450, and the support band 3 that is pulled or loosened when rotating in an eccentric state is provided. , To prevent the eccentric disc pulley 450 from being wound around the outer peripheral surface.

  If the idle bearing 455 is not provided, the support band 3 is wound by the frictional force with respect to the outer peripheral surface of the eccentric disc pulley 450. When wound in this way, the support band 3 on the rotational direction side of the eccentric disc pulley 450 is wound more than the support band 3 on the opposite side.

  That is, the eccentric disk pulley 450 pulls only the rotation direction side more without pulling the support band 3 equally from both sides.

  However, when the idle bearing 455 that idles in this way is provided, the support band 3 is not wound around the outer peripheral surface of the eccentric disk pulley 450 due to the idle rotation of the idle bearing 455, and therefore the eccentric disk pulley 450 is supported. The band 3 can be pulled evenly from both sides.

  More specifically, when the shaft 410 rotates in the clockwise direction, the eccentric disc pulley 450 rotates downward in an eccentric state to pull the support band 3 downward, and the support band 3 is pulled by the tensile force of the eccentric disc pulley 450. While being tense, it is rubbed with the idle bearing 455, and the idle bearing 455 is idly rotated by the frictional force.

  Therefore, the support band 3 is not wound around the outer peripheral surface of the eccentric disk pulley 450 by the idle bearing 455 that rotates idly, and thus the eccentric disk pulley 450 can evenly pull the support band 3 from both sides.

  On the other hand, when the eccentric disc pulley 450 rotates in the opposite direction, that is, when the eccentric disc pulley 450 rotates counterclockwise in the eccentric state, the idle bearing 455 is idly rotated by the frictional force of the support band 3, so that the eccentric disc pulley 450 is Loosen the support band 3 evenly from both sides. Therefore, the support band 3 is released from the tension state and loosens.

  Since the outer peripheral surface of the eccentric disc pulley 450 is formed in a U-shaped cross section and the inner peripheral surface of the idle bearing 455 is formed in a V-shaped cross section, when the idle bearing 455 is idling, The circumferential surface makes line contact and reduces frictional resistance.

  That is, the eccentric disc pulley 450 has a concave outer peripheral surface like a general V-belt pulley, and the idle bearing 455 takes a form in which the center of the cross section is sharp like a V-belt.

  Therefore, the eccentric disk pulley 450 and the idle bearing 455 can minimize the frictional resistance generated during idling due to the outer peripheral surface and the inner peripheral surface formed so as to be in line contact with each other.

  In the present invention, the idle bearing 455 is preferably formed of a rubber or urethane material so as to ensure a frictional force against the support band 3 and to be inserted into the outer peripheral surface of the eccentric disc pulley 450 while expanding and contracting.

  The operating principle of the eccentric disk pulley 450 configured and operated in this way is shown in FIG. The momentum equation (Equation 1) for calculating the vertical momentum of the eccentric disk pulley 450 that performs rotational motion in an eccentric state is expressed by the symbols shown in the drawings as follows.

Formula 1

  Here, d indicates the diameter of the shaft 410, and r indicates the radius of the eccentric disc pulley 450. d and r are determined from the size (diameter and radius) of the shaft 410 and the eccentric disc pulley 450 manufactured according to the embodiment of the present invention.

  The momentum equation is used to set the sizes of the shaft 410 and the eccentric disk pulley 450 by calculating the moving distance by which the support band 3 is pulled. Alternatively, it is used to calculate the moving distance of the support band 3 depending on the set size of the shaft 410 and the eccentric disc pulley 450.

  When the winding rod 210 winds the vinyl roof 2a, the eccentric disc pulley 450 must rotate upward in an eccentric state to loosen the support band 3, and once the winding of the vinyl roof 2a is completed, The support band 3 must be tensioned by rotating downward in an eccentric state.

  That is, after the eccentric disc pulley 450 loosens the support band 3, the winding rod 210 winds the vinyl roof 2a, and when the winding rod 210 finishes winding, the eccentric disc pulley 450 again supports the support band 3. I have to be nervous.

  Therefore, the winding rod 210 is not interfered by the support band 3 when winding the vinyl roof 2a, and is firmly fixed by the support band 3 after the winding is completed.

  Thus, since the support band 3 does not interfere with the winding operation of the winding rod 210, the winding rod 210 is close to the mounting block 100 mounted on the roof 2 as shown in FIG. It can be lifted up to 3.8 m) and most of the roof 2 can be opened.

  As described above, in the fully automatic open / close roof system of the multi-storey vinyl greenhouse according to the present invention, the lower end portion of the vinyl roof 2 a wound around the winding rod 210 is connected to the vinyl lower end fixing portion 212 provided inside the winding rod 210. Since it is inserted, even if the vinyl roof 2a is wound around the winding rod 210, a part thereof does not protrude from the outer peripheral surface.

  Further, the winding rod 210 is maintained at the same level at both ends by the winding rod horizontal maintaining means 300, so that the winding operation and the lifting operation can be performed while maintaining the horizontal state.

  Further, since the tension of the support band 3 can be selectively adjusted, it is possible not only to prevent the support band 3 from interfering with the take-up bar 210 but also to the lower end of the mounting block 100 of the roof 2. Since 210 winds up the vinyl roof 2a, almost the entire roof 2 can be opened.

  9 is a front view of a multi-storey vinyl greenhouse according to another embodiment of the present invention, FIG. 10 is an enlarged front view of a valley section of the multi-storey vinyl greenhouse shown in FIG. 9, and FIG. 11 is a winding shown in FIG. It is a front view which expands and shows a rod accommodating member.

  As shown in the figure, the other embodiment of the present invention is substantially the same in configuration as the above-described embodiment of the present invention, but only the take-up bar horizontal maintaining means 300 is separated from the pinion 310 and the arched rack 320. Without being configured, the configuration is different from a disc collar 310-1 and an arched guide rail 320-1 described later.

  Furthermore, the fully automatic opening and closing roof system according to another embodiment of the present invention selectively restrains the winding unit 210 in the valley V between the continuously installed roofs 2 by the operation of the eccentric disk pulley 450. Thus, the winding rod 210 includes a winding rod receiving member 250 that prevents the winding rod 210 from floating.

  This will be described in detail later. In this description, the same reference numerals are given to the same parts as those of the above-described embodiment, and the description thereof is omitted, and unnecessary parts are not described.

  As shown in FIG. 9, the take-up bar horizontal maintaining means 300 according to another embodiment of the present invention is integrally provided at both ends of the rotating take-up bar 210 and rotates while the take-up bar 210 is raised and lowered. A disc collar 310-1 that moves up and down together with the take-up rod 210, and a lower portion of the disc collar 310-1 that supports the lower portion of the disc collar 310-1 so that the take-up rod 210 forms a horizontal state. And an arched guide rail 320-1 that guides the vehicle up and down while traveling in an arch shape.

  Of course, as shown in the drawing, a rail groove 320-1a into which the disk collar 310-1 is inserted is formed on the outer peripheral surface of the arched guide rail 320-1, so that the disk collar is raised when the winding rod 210 is moved up and down. It is preferable that 310-1 travel while rotating along the rail groove 320-1a.

  However, an insertion groove (not shown) like a normal pulley is formed on the outer peripheral surface of the disc collar 310-1, and the insertion protrusion inserted into the insertion groove on the outer peripheral surface of the arched guide rail 320-1. A strip (not shown) may be formed and configured.

  The winding rod level maintaining means 300 is a guide plate that supports both sides of the arched guide rail 320-1 in order to prevent the traveling disc collar 310-1 from being detached from the arched guide rail 320-1. 350 is further included.

  A roller 352 is further provided at the lower portion of the guide plate 350 to help the disk collar 310-1 travel in close contact with the lower surface of the arched guide rail 320-1.

  Accordingly, the take-up bar horizontal maintaining means 300 configured as described above has a height of both ends of the take-up bar 210 by the guide plate 350 having the disk collar 310-1, the arched guide rail 320-1, and the roller 352. Can be maintained in the same horizontal state.

  As shown in FIGS. 10 and 11, the take-up bar accommodating member 250 according to another embodiment of the present invention is a rain provided separately in one side of the arched frame 1 located in the valley V of the roof or in the valley V. A fixing plate 252 to be fixed (by welding or screw fastening) is provided on one side surface of the flange 4. One side of the fixed plate 252 has an inner diameter that is slightly smaller than the outer diameter of the winding rod 210, and has an open side elastic ring 255 that is integrally provided with round portions 255a that are bent outward at the upper and lower ends. Is provided. Accordingly, when the winding rod 210 is inserted into the elastic ring 255 while pressurizing the round portion 255a, the elastic ring 255 has a repulsive force for rejecting the winding rod 210.

