CN114557230A

CN114557230A - A irrigation equipment for climbing cane crop

Info

Publication number: CN114557230A
Application number: CN202210302932.6A
Authority: CN
Inventors: 李智勇; 齐静; 滕海波; 郭舒心; 裴亮; 叶昕; 许泽帆; 聂相田
Original assignee: North China University of Water Resources and Electric Power
Current assignee: North China University of Water Resources and Electric Power
Priority date: 2022-03-24
Filing date: 2022-03-24
Publication date: 2022-05-31
Anticipated expiration: 2042-03-24
Also published as: CN114557230B

Abstract

An irrigation device for climbing vine crops comprises a hollow supporting rod, supporting components arranged at intervals along the height direction of the supporting rod and a water delivery channel arranged in the supporting rod; the supporting assembly comprises a supporting rod, a supporting spring and a partition plate, the partition plate is arranged in a cavity of the supporting rod, the supporting spring is connected between the supporting rod and the partition plate, through holes for the two ends of the supporting rod to penetrate out are formed in the side wall of the supporting rod, a control mechanism for controlling the supporting spring to be in a compressed state is further arranged between the supporting spring and the supporting rod, and the supporting spring is used for pushing the supporting rod to move after the control mechanism removes the control action; the lower part of the water delivery channel is communicated with the inner cavity of the supporting rod, the lower part of the supporting rod is used for being inserted into soil, and the side wall of the supporting rod inserted into the soil is provided with a pouring hole which is used for allowing water in the water delivery channel to flow out so as to irrigate crops. The invention is used for uniformly irrigating the climbing vine crops through the climbing vine device.

Description

A irrigation equipment for climbing cane crop

Technical Field

The invention relates to the field of plant irrigation, in particular to an irrigation device for climbing vines.

Background

The creeper crops refer to plants which are attached to and wound around other objects to grow, and the common plants include the tigers, roses, wisteria floribunda, grapes, passion fruits and the like. In agricultural production, the planting of rattan vegetables and fruits accounts for most of summer vegetables and fruits variety, and the planting in-process of rattan vegetables and fruits is provided with generally climbs the rattan device to support rattan vegetables and fruits, and strengthen the air permeability and the illumination of plant, increase of production. In order to enhance the climbing effect of the vines on the vine climbing device, the vine climbing device in the prior art is often provided with a fixing clamp, the vines are fixed on the vine climbing device by the fixing clamp when the crops are about to bear fruits, the crops need to be irrigated regularly in order to guarantee the requirements of the crops on moisture, on one hand, the labor intensity is high, on the other hand, when the planting area is large, the uneven irrigation points can cause that partial crops are difficult to be irrigated fully, the drought and waterlogging of the crops are uneven, and therefore the growth of the crops is affected.

Disclosure of Invention

The invention aims to provide an irrigation device for climbing crops, which is used for uniformly irrigating the climbing crops through the climbing device.

In order to solve the technical problems, the invention adopts the specific scheme that: an irrigation device for climbing vine crops comprises a hollow supporting rod, supporting components arranged at intervals along the height direction of the supporting rod and a water delivery channel arranged in the supporting rod; the supporting assembly comprises a supporting rod, a supporting spring and a partition plate, the partition plate is arranged in a cavity of the supporting rod, the supporting spring is connected between the supporting rod and the partition plate, through holes for the two ends of the supporting rod to penetrate out are formed in the side wall of the supporting rod, a control mechanism for controlling the supporting spring to be in a compressed state is further arranged between the supporting spring and the supporting rod, and the supporting spring is used for pushing the supporting rod to move after the control mechanism removes the control action; the lower part of the water delivery channel is communicated with the inner cavity of the supporting rod, the lower part of the supporting rod is used for being inserted into soil, and the side wall of the supporting rod inserted into the soil is provided with a pouring hole which is used for allowing water in the water delivery channel to flow out so as to irrigate crops.

As a further optimization of the technical scheme, the control mechanism is a control line connected between the partition plate and the support rod, and the control line is made of a soluble material.

