CN215301522U - Big-arch shelter irrigation equipment of adjustable liquid manure flow - Google Patents

Abstract

The utility model discloses a greenhouse irrigation device capable of adjusting water and fertilizer flow, which relates to the technical field of irrigation equipment and comprises a device shell, a conical groove and connecting rings, wherein the upper ends of two sides of the device shell are connected with second connecting pipes, the two connecting rings are positioned on the inner walls of the two second connecting pipes, which are far away from the device shell, one ends of the two connecting rings, which are far away from the device shell, are connected with fixing rings, and one ends of the two fixing rings, which are far away from the connecting rings, are connected with first connecting pipes. According to the utility model, the lifting plate is arranged, so that the effect of controlling the flow of the liquid manure can be realized, the fan blades drive the connecting shaft to rotate through water flow, meanwhile, the connecting shaft drives the reciprocating threaded rod to lift the lifting plate in the tapered groove through rotation, meanwhile, the lifting plate limits the position in the tapered groove through the limiting rod, and the lifting plate can be driven to lift to control the flow of the liquid manure through the flow velocity of the liquid manure passing through the device shell through the mutual matching of the plurality of parts.

Description

Big-arch shelter irrigation equipment of adjustable liquid manure flow

Technical Field

The utility model relates to a greenhouse irrigation device capable of adjusting water and fertilizer flow, in particular to a greenhouse irrigation device capable of adjusting water and fertilizer flow.

Background

With the production of high molecular polymers, namely polyvinyl chloride and polyethylene, plastic films are widely applied to agriculture, greenhouses are originally special equipment for vegetable production, the greenhouses are more widely applied with the development of production, the current greenhouses are used for potted flower and cut flower cultivation, fruit tree production is used for cultivating grapes, strawberries, watermelons, melons, peaches, oranges and tangerines and the like, forestry production is used for forest seedling cultivation, ornamental tree cultivation and the like, and breeding industry is used for silkworm breeding, chicken breeding, cattle breeding, pig breeding, fish, fry and the like.

Irrigation, namely watering the land with water, wherein the irrigation principle is that the irrigation amount, the irrigation frequency and the irrigation time are determined according to the water requirement characteristics of medicinal plants, the growth stage, the climate and the soil condition, and the irrigation needs to be timely, proper and reasonable, and the types of the irrigation mainly comprise irrigation before sowing, seedling promotion irrigation, growth period irrigation, winter irrigation and the like.

But at present at the in-process of irrigating, often the velocity of flow of water is difficult to control, if the rivers are too big, then the water erodees ground, destroys crops, causes the waste of water, if the water is less, then can not reach the purpose of irrigating, can't maintain the change fast alone when the condition of damage alone takes place for current irrigation equipment simultaneously, urgently need one kind can control the flow size and can carry out the big-arch shelter irrigation equipment who maintains the change alone to the device.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a greenhouse irrigation device capable of adjusting the flow of water and fertilizer, so as to solve the problems in the background art.

In order to achieve the purpose, the utility model provides the following technical scheme:

a greenhouse irrigation device capable of adjusting water and fertilizer flow comprises a device shell, two conical grooves and connecting rings, wherein the upper ends of two sides of the device shell are connected with second connecting pipes, the two connecting rings are positioned on the inner wall of one side, away from the device shell, of the two second connecting pipes, the ends, away from the device shell, of the two connecting rings are connected with fixing rings, the ends, away from the connecting rings, of the two fixing rings are connected with first connecting pipes, water conveying pipes are sleeved inside the two first connecting pipes, the conical grooves are positioned at the center of the bottom end of the device shell, the center of the lower surface of the device shell, positioned at the conical grooves, is connected with a lifting plate, the center of the upper surface of the lifting plate is connected with a reciprocating threaded rod, the center of the top end of the reciprocating threaded rod is connected with a connecting shaft, the two ends of the connecting shaft are connected with fan blades, one side, positioned at the reciprocating threaded rod, of the upper surface of the lifting plate is connected with a limiting rod, the top end of the limiting rod is connected with a connecting plate.

As a still further scheme of the utility model: the connecting shaft is rotatably connected with the device shell through a rotating shaft, and the connecting positions of the two second connecting pipes and the connecting ring are provided with rotating chutes matched with the outer wall of the connecting ring.

As a still further scheme of the utility model: the connecting position of the lifting plate and the limiting rod is provided with limiting grooves matched with the outer wall of the limiting rod, and the sizes of the inner walls of the two fixing rings are consistent with those of the inner walls of the connecting ring and the first connecting pipe.

As a still further scheme of the utility model: the lifting plate is provided with a threaded groove matched with the outer wall of the reciprocating threaded rod at the connecting position of the reciprocating threaded rod, and internal threads are formed in the two first connecting pipes.

As a still further scheme of the utility model: the outer wall of the lifting plate is matched with the inner wall of the conical groove at the position close to the lower surface, and external threads matched with the internal threads of the first connecting pipe are arranged at the connecting position of the two water conveying pipes and the internal threads of the first connecting pipe.