  At this time, an inclined piece 257 extending obliquely upward from the elastic ring 255 is provided at the upper end of the elastic ring 255, and the winding rod 210 is guided along the inclined piece 257 and inserted into the elastic ring 255. It is preferable to configure as described above.

  Therefore, when the winding bar 210 descends from the upper end of the roof 2 to the valley V side along the arched guide rail 320-1 while rewinding the vinyl roof 2a, it is placed on the inclined piece 257 as shown in FIG. Thereafter, the winding rod 210 is guided to the elastic ring 255 by the inclined piece 257.

  When the wound vinyl roof 2a is all returned and the winding rod 210 is positioned at the open portion of the elastic ring 255 as shown in the drawing, the eccentric disk pulley 450 rotates and tensions the support band 3.

  Then, the winding bar 210 is pressurized while the support band 3 is tensioned, and the winding bar 210 slides on the round portion 255 a of the elastic ring 255 and is inserted into the elastic ring 255.

  At this time, since the inner diameter of the elastic ring 255 is smaller than the outer diameter of the winding rod 210, a repulsive force that rejects the winding rod 210 is generated while being expanded as the winding rod 210 is inserted.

  However, since this elastic repulsive force cannot overcome the pressure applied to the support band 3 by the eccentric disc pulley 450, the state where the winding rod 210 is inserted into the elastic ring 255 is maintained.

  When the take-up bar 210 is inserted into the elastic ring 255 and fixed in this way, the vinyl roof 2a connected to the take-up bar 210 is completely extended and pinched. Therefore, in order to maximize the light transmission efficiency of the vinyl roof 2a, the light transmittance of the vinyl roof 2a is greatly improved.

  Further, since the vinyl roof 2a is connected to the take-up bar 210 fixed to the take-up bar housing member 250, the vinyl roof 2a is not blown and the take-up bar 210 does not move freely.

  When the winding rod 210 is housed in the winding rod housing member 250 as shown in FIG. 11, it is possible to prevent the winding rod 210 inserted into the elastic ring 255 from being contaminated by dust or foreign matter.

  When the eccentric disk pulley 450 rotates reversely to take up the winding rod 210 and the tension state of the support band 3 is loosened, the expanded elastic ring 255 contracts due to its own elastic force and the support band 3 Overcome pressure.

  Then, the elastic ring 255 having a curved surface and the winding rod 210 slide by the curved surface contact, and thereby the winding rod 210 is detached from the elastic ring 255.

  When the winding rod 210 is thus separated from the elastic ring 255, the winding rod 210 can perform the winding operation of the vinyl roof 2a again.

  As described above, the winding rod 210 is selectively inserted into or separated from the winding rod receiving member 250 by the operation of the eccentric disc pulley 450.

  Although the preferred embodiments of the present invention have been disclosed for the purpose of illustration, those skilled in the art will recognize that various modifications and additions can be made without departing from the scope and spirit of the present invention as disclosed in the appended claims. And alternatives will be understood.

It is a perspective view which shows the conventional continuous building vinyl greenhouse. It is a perspective view which shows the fully automatic opening and closing roof system of the multi-row vinyl greenhouse by this invention. It is a top view of the continuous building vinyl greenhouse shown in FIG. It is a front view of the continuous building vinyl greenhouse shown in FIG. It is side surface sectional drawing which shows the structure of the mounting block and winding rod which are shown in FIG. It is a front view of the eccentric disc pulley shown in FIG. It is a perspective view of the eccentric disc pulley shown in FIG. It is a conceptual diagram which shows the operation | movement concept of the eccentric disc pulley shown in FIG. It is a front view of the continuous greenhouse vinyl greenhouse by the other Example of this invention. It is a front view which expands and shows the trough part of the continuous building vinyl greenhouse shown in FIG. It is a front view which expands and shows the winding-bar accommodation member shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Arch-shaped frame 2 ... Roof 2a ... Vinyl roof 3 ... Support band 4 ... Rain gutter 100 ... Mounting block 110,120 ... Insertion groove 112 ... Insertion groove cover 114 ... Fastening member 122 ... Locking bulging part 210 ... Winding Bar 212 ... Vinyl lower end fixing portion 212a ... Vinyl receiving groove 212b ... Supporting piece 212c ... Fastening member 250 ... Winding rod receiving member 252 ... Fixing plate 255 ... Elastic ring 255a ... Round portion 257 ... Inclined piece 300 ... Winding rod horizontal maintenance Means 310 ... Disk collar 320 ... Arched guide rail 350 ... Guide plate 352 ... Roller 400 ... Band tension adjusting means 410 ... Shaft 420 ... Support member 430 ... Transmission member 432 ... Drive pinion 434 ... Horizontal rack 434a ... Anti-skid tool 434b ... guide roller 436 ... driven pinion 450 ... eccentric circle Plate pulley 455 ... Idle bearing 502 ... Horizontal plate M1, M2 ... Winding motor