As a further optimization of the technical scheme, a first water outlet corresponding to the bearing assembly is formed in the side wall of the water delivery channel, a water baffle is arranged inside the water delivery channel, a second water outlet corresponding to the first water outlet is formed in the water baffle, and the relative position of the first water outlet and the second water outlet is adjusted to control the water flow direction control line in the water delivery channel.

As the further optimization of the technical scheme, a plurality of water permeable holes are formed in the partition plate.

As the further optimization of above-mentioned technical scheme, the division board is located the below of bearing rod, and the through-hole is for being used for supplying the gliding bar hole from top to bottom of bearing rod.

As above-mentioned technical scheme's further optimization, the division board is located the top of bearing pole, and the bearing pole includes two bearing branch of mutual articulated, and bearing spring's one end is connected on the division board, and the pin joint at bearing branch is connected to the other end, and the through-hole is for being used for supplying bearing branch pivoted bar hole.

As the further optimization of the technical scheme, the bearing support rod is provided with the limiting pin for controlling the hinge angle, and the limiting pin is positioned at one end, close to the hinge point, of the bearing support rod.

As a further optimization of the technical scheme, the control mechanism is a pull rope which sequentially penetrates through all the bearing assemblies from bottom to top.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the water delivery channel is arranged in the support rod to irrigate the plants, so that the internal space of the support rod is reasonably utilized, the waste of space resources is avoided, the support rods are uniformly distributed in the planting area, and the uniform irrigation of the crops can be realized.

2. Two mutual articulated bearing branch constitute the bearing pole, and bearing spring connects in the mutual articulated position of bearing branch, promotes the pin joint through bearing spring and moves down to make bearing branch keep away from the upwards perk of one end of pin joint, make the branch of climbing on bearing branch attach more stable, need not to reuse the fixation clamp to fix the branch, alleviateed operation intensity.

3. Be provided with the spacer pin of articulated angle of control on the bearing branch, avoid because control mechanism when too big to the ascending pulling force of bearing branch, cause the height that highly is higher than the through-hole at the horizontal direction pin joint, and then make the outside bearing branch downward sloping of bracing piece that stretches out, influence the climbing of plant.

4. The irrigation holes arranged at the bottom of the supporting rod and the nozzles arranged on the side wall of the supporting rod form a three-dimensional irrigation system which irrigates the roots of the plants and the branch blades climbing on the supporting rod respectively, so that the irrigation requirement of climbing vines is met.

Drawings

FIG. 1 is a schematic view of a support spring in a compressed state according to an embodiment;

FIG. 2 is an enlarged view taken at A in FIG. 1;

FIG. 3 is an enlarged view at B in FIG. 1;

FIG. 4 is a schematic view of an embodiment of a support spring in an extended position;

FIG. 5 is a diagram of the method at C in FIG. 4;

FIG. 6 is a top view of the divider plate;

FIG. 7 is a schematic structural diagram according to a second embodiment;

FIG. 8 is a side view of the second embodiment;

FIG. 9 is a schematic structural view of the third embodiment;

reference numerals: 1. the supporting rod 2, the water delivery channel 3, the bearing component 301, the partition plate 301-1, the water permeable hole 302, the bearing spring 303, the control line 304, the bearing rod 304-1, the bearing supporting rod 304-2, the hinge point 304-3, the limiting pin 4, soil 5, the water baffle 6, the first water outlet hole 7, the second water outlet hole 8, the watering hole 9, the through hole 10 and the pull rope.

Detailed Description

The first embodiment is as follows:

as shown in fig. 1 and 2, the present invention relates to an irrigation device for climbing vine crops, which comprises a hollow supporting rod 1, supporting components 3 arranged at intervals along the height direction of the supporting rod 1, and a water delivery channel 2 arranged in the supporting rod 1.