As a still further scheme of the utility model: the outer walls of the two fan blades are slightly smaller than the inner wall of the position where the fan blades are connected with the device shell.

Compared with the prior art, the utility model has the beneficial effects that:

1. the lifting plate is arranged, so that the effect of controlling the flow of the liquid manure can be realized, the fan blades drive the connecting shaft to rotate through water flow, the connecting shaft drives the reciprocating threaded rod to lift the lifting plate in the tapered groove through rotation, the lifting plate is limited in the tapered groove through the limiting rod, and the lifting plate can be driven to lift through the flow velocity of the liquid manure passing through the device shell to control the flow of the liquid manure through the mutual matching of the plurality of parts;

2. through setting up the go-between, can realize the effect that the device maintained the change fast, rotate with the raceway of both sides respectively through the inside internal thread of the first connecting pipe in device shell both ends and be connected, drive the go-between through solid fixed ring and carry out the rotational sliding in the inside of second connecting pipe when two first connecting pipes are connected with the raceway simultaneously, carry out limited extension when can making first connecting pipe and rotatory cup jointing of raceway through mutually supporting of above a plurality of parts.

Drawings

FIG. 1 is a schematic structural diagram of a greenhouse irrigation device capable of adjusting the flow rate of water and fertilizer;

FIG. 2 is a schematic diagram of an exploded structure of a greenhouse irrigation device capable of adjusting the flow rate of liquid manure;

FIG. 3 is a schematic view of a portion of a greenhouse irrigation apparatus with adjustable water and fertilizer flow at the position A;

fig. 4 is a schematic enlarged view of a part B of the greenhouse irrigation device capable of adjusting the flow of water and fertilizer.

In the figure: 1. a device housing; 2. a tapered groove; 3. a connecting ring; 4. a first connecting pipe; 5. a fixing ring; 6. a second connecting pipe; 7. a limiting rod; 8. a connecting plate; 9. a lifting plate; 10. a reciprocating threaded rod; 11. a fan blade; 12. a connecting shaft; 13. a water delivery pipe.

Detailed Description

Referring to fig. 1 to 4, in the embodiment of the utility model, a greenhouse irrigation device capable of adjusting the flow rate of liquid manure comprises a device shell 1, a conical groove 2 and connecting rings 3, wherein the upper ends of two sides of the device shell 1 are connected with second connecting pipes 6, the two connecting rings 3 are positioned on the inner wall of one side of the two second connecting pipes 6, which is far away from the device shell 1, one ends of the two connecting rings 3, which are far away from the device shell 1, are connected with fixing rings 5, one ends of the two fixing rings 5, which are far away from the connecting rings 3, are connected with first connecting pipes 4, water conveying pipes 13 are sleeved inside the two first connecting pipes 4, the conical groove 2 is positioned at the center of the bottom end of the device shell 1, the center of the lower surface of the device shell 1, which is positioned at the conical groove 2, is connected with a lifting plate 9, the center of the upper surface of the lifting plate 9 is connected with a reciprocating threaded rod 10, the center of the top end of the reciprocating threaded rod 10 is connected with a connecting shaft 12, both ends of the connecting shaft 12 are connected with fan blades 11, one side of the upper surface of the lifting plate 9, which is positioned on the reciprocating threaded rod 10, is connected with a limiting rod 7, and the top end of the limiting rod 7 is connected with a connecting plate 8.

The greenhouse irrigation device capable of adjusting the flow of the liquid manure enables the first connecting pipe 4 to extend in a limited way on one side of the second connecting pipe 6 through the connecting ring 3.

In FIGS. 2 to 4: the connecting shaft 12 is rotatably connected with the device shell 1 through a rotating shaft, and the connecting positions of the two second connecting pipes 6 and the connecting ring 3 are provided with rotating chutes matched with the outer wall of the connecting ring 3.

This kind of big-arch shelter irrigation equipment of adjustable liquid manure flow makes connecting axle 12 drive flabellum 11 rotate through the pivot.

In FIGS. 2 to 4: the connecting position of the lifting plate 9 and the limiting rod 7 is provided with a limiting groove matched with the outer wall of the limiting rod 7, and the sizes of the inner walls of the two fixing rings 5 are consistent with those of the connecting ring 3 and the first connecting pipe 4.

This kind of big-arch shelter irrigation equipment of adjustable liquid manure flow makes lifter plate 9 carry on spacingly when going up and down through the spacing groove.

In FIGS. 2 to 4: the connecting position of the lifting plate 9 and the reciprocating threaded rod 10 is provided with threaded grooves matched with the outer wall of the reciprocating threaded rod 10, and internal threads are arranged inside the two first connecting pipes 4.

This kind of big-arch shelter irrigation equipment of adjustable liquid manure flow makes lifter plate 9 go up and down under the rotation of reciprocal threaded rod 10 through the thread groove.

In FIGS. 2 to 4: the outer wall of the lifting plate 9 is matched with the inner wall of the conical groove 2 close to the lower surface, and the connecting position of the internal threads of the two water pipes 13 and the first connecting pipe 4 is provided with external threads matched with the internal threads of the first connecting pipe 4.