Claims (3)

A plurality of vinyl greenhouse having a tunnel-shaped roof vinyl roof placed over the plurality of arcuate frame a plurality of support bands are fixed surrounds at equal intervals from the outside, continuously placed are connected by their sides, the Fully automatic multi- building greenhouse with a winding rod that winds up or down while winding or unwinding the vinyl roof and opens and closes the roof, and band tension adjusting means for adjusting the tension of the support band In the roof opening and closing system,
The vinyl lower end fixing portion of the take-up rod is formed so as to be inserted into the lower end portion of the vinyl roof and the vinyl accommodation groove in the axial direction along the outer peripheral surface of the take-up rod. A support piece and a fastening member are sequentially inserted, and the vinyl roof is pressed and fixed by the support piece,
The band tension adjusting means is
A plurality of shafts respectively provided in the longitudinal direction of the roof in the valley formed in the lower part between the adjacent roofs;
A support member fixed to the trough and rotatably supporting the shaft;
A transmission member connected to a drive motor and transmitting a driving force to the plurality of shafts to rotate simultaneously;
A plurality of eccentric disk pulleys attached to the shaft in an eccentric state, and adjusting the tension of the support band by the rotation in the eccentric state when the shaft rotates,
The transmission member is
A drive pinion attached to the drive motor and rotated by the drive motor;
A horizontal rack that meshes with the drive pinion and reciprocates by driving of the drive motor;
A driven pinion that is attached to each end of the plurality of shafts, meshes with the horizontal rack, and rotates by reciprocating movement of the horizontal rack to rotate the plurality of shafts;
The horizontal rack is
In order to prevent floating in both side directions during reciprocating motion, an anti-skid tool that supports both side surfaces of the horizontal rack;
A horizontal plate that supports the vertical load of the horizontal rack;
A fully automatic roof open / close system for a multi-storey vinyl greenhouse, comprising: the horizontal plate; and a guide roller that rolls between the horizontal racks . The eccentric disc pulley further includes an annular idle bearing that idles on the outer peripheral surface of the eccentric disc pulley in order to prevent the support band from being wound around the outer peripheral surface of the eccentric disc pulley. ,
The outer peripheral surface of the eccentric disc pulley is formed in a U-shaped cross section, the inner peripheral surface of the idle bearing is formed in a V-shaped cross section, and the outer peripheral surface and the inner peripheral surface are in line contact with each other when the idle bearing is idling. fully automated roof opening and closing system of Row vinyl greenhouse according to claim 1, wherein the frictional resistance is reduced by. A take-up bar receiving member that is provided in a valley formed in a lower portion between the roofs and selectively restrains the take-up bar by the operation of the eccentric disk pulley to prevent the take-up bar from moving freely; Including
The winding rod housing member is provided with a fixing plate fixed to one side surface of the arched frame located in the valley or one side surface of a rain gutter separately provided in the valley, and on one side of the fixing plate In order to accommodate the winding rod, the winding rod can be added to the round portion by providing a one-side open elastic ring integrally formed with the round portion bent outward at the upper and lower ends. When inserted into the elastic ring while pressing, the elastic ring will generate a repulsive force that rejects the winding rod,
Since inclined piece on the upper end of the resilient ring is extended obliquely upward claim 1, characterized in that the roll bar is inserted into the interior of the elastic ring is guided along the inclined piece Fully automatic roof opening and closing system for listed greenhouses.

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