The quantity of bearing subassembly 3 is the multiunit, and bearing subassembly 3 is used for supplying the branch climbing of climbing cane crop to adhere to. Bearing subassembly 3 includes bearing rod 304, bearing spring 302 and division board 301, division board 301 sets up inside the cavity of bracing piece 1, bearing spring 302 is connected between bearing rod 304 and division board 301, set up the through-hole 9 that supplies bearing rod 304 both ends to wear out on the lateral wall of bracing piece 1, still be provided with the control mechanism that control bearing spring 302 is in compression state between bearing spring 302 and the bearing rod 304, bearing spring 302 is used for promoting bearing rod 304 to remove after control mechanism removes control action.

The control mechanism is a control wire 303 connected between the partition plate 301 and the support rod 304, the control wire 303 is made of a soluble material, and the control wire 303 used in the present invention is a commercially available normal temperature water-soluble wire.

The lower part of the supporting rod 1 is used for being inserted into soil 4 to fix the supporting rod 1, a pouring hole 8 (shown in figure 3) is formed in the side wall of the supporting rod 1 inserted into the soil 4, and the pouring hole 8 is circumferentially distributed along the side wall of the supporting rod 1. The water delivery channel 2 is a water delivery pipe penetrating through the support rod 1, the water delivery pipe penetrates through the partition plate 301, and the partition plate 301 can limit the water delivery pipe to prevent the water delivery pipe from inclining. The lower water outlet end of the water delivery channel 2 is communicated with the inner cavity of the support rod 1, and the lower water outlet end of the water delivery channel 2 is also inserted into the soil 4 after the support rod 1 is inserted into the soil 4, so that water in the water delivery channel 2 flows into the soil 4 through the irrigation holes 8 to irrigate the roots of crops.

The lateral wall of the water delivery channel 2 is provided with a first water outlet hole 6 corresponding to the bearing component 3, a water baffle 5 is arranged inside the water delivery channel 2, the water baffle 5 is strip-shaped, the length of the water baffle 5 is consistent with that of the water delivery channel 2, the cross section of the water baffle 5 is arc-shaped and consistent with the inner wall of the water delivery channel 2, and a second water outlet hole 7 corresponding to the first water outlet hole 6 is formed in the water baffle 5. When irrigating crops, the first water outlet 6 is located above the second water outlet 7, the strip-shaped water baffle 5 stops water from flowing to the control line 303, and when the bearing rod 304 needs to be controlled to move to adjust the branch supporting condition, the strip-shaped water baffle 5 is moved upwards to align the first water outlet 6 and the second water outlet 7, so that the water in the water delivery channel 2 flows to the control line 303.

The upper portion of the water delivery channel 2 is connected with a section of telescopic pipe (not shown in the figure), the telescopic direction of the telescopic pipe is a vertical direction, the water baffle 5 is located inside the telescopic pipe, the upper end of the water baffle 5 is connected with the upper end of the telescopic pipe, the upper portion of the telescopic pipe is pulled upwards to enable the telescopic pipe to be unfolded, the water baffle 5 can be driven to move upwards, the upwards stretching height of the telescopic pipe is controlled, and the first water outlet 6 and the second water outlet 7 are aligned. The filling device is used for irrigating greenhouse plants, the mechanism for drawing the telescopic pipe to stretch upwards is a traction rope and a pulley for winding the traction rope, the pulley is fixed on the top of the greenhouse, and the traction rope is connected to the upper part of the telescopic pipe after passing through the pulley. After the control line 303 is dissolved, stop to pull flexible pipe upwards, breakwater 5 moves down under the effect of gravity, and first apopore 6 staggers with second apopore 7, and first apopore 6 stops the drainage. In order to prevent the water baffle 5 from inclining in the water delivery channel 2, restraint strips are further arranged in the water delivery channel 2 at intervals, the restraint strips are transversely arranged inside the water delivery channel 2 and are consistent with the radian of the water delivery channel 2, and the water baffle 5 is located in an arc-shaped channel formed by the restraint strips and the water delivery channel 2 and can slide up and down in the arc-shaped channel.

As shown in fig. 6, the partition plate 301 is provided with a plurality of water permeable holes 301-1 so that water after the solvent control line 303 flows into the surface of the soil 4 to irrigate crops.

As another embodiment of the water delivery passage 2, the water delivery passage 2 may be a passage divided in the support rod 1 along the length direction of the support rod 1, and the water guard 5 is located inside the water delivery passage 2.

As shown in fig. 4 and 5, the divider plate 301 is located above the support rod 304, the support rod 304 includes two support struts 304-1 hinged to each other, the hinge point 304-2 is located at the end of the two support struts 304-1, one end of the support spring 302 is connected to the divider plate 301, and the other end is connected to the hinge point 304-2 of the support rod 304. The through hole 9 formed on the side wall of the support rod 1 is a strip-shaped hole for supporting the rotation of the support rod 304-1. The hinge point 304-2 is pushed to move downwards by the bearing spring 302, so that one end of the bearing support rod 304-1 far away from the hinge point 304-2 tilts upwards, a branch climbing on the bearing support rod 304-1 is more stable, a fixing clamp is not needed to fix the branch, and the operation intensity is reduced.

The position of the bearing support rod 304-1 close to the hinge point 304-2 is further provided with a limiting pin 304-3, the limiting pin 304-3 is located on one side of the bearing support opposite to the supporting spring, and the limiting pin 304-3 is used for controlling the hinge angle of the bearing support rod 304-1 so as to avoid that the height of the hinge point 304-2 in the horizontal direction is higher than that of the through hole 9 when the upward pulling force of the control mechanism on the bearing support rod 304-1 is too large, and further the bearing support rod 304-1 extending out of the support rod 1 is inclined downwards to influence the climbing of plants.

In addition, because the climbing crop occupies a large space, irrigation is required both on the vine and on the ground. Blades on the pergola are higher off the ground, so that water can not reach top blades sometimes by drip irrigation, the mode of large-area spray irrigation easily causes insufficient water absorption of crop roots, one irrigation mode can not meet the growth requirement of climbing vines in arid and high-heat areas, the yield of crops is reduced, and economic loss is brought to farmers. Can set up the multiunit nozzle on the lateral wall of bracing piece 1, the water inlet of nozzle is connected on water delivery passageway 2, and the nozzle is unified control by the solenoid valve, through the nozzle that waters 8 and the 1 lateral wall of bracing piece setting in 1 bottom of bracing piece, constitutes three-dimensional irrigation system, waters the root of plant and the blade on the bearing pole 304 respectively, satisfies the irrigation needs of climbing cane plant.

Example two:

as shown in fig. 7 and 8, the second embodiment has the same structure as the first embodiment, except that the supporting rod 304 of the present embodiment is integrally formed, the partition plate 301 is located below the supporting rod 304, and the through hole 9 formed in the side wall of the supporting rod 1 is a strip-shaped hole for allowing the supporting rod 304 to slide up and down, when the control line 303 is dissolved by water, the supporting spring 302 releases elastic potential energy, and the supporting spring 302 drives the supporting rod 304 to slide up, so that the branches climbing on the supporting rod 304 are supported more firmly by the upward acting force, and branches not climbing on the supporting rod 304 contact the supporting rod 304 due to the adjustment of the position of the supporting rod 304.

Example three:

as shown in figure 9, the three embodiments are the same as the first embodiment in the main structure of the supporting member 3 and the supporting rod 1, but the third embodiment is different from the first embodiment in the way of arranging the control mechanism and the water supply channel 2.

Specifically, the control mechanism in the third embodiment is a pull rope 10 sequentially passing through all the supporting members 3 from bottom to top, and a stopper is disposed at a joint between the supporting rod 304 of each group of supporting members 3 and the pull rope 10, so that when the pull rope 10 is pulled tightly, the supporting rod 304 is driven by the stopper to move upward to compress the supporting spring 302. After releasing the pull rope 10, the support spring 302 pushes the hinge point 304-2 of the support strut 304-1 to move downward, so that the end of the support strut 304-1 far from the hinge point 304-2 tilts upward to support the crop branches.