This kind of big-arch shelter irrigation equipment of adjustable liquid manure flow makes liquid manure utilize the space control output between bell jar 2 and the lifter plate 9 through the outer wall of lifter plate 9.

In FIGS. 2 to 4: the outer walls of the two blades 11 are slightly smaller than the inner wall at the position where they meet the device housing 1.

This kind of big-arch shelter irrigation equipment of adjustable liquid manure flow makes connecting axle 12 rotate under the drive of liquid manure through two flabellums 11.

The working principle of the utility model is as follows: when the device is used, the device shell 1 is placed in the middle of the two water pipes 13, at the moment, the first connecting pipes 4 at the two ends of the device shell 1 are respectively rotatably connected with the water pipes 13 at the two sides through internal threads, simultaneously, the two first connecting pipes 4 are connected with the water pipes 13 and simultaneously drive the connecting ring 3 to rotatably slide in the second connecting pipe 6 through the fixing ring 5, the first connecting pipes 4 are conveniently and rotatably connected with the water pipes 13 and simultaneously extend in a limited manner, the first connecting pipes 4 are favorable for quickly and fixedly sleeving the water pipes 13, after the device shell 1 is connected with the two water pipes 13, the water valve is opened, so that water and fertilizer flow into the device shell 1 through the water pipes 13, at the moment, the fan blades 11 drive the connecting shafts 12 to rotate through water flow, meanwhile, the reciprocating threaded rod 10 is driven to rotate through the connecting shafts 12, and the lifting plate 9 is lifted in the tapered groove 2 through the reciprocating threaded rod 10, simultaneously the lifter plate 9 is spacing in the inside of bell jar 2 through gag lever post 7, is convenient for through the rate of flow size control lifter plate 9's of liquid manure process device shell 1 lifting speed, is favorable to the water yield when not equidimension liquid manure velocity of flow through lifter plate 9 control, then carries out reverse operation to above-mentioned operation, is convenient for carry out quick replacement to taking place the device shell 1 of damage.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present invention, and the technical solutions and the utility model concepts of the present invention are equivalent to or changed within the scope of the present invention.

Claims (6)

1. The greenhouse irrigation device capable of adjusting the flow of liquid manure comprises a device shell (1), two conical grooves (2) and two connecting rings (3), wherein the upper ends of the two sides of the device shell (1) are connected with second connecting pipes (6), the two connecting rings (3) are positioned on the inner walls, away from the device shell (1), of the two second connecting pipes (6), one ends, away from the device shell (1), of the two connecting rings (3) are connected with fixing rings (5), one ends, away from the connecting rings (3), of the two fixing rings (5) are connected with first connecting pipes (4), water conveying pipes (13) are sleeved inside the first connecting pipes (4), the conical grooves (2) are positioned at the center of the bottom end of the device shell (1), and lifting plates (9) are connected at the center of the lower surface, positioned in the conical grooves (2), of the device shell (1), the utility model discloses a fan blade lifting device, including lifter plate (9), the upper surface central point of lifter plate (9) puts the department and is connected with reciprocal threaded rod (10), the top central point of reciprocal threaded rod (10) puts the department and is connected with connecting axle (12), the both ends of connecting axle (12) are connected with flabellum (11), one side that the upper surface of lifter plate (9) is located reciprocal threaded rod (10) is connected with gag lever post (7), the top of gag lever post (7) is connected with connecting plate (8).

2. The greenhouse irrigation device capable of adjusting the flow of liquid manure as claimed in claim 1, wherein the connecting shaft (12) is rotatably connected with the device housing (1) through a rotating shaft, and the connecting positions of the two second connecting pipes (6) and the connecting ring (3) are provided with rotating chutes matched with the outer wall of the connecting ring (3).

3. The greenhouse irrigation device capable of adjusting the flow of liquid manure as claimed in claim 1, wherein a limiting groove matched with the outer wall of the limiting rod (7) is formed at the joint of the lifting plate (9) and the limiting rod (7), and the inner walls of the two fixing rings (5) are consistent with the inner walls of the connecting ring (3) and the first connecting pipe (4).

4. The greenhouse irrigation device capable of adjusting the flow of liquid manure as claimed in claim 1, wherein the connection position of the lifting plate (9) and the reciprocating threaded rod (10) is provided with a threaded groove matched with the outer wall of the reciprocating threaded rod (10), and the two first connecting pipes (4) are internally provided with internal threads.

5. The greenhouse irrigation device capable of adjusting the flow of liquid manure as claimed in claim 1, wherein the outer wall of the lifting plate (9) is matched with the inner wall of the conical groove (2) at the position close to the lower surface, and external threads matched with the internal threads of the first connecting pipe (4) are formed at the connecting position of the two water pipes (13) and the internal threads of the first connecting pipe (4).

6. The greenhouse irrigation device capable of adjusting the flow of liquid manure as claimed in claim 1, wherein the outer walls of the two fan blades (11) are slightly smaller than the inner wall of the device at the position where the fan blades are connected with the device shell (1).

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