A tree watering device

By designing a tree irrigation device that combines a ferrule and a water storage cylinder, water can be directly infiltrated into the tree roots, solving the problem of water waste caused by limited soil permeability and improving water use efficiency.

CN224386397UActive Publication Date: 2026-06-23CHONGQING YUANXIN LANDSCAPING ENGINEERING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHONGQING YUANXIN LANDSCAPING ENGINEERING CO LTD
Filing Date
2025-07-11
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In existing technologies, when sanitation vehicles use water pipes for irrigation, the limited permeability of the soil causes water to overflow and be wasted because it cannot penetrate the ground in time.

Method used

A tree irrigation device was designed, including a clamp, a water storage cylinder, an adjustment component, and an insertion and infiltration component. The clamp is installed on the tree trunk, and the water storage cylinder and the insertion and infiltration component are combined to allow water to seep directly into the soil at the tree roots. The adjustment component is used to regulate the water volume to adapt to changes in soil permeability.

Benefits of technology

It effectively avoids water waste, ensures that water seeps directly into the tree roots, reduces surface runoff, adjusts the components to adapt to changes in soil permeability, and improves water use efficiency.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224386397U_ABST
    Figure CN224386397U_ABST
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Abstract

The utility model belongs to the technical field of pouring pipe device, concretely relates to a tree irrigation device, include: the sleeve, the water storage cylinder is set up at one side of the sleeve through the sleeve, is provided with the drain pipe at the bottom of water storage cylinder, and the water delivery hose is set up in the drain pipe bottom mouth portion, the adjusting component is set up in the drain pipe top mouth portion, the insertion infiltration component is set up in the water delivery hose bottom mouth portion, is used for solving the problem that the water pipe of the sanitation car is used to water the trees around, because the soil permeability is limited, when the water pipe of the sanitation car is used to water, most of the water will flow out and cause waste because of not in time to penetrate the underground.
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Description

TECHNICAL FIELD

[0001] The utility model belongs to the technical field of pouring pipe device, concretely relates to a tree irrigation device. BACKGROUND

[0002] Sidewalk trees are an important part of urban greening, and have multiple functions such as ecology, landscape, and function. Their main functions include adjusting microclimate, absorbing pollutants (dust, exhaust gas), reducing noise, maintaining biodiversity (providing habitat for birds and insects), dividing road space, guiding traffic sight, relieving driving fatigue, and improving driving safety. Therefore, some trees are often planted on both sides of newly repaired roads.

[0003] Currently, for the early irrigation management of newly planted trees on both sides of the road, a sanitation truck water pipe is usually used to water the trees around the trees. However, due to the limited soil permeability, a large part of the water will flow out and be wasted when using the sanitation truck water pipe to water. INVENTION CONTENTS

[0004] Based on the problems mentioned in the above background technology, the utility model provides a tree irrigation device to solve the problem of waste caused by the limited soil permeability when using the sanitation truck water pipe to water the trees around the trees.

[0005] The technical scheme adopted by the utility model is as follows:

[0006] A tree irrigation device comprises:

[0007] A sleeve is provided on one side of the sleeve.

[0008] A water storage cylinder is provided on one side of the sleeve by a sleeve pocket, and the bottom of the water storage cylinder is provided with a drain pipe.

[0009] An adjusting member is provided on the top opening of the drain pipe.

[0010] An insertion and permeation member is provided on the bottom opening of the water delivery hose.

[0011] Based on the above technical scheme, the utility model has the following improvements:

[0012] Further, the adjusting member comprises an adjusting pipe, the adjