CN115226601B - Gardens greenbelt water-saving irrigation device - Google Patents

Abstract

The utility model relates to a garden equipment's field especially relates to a gardens greenbelt water-saving irrigation equipment, and it is including the trunk line that is used for the water delivery, be provided with a plurality of minutes pipelines that are used for inserting in the soil on the trunk line, be in charge of the inside trunk line and be linked together and be used for the water delivery with the trunk line is inside, run through on the minute pipeline and set up a plurality of water holes that are used for watering irrigation, it is provided with the soil loosening disc to slide on the minute pipeline, the soil loosening disc slides on the minute pipeline and is used for loosening the soil, be provided with on the minute pipeline and be used for making the gliding drive assembly of soil loosening disc. This application has the effect of reducing the extravagant probability of evaporation of moisture and piling up on the soil top layer.

Description

Gardens greenbelt water-saving irrigation device

Technical Field

The application relates to the field of garden equipment, in particular to a garden greenbelt water-saving irrigation device.

Background

Along with the development of the society in China, greening is more and more paid attention to, and a piece of greening garden is provided for people to scatter the mind and body health of people is maintained.

The irrigation device is usually used when watering green land, and comprises a pipeline arranged on a soil layer, wherein the end part of the pipeline is connected to a water pump, a plurality of water holes for water supply sprinkling are formed in the side wall of the pipeline, and a processor for controlling the water pump to be started at a specified time and closed at the specified time.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: when the irrigation device sprays water to the green land, the upper soil absorbs water, so that the upper soil is solid, the underwater seepage speed is reduced, and the water is accumulated on the soil surface layer and volatilized into the air to generate waste.

Disclosure of Invention

In order to solve the problem that water is accumulated on the surface layer of soil and volatilized into the air to generate waste, the application provides a water-saving irrigation device for garden greenbelts.

The application provides a gardens greenbelt water-saving irrigation equipment adopts following technical scheme:

the utility model provides a gardens greenbelt water-saving irrigation equipment, is including the trunk line that is used for the water delivery, be provided with a plurality of minutes pipelines that are used for inserting in the soil on the trunk line, divide the inside and the trunk line of pipeline to be linked together and be used for the water delivery, run through on the minute pipeline and set up a plurality of water holes that are used for watering irrigation, it is provided with the soil loosening disk to slide on the minute pipeline, the soil loosening disk slides on the minute pipeline and is used for loosening the soil, be provided with on the minute pipeline and be used for making the gliding drive assembly of soil loosening disk.

Through adopting above-mentioned technical scheme, when needs water greenery patches soil, the staff accessible drive assembly makes the disc that loosens the soil slide on dividing the pipeline, simultaneously divide the soil near the pipeline to carry out the operation of loosening the soil, the water hole on the dividing pipeline that the rethread inserted to in the soil is watered, make from the infiltration of water hole internal spun water to soil more quick, improved the soaking speed of water, make the moisture more wet soil, improved the speed of soil to moisture absorption, simultaneously still through loosening up the soil and improved the air content in the soil, improved soil fertility, simultaneously because the direct watering of water is inside the soil, reduced the water volatilizees to the outside air in, thereby cause the probability of water resource waste, reach the purpose of saving water resource.

Optionally, the soil loosening disc is including the ring of twining, the ring cover of twining is established and is slided on dividing the pipeline, drive assembly is used for driving the ring of twining and slides, it is provided with the carousel to twine to rotate on the ring, the carousel cover is established outside the ring of twining, be formed with the soil drilling face that is the slope setting on the carousel lateral wall, the slope soil drilling face is used for making things convenient for the carousel to bore soil.

Through adopting above-mentioned technical scheme, drive the dish ring through drive assembly and slide on being in branch pipeline, the soil is separated through the brill soil surface of slope, has reduced the resistance that the carousel received when sliding and loosening the soil for the process of loosening the soil is more smooth and rapid.

Optionally, the soil drilling surface is provided with a rotary groove for soil to pass through, the length direction of the rotary groove is in an arc shape, and the rotary groove is used for enabling the soil to drive the turntable to rotate.

Through adopting above-mentioned technical scheme, bore the soil face and carry out divided in-process to soil, soil extrusion is contradicted on changeing the inslot wall, through being the changeing the groove that the arc set up for soil is to changeing the pivoted power of carousel when changeing the reaction force of inslot wall and providing one under the direction of changeing the groove setting direction, and will accelerate after the carousel rotates and bore the soil face and dial out the speed of soil, thereby further improved the efficiency of loosening the soil.

Optionally, the disc ring is provided with a limiting block, and the branch pipeline is provided with a limiting groove for the limiting block to insert and slide.

Through adopting above-mentioned technical scheme, insert to the spacing inslot through the stopper and slided, played spacing effect to the dish ring, reduced the dish ring and rotated to lead to the dish ring to lead to the probability that the pipeline lateral wall was divided to the wearing and tearing, played the guard action to the pipeline lateral wall.

Optionally, the spout has been seted up on the water hole inner wall, it has the breakwater to slide in the spout, the breakwater is used for covering the water hole opening surface sealed, the control groove has been seted up on the stopper, it has the control block to slide in the control groove, be provided with the spring between control groove inner wall and the control block, the spring stretches out and draws back along the slip direction of control block, the control block is used for promoting the breakwater and slides, be provided with the guide face on the control block tip, the guide face is used for contradicting and guiding the control block to move back into towards the control groove with the breakwater tip.

By adopting the technical scheme, the water hole is controlled to be opened and closed through the water baffle, so that the probability of blockage in the branch pipelines caused by soil entering the branch pipelines from the water hole when the water hole does not work is reduced, and the water baffle plays a role in protecting the branch pipelines and the water hole; meanwhile, when the control block slides to drive the control block, the control block is inserted and abuts against the water baffle under the action of the elastic force of the spring when the control block is aligned to the gap between the water baffle and the sliding chute, so that the water baffle slides along with the sliding of the control block, the water hole is opened or closed at the moment, when the water baffle slides to abut against the inner wall of the sliding chute and is difficult to slide continuously, the control block returns to the control groove under the guidance of the guiding surface, so that the stop block slides continuously, the opening and closing of the water hole can be controlled through the stop block, the operation is greatly facilitated, the driving source is reduced, the energy is saved, and the manufacturing cost is reduced.

Optionally, the breakwater is last to run through and to have offered the auxiliary hole, it has the auxiliary block to slide in the auxiliary hole, the length of auxiliary block is greater than the degree of depth in auxiliary hole, the auxiliary block is used for contradicting on the guide surface.

Through adopting above-mentioned technical scheme, drive breakwater and supplementary piece through the control block conflict on the breakwater and slide, when the breakwater will be contradicted to on the spout inner wall, supplementary piece will be contradicted earlier on the spout inner wall, the control block will continue to push up and move the breakwater and slide this moment, and because the guide face is contradicted on supplementary piece, because supplementary piece is difficult to slide this moment for the guide face is retracted towards the direction of moving back into the control groove under the guide of self inclination, thereby makes the retraction of control block more smooth and easy.

Optionally, an abutting groove is formed in the inner wall of the auxiliary hole, and an abutting block used for being inserted into and sliding in the abutting groove is arranged on the auxiliary block.

Through adopting above-mentioned technical scheme, insert through the conflict piece and slide in conflict inslot for when supplementary piece takes place the mistake in supplementary downthehole smooth, contradict on conflict inslot wall through the conflict piece, played spacing effect to the slip of supplementary piece, reduced the probability that supplementary piece deviate from in the supplementary hole, improved the stability of supplementary piece.

Optionally, the length of the control block occupied by the guide surface is smaller than the width of the auxiliary block plus the thickness between the inner wall of the auxiliary hole and the outer side wall of the adjacent water baffle, and the length of the control block occupied by the guide surface plus the width of the auxiliary block is larger than the thickness between the inner wall of the auxiliary hole and the outer side wall of the adjacent water baffle.

By adopting the technical scheme, the guide surface is abutted against the auxiliary block, the side wall of the control block is abutted against the side wall of the water baffle to realize driving sliding, the control block continues to slide only when the auxiliary block is abutted against the inner wall of the chute and is difficult to slide, the guide surface is abutted against the auxiliary block, the guide surface enables the control block to slide towards the direction of retreating into the control groove under the self-inclined guide, at the moment, the guide surface can be abutted against the side wall of the water baffle, and then the control block is completely retreated into the control groove under the abutting; under this operating mode, when the control block drives the breakwater and the auxiliary block slides jointly, only through the conflict of control block lateral wall and breakwater lateral wall in order to realize sliding, improved the reliability, when having reduced guide face and breakwater lateral wall conflict, when leading to the guide face to be difficult to promote the breakwater because of breakwater lateral wall and spout inner wall frictional force is too big, make the control block withdraw from the spout under the guide of the lateral wall of guide face slope and withdraw from the probability in the control groove.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the method has the advantages that the infiltration of water to the soil is faster, the soaking speed of the water is improved, the water is easier to wet the soil, the water absorption rate of the soil is improved, the air content in the soil is improved, the soil fertility is improved, the probability that the water volatilizes to the outside air is reduced, and the water resource waste is caused, so that the purpose of saving the water resource is achieved.

2. The process of loosening the soil is smoother and faster, the outer side wall of the split pipeline is protected, the opening and closing of the water hole can be controlled through the limiting block, the operation is greatly facilitated, the driving source is reduced, the energy is saved, and the manufacturing cost is reduced.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a garden greenbelt water-saving irrigation device in an embodiment of the application.

Fig. 2 is an enlarged schematic view of the structure at a in fig. 1.

Fig. 3 is a schematic cross-sectional view taken along line B-B of fig. 1.

Fig. 4 is a schematic diagram showing an exploded structure of the chute.

Fig. 5 is an enlarged schematic view of the structure at C in fig. 3.

Reference numerals illustrate: 1. a main pipe; 11. dividing the pipeline; 12. a water hole; 13. a soil loosening disc; 14. a drive assembly; 2. a disc ring; 21. a turntable; 22. drilling the soil surface; 23. a rotary groove; 24. a limiting block; 25. a limit groove; 3. a chute; 31. a water baffle; 32. a control groove; 33. a control block; 34. a spring; 35. a guide surface; 4. an auxiliary hole; 41. an auxiliary block; 42. a collision groove; 43. a collision block; 5. inserting a ring; 51. a slot.

Detailed Description

The present application is described in further detail below in conjunction with the appended claims 1-5.

The embodiment of the application discloses a gardens greenery patches water-saving irrigation equipment. Referring to fig. 1, the garden greenbelt water-saving irrigation device comprises a main pipeline 1 for delivering water, wherein a water pump is connected to the end part of the main pipeline 1 and used for controlling the water to be delivered in the main pipeline 1. The main pipeline 1 is fixedly connected with a plurality of branch pipelines 11 which are inserted into the soil, and the inside of each branch pipeline 11 is communicated with the inside of the main pipeline 1 and is used for water delivery. The outer side wall of the branch pipeline 11 is provided with a plurality of water holes 12 for watering irrigation in a penetrating way, the water holes 12 are symmetrically and uniformly distributed on the branch pipeline 11, and the water holes 12 are distributed along the length direction of the branch pipeline 11. The outer side wall of the branch pipeline 11 is provided with a soil loosening disc 13 in a sliding mode, the soil loosening disc 13 slides along the length direction of the branch pipeline 11, the soil loosening disc 13 slides on the branch pipeline 11 to loosen soil, and a driving assembly 14 for enabling the soil loosening disc 13 to slide is arranged on the end portion, close to the main pipeline 1, of the branch pipeline 11. The staff can reduce the probability of damaging the green plant root system when the soil loosening disc 13 loosens the soil by adjusting the arrangement of the branch pipelines 11.

Referring to fig. 2, the soil loosening disc 13 includes a disc ring 2, the disc ring 2 is circumferentially sleeved and slides on the outer side wall of the branch pipe 11, a limiting block 24 is fixedly connected to the disc ring 2, a limiting groove 25 for inserting and sliding the limiting block 24 is formed in the branch pipe 11, the limiting groove 25 extends along the length direction of the branch pipe 11, and the driving assembly 14 is used for driving the disc ring 2 to slide.

Referring to fig. 2, the driving assembly 14 includes a rotating motor mounted on the end of the sub-pipe 11 near the main pipe 1, and a screw rod fixedly connected to a rotating shaft of the rotating motor and coaxially rotated with the rotating shaft of the rotating motor. The lead screw is inserted into the limit groove 25 of the branch pipeline 11, the length direction of the lead screw extends along the length direction of the branch pipeline 11, the lead screw is inserted into and penetrates through the limit block 24, and the lead screw is in threaded connection with the limit block 24.

Referring to fig. 3, a turntable 21 is rotatably connected to the outer ring side wall of the disc ring 2, the turntable 21 is circumferentially sleeved and rotated outside the disc ring 2, an insert ring 5 is fixedly connected to the inner ring side wall of the turntable 21, the insert ring 5 circumferentially surrounds the inner ring side wall of the turntable 21, a slot 51 for inserting the insert ring 5 is formed in the outer ring side wall of the disc ring 2, and the slot 51 is matched with the insert ring 5. The outer side wall of the turntable 21, which is opposite to the main pipeline 1, is provided with an inclined earth drilling surface 22, and the inclined earth drilling surface 22 is used for facilitating earth drilling of the turntable 21, wherein the farther the earth drilling surface 22 is from the main pipeline 1, the closer the outer side wall of the branch pipeline 11 is.

Referring to fig. 2 and 3, the disc ring 2, the turntable 21 and the stopper 24 are all inclined toward the side wall of the main pipe 1, the closer the disc ring 2, the turntable 21 and the stopper 24 are to the bottom wall of the stopper groove 25, the closer to the main pipe 1, and the inclined side wall surfaces of the disc ring 2, the turntable 21 and the stopper 24 are connected.

Referring to fig. 2 and 3, a plurality of rotating grooves 23 for soil to pass through are formed in the soil drilling surface 22, the length direction of the rotating grooves 23 is arc-shaped, the length direction of the rotating grooves 23 extends from the end, far away from the main pipeline 1, of the soil drilling surface 22 towards the end, close to the main pipeline 1, of the soil drilling surface 22, when the screw rod rotates to drive the disc ring 2 to slide, soil is abutted against the soil drilling surface 22, at the moment, the soil is extruded on the inner wall of the rotating grooves 23, and the soil is guided by the length direction of the rotating grooves 23 to drive the rotary table 21 to rotate.

Referring to fig. 4 and 5, two water holes 12 symmetrically distributed on two sides of the branch pipeline 11 are a group, a chute 3 is formed on the inner wall of the water hole 12, the chutes 3 on the inner walls of the water holes 12 in the same group are communicated, the same water baffle 31 slides in the chute 3, the water baffle 31 slides in the chute 3 along the length direction of the branch pipeline 11, the depth of the chute 3 is greater than the height of the water baffle 31, the height of the water baffle 31 is greater than the diameter of the opening surface of the water hole 12, the water baffle 31 is used for covering and sealing the opening surface of the water hole 12, the outer side wall of the water baffle 31 is abutted against the inner wall of the chute 3, and the water baffle 31 is fixed in the position of the chute 3 by friction after sliding.

Referring to fig. 5, the sliding path of the limiting block 24 is located at the middle section of the water baffle 31 between the same group of water holes 12, a control groove 32 is formed in the side wall of the end part of the limiting block 24, which is close to the water baffle 31, a control block 33 is arranged in the control groove 32 in a sliding manner, the outer side wall of the control block 33 is abutted against the inner wall of the control groove 32, the control block 33 slides towards the direction, which is close to or far away from the water baffle 31, a spring 34 is fixedly connected between the bottom wall, which faces the opening surface of the control groove 32, of the control block 33, and the outer side wall of the control block 33, and the spring 34 stretches along the sliding direction of the control block 33.

Referring to fig. 5, the control block 33 is configured to abut against a side wall of the water baffle 31 to push the water baffle 31 to slide, two guide surfaces 35 are provided on an end portion of the control block 33 away from the bottom wall of the control slot 32, the two guide surfaces 35 are respectively provided on a side wall of the control block 33 facing or facing away from the main pipe 1, and the two guide surfaces 35 are closer to each other as the guide surface 35 is further from the bottom wall of the control slot 32. The guide surface 35 is used to interfere with the end of the water deflector 31 and guide the control block 33 to retract into the control groove 32.

Referring to fig. 4 and 5, the water baffle 31 is provided with an auxiliary hole 4, the auxiliary hole 4 penetrates along the height direction of the water baffle 31, and the position of the auxiliary hole 4 corresponds to the position of the limit groove 25. An auxiliary block 41 is slid in the auxiliary hole 4, the length of the auxiliary block 41 is larger than the depth of the auxiliary hole 4, and the auxiliary block 41 is used for abutting against the guide surface 35. The side walls at two ends of the auxiliary block 41 are all inclined, and the inclined side walls of the auxiliary block 41 are respectively used for abutting and attaching with the corresponding guide surface 35, so that the control block 33 withdraws from the side wall of the water baffle 31 and retreats into the control groove 32 under the abutting of the guide surface 35 and the auxiliary block 41.

Referring to fig. 5, an abutting groove 42 is formed on the inner wall of the auxiliary hole 4, the abutting groove 42 is circumferentially formed on the inner wall of the auxiliary hole 4, and the abutting groove 42 is formed along the length direction of the auxiliary hole 4. The auxiliary block 41 is fixedly connected with a collision block 43 which is inserted into and slides in the collision groove 42, the collision block 43 is circumferentially fixed on the outer side wall of the auxiliary block 41, and the outer side wall of the collision block 43 is in collision fit with the inner wall of the collision groove 42, so that the collision block 43 is matched with the collision groove 42.

Referring to fig. 4 and 5, the length of the control block 33 occupied by the guide surface 35 is smaller than the width of the auxiliary block 41 plus the thickness between the inner wall of the auxiliary hole 4 and the outer side wall of the adjacent water baffle 31, and the length of the control block 33 occupied by the guide surface 35 plus the width of the auxiliary block 41 is larger than the thickness between the inner wall of the auxiliary hole 4 and the outer side wall of the adjacent water baffle 31. So that the guide surface 35 is abutted against the inclined side wall of the auxiliary block 41, and the side wall of the control block 33 is abutted against the side wall of the water baffle 31, thereby simultaneously driving the auxiliary block 41 and the water baffle 31 to slide.

The implementation principle of the garden green land water-saving irrigation device provided by the embodiment of the application is as follows: when the water baffle 31 is in an initial state, the water baffle 31 covers and plugs the opening surface of the water hole 12, and when the rotating motor drives the disc ring 2 to slide in a direction away from the main pipeline 1, soil enters and collides on the inner wall of the rotary groove 23, so that the rotary table 21 rotates. The end of the control block 33 abuts against the bottom wall of the limit slot 25 facing away from the opening surface thereof, so that the control block 33 is integrally retracted in the control slot 32, and the spring 34 is in a compressed state. When the limiting block 24 slides to the position of the chute 3, the control block 33 is separated from the abutting state with the bottom wall of the limiting groove 25, at this time, the control block 33 is inserted between the side wall of the water baffle 31 facing the main pipe 1 and the side wall of the chute 3 facing away from the main pipe 1, the side wall of the control block 33 facing away from the main pipe 1 abuts against the side wall of the water baffle 31 facing the main pipe 1, and meanwhile, the guide surface 35 of the control block 33 facing away from the main pipe 1 abuts against the side wall of the inclined end portion of the auxiliary block 41 close to the main pipe 1.

At this time, the disc ring 2 continues to slide in a direction away from the main pipe 1, the control block 33 simultaneously collides and drives the water baffle 31 and the auxiliary block 41 to slide in a direction away from the main pipe 1, and at this time, the water baffle 31 moves away from the opening surface of the water hole 12, so that the water hole 12 starts to spray water. When the auxiliary block 41 slides until the end of the auxiliary block 41 away from the main pipe 1 collides with the inner wall of the chute 3 facing the main pipe 1, the auxiliary block 41 is difficult to continue sliding, and the control block 33 continues sliding, and the side wall of the control block 33 still collides with the side wall of the water baffle 31, so as to push the water baffle 31 to slide, in the process, under the common guidance of the guide surface 35 and the inclined side wall of the auxiliary block 41, the control block 33 will retract into the control groove 32, and finally the control block 33 slides until the guide surface 35 collides with the side wall of the water baffle 31, and the control block 33 continues sliding to completely retract the control block 33 from the chute 3.

When the water hole 12 is required to be closed after watering, the disc ring 2 is driven to slide towards the direction close to the main pipeline 1 by rotating the motor, when the limiting block 24 slides to the position of the sliding groove 3, the control block 33 is separated from the abutting state with the bottom wall of the limiting groove 25, at the moment, the control block 33 is inserted between the side wall of the water baffle 31 facing away from the main pipeline 1 and the side wall of the sliding groove 3 facing towards the main pipeline 1, the side wall of the control block 33 facing away from the main pipeline 1 is abutted against the side wall of the water baffle 31, meanwhile, the guide surface 35 of the control block 33 facing towards the main pipeline 1 is abutted against the side wall of the inclined end part of the auxiliary block 41 far away from the main pipeline 1, at the moment, the control block 33 continuously slides to push the auxiliary block 41 and the water baffle 31 to slide towards the direction close to the main pipeline 1, so that the opening surface of the water hole 12 is covered and plugged, and the purpose of closing the water hole 12 is achieved.

When the auxiliary block 41 slides until the end of the auxiliary block 41 close to the main pipe 1 collides with the inner wall of the chute 3 facing away from the main pipe 1, the auxiliary block 41 is difficult to continue sliding, and the control block 33 continues sliding, and the side wall of the control block 33 still collides with the side wall of the water baffle 31, so that the water baffle 31 is pushed to continue sliding until colliding with the inner wall of the chute 3, in the process, under the common guidance of the guide surface 35 and the inclined side wall of the auxiliary block 41, the control block 33 will retract into the control groove 32, and finally the control block 33 slides until the guide surface 35 collides with the side wall of the water baffle 31, and the control block 33 continues sliding to completely retract from the chute 3.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (3)

1. A gardens greenbelt water-saving irrigation equipment, its characterized in that: the novel water-saving type soil loosening device comprises a main pipeline (1) for water delivery, wherein a plurality of branch pipelines (11) for being inserted into soil are arranged on the main pipeline (1), the inside of each branch pipeline (11) is communicated with the inside of the main pipeline (1) and is used for water delivery, a plurality of water holes (12) for watering and irrigating are formed in the branch pipelines (11) in a penetrating mode, a soil loosening disc (13) is arranged on the branch pipelines (11) in a sliding mode, the soil loosening disc (13) slides on the branch pipelines (11) and is used for loosening soil, and a driving assembly (14) for enabling the soil loosening disc (13) to slide is arranged on the branch pipelines (11);

the soil loosening disc (13) comprises a disc ring (2), the disc ring (2) is sleeved and slides on the branch pipeline (11), the driving assembly (14) is used for driving the disc ring (2) to slide, a rotary disc (21) is rotatably arranged on the disc ring (2), the rotary disc (21) is sleeved outside the disc ring (2), a soil drilling surface (22) which is obliquely arranged is formed on the side wall of the rotary disc (21), and the inclined soil drilling surface (22) is used for facilitating soil drilling of the rotary disc (21);

the soil drilling surface (22) is provided with a rotary groove (23) for soil to pass through, the length direction of the rotary groove (23) is arc-shaped, and the rotary groove (23) is used for enabling the soil to drive the turntable (21) to rotate;

a limiting block (24) is arranged on the disc ring (2), and a limiting groove (25) for the limiting block (24) to insert and slide is formed in the branch pipeline (11);

a chute (3) is formed in the inner wall of the water hole (12), a water baffle (31) is arranged in the chute (3) in a sliding manner, the water baffle (31) is used for covering and sealing the opening surface of the water hole (12), a control groove (32) is formed in the limiting block (24), a control block (33) is arranged in the control groove (32) in a sliding manner, a spring (34) is arranged between the inner wall of the control groove (32) and the control block (33), the spring (34) stretches out and draws back along the sliding direction of the control block (33), the control block (33) is used for pushing the water baffle (31) to slide, a guide surface (35) is arranged at the end part of the control block (33), and the guide surface (35) is used for abutting against the end part of the water baffle (31) and guiding the control block (33) to retract into the control groove (32);

the water baffle (31) is provided with an auxiliary hole (4) in a penetrating mode, an auxiliary block (41) is arranged in the auxiliary hole (4) in a sliding mode, the length of the auxiliary block (41) is larger than the depth of the auxiliary hole (4), and the auxiliary block (41) is used for being abutted to the guide surface (35).

2. A garden greenbelt water-saving irrigation device according to claim 1, wherein: an abutting groove (42) is formed in the inner wall of the auxiliary hole (4), and an abutting block (43) which is used for being inserted into and sliding in the abutting groove (42) is arranged on the auxiliary block (41).

3. A garden greenbelt water-saving irrigation device according to claim 1, wherein: the length of the control block (33) occupied by the guide surface (35) is smaller than the width of the auxiliary block (41) plus the thickness between the inner wall of the auxiliary hole (4) and the outer side wall of the adjacent water baffle (31), and the length of the control block (33) occupied by the guide surface (35) plus the width of the auxiliary block (41) is larger than the thickness between the inner wall of the auxiliary hole (4) and the outer side wall of the adjacent water baffle (31).