The water delivery channel 2 in the third embodiment is a water delivery pipe penetrating through the support rod 1, the water delivery pipe penetrates through the partition plate 301, and the partition plate 301 can limit the water delivery pipe to prevent the water delivery pipe from inclining in the support rod 1. The lower water outlet end of the water delivery channel 2 is communicated with the inner cavity of the support rod 1, and the lower water outlet end of the water delivery channel 2 is also inserted into the soil 4 after the support rod 1 is inserted into the soil 4, so that water in the water delivery channel 2 flows into the soil 4 through the irrigation holes 8 to irrigate the roots of crops. In addition, the water supply passage 2 may be a passage partitioned in the support rod 1 along the length direction of the support rod 1.

Set up the multiunit nozzle on the lateral wall of bracing piece 1, the water inlet of nozzle is connected on water delivery passageway 2, and the nozzle is by the unified control of solenoid valve, and the blade of water in the water delivery passageway 2 through the nozzle blowout of the lateral wall of bracing piece 1 in order to water the plant, rivers are irrigated the root of plant in soil 4. Through the irrigation hole 8 that sets up in bracing piece 1 bottom and the nozzle that the bracing piece 1 lateral wall set up, constitute three-dimensional irrigation system, water the root of plant and the blade on the bearing pole 304 respectively, satisfy the irrigation needs of climbing cane plant.

Claims

1. An irrigation device for climbing vine crops is characterized by comprising a hollow supporting rod (1), supporting components (3) arranged at intervals along the height direction of the supporting rod (1) and a water delivery channel (2) arranged in the supporting rod (1);

the bearing component (3) comprises a bearing rod (304), a bearing spring (302) and a partition plate (301), the partition plate (301) is arranged in a cavity of the supporting rod (1), the bearing spring (302) is connected between the bearing rod (304) and the partition plate (301), a through hole (9) for penetrating out of two ends of the bearing rod (304) is formed in the side wall of the supporting rod (1), a control mechanism for controlling the bearing spring (302) to be in a compression state is further arranged between the bearing spring (302) and the bearing rod (304), and the bearing spring (302) is used for pushing the bearing rod (304) to move after the control mechanism removes control action;

the lower part of water delivery passageway (2) goes out the water end and is linked together with the inner chamber of bracing piece (1), and the lower part of bracing piece (1) is used for inserting in soil (4) and insert bracing piece (1) lateral wall in soil (4) and seted up irrigation hole (8), and irrigation hole (8) are used for supplying the rivers play in water delivery passageway (2) in order to irrigate the crop.

2. An irrigation device for climbing vines according to claim 1, wherein the control mechanism is a control line (303) connected between the partition plate (301) and the support bar (1), the control line (303) being of a soluble material.

3. The irrigation device for the climbing crops as claimed in claim 2, wherein a first water outlet hole (6) corresponding to the bearing component (3) is formed in the side wall of the water delivery channel (2), a water baffle (5) is arranged inside the water delivery channel (2), a second water outlet hole (7) corresponding to the first water outlet hole (6) is formed in the water baffle (5), and the relative position of the first water outlet hole (6) and the second water outlet hole (7) is adjusted to control the water flow direction control line (303) in the water delivery channel (2).

4. An irrigation device for climbing vine crops according to claim 2, wherein a plurality of water permeable holes (301-1) are provided on the partition plate (301).

5. An irrigation device for climbing vine crops according to claim 2, characterized in that the partition plate (301) is located below the support rod (304), and the through hole (9) is a strip-shaped hole for the support rod (304) to slide up and down.

6. An irrigation device for climbing vine crops according to claim 2, wherein the divider plate (301) is located above the support rod (304), the support rod (304) comprises two support struts (304-1) hinged to each other, one end of the support spring (302) is connected to the divider plate (301), the other end of the support spring is connected to a hinged point (304-2) of the support strut (304-1), and the through hole (9) is a strip-shaped hole for allowing the support strut (304-1) to rotate.

7. An irrigation device for climbing vines according to claim 6, characterized in that the supporting struts (304-1) are provided with limiting pins (304-3) for controlling the hinging angle, the limiting pins (304-3) being located at the ends of the supporting struts (304-1) close to the hinging point (304-2).

8. An irrigation device for climbing vines according to claim 1, characterized in that the control means is a pull rope (10) passing through all the supporting members (3) in sequence from bottom to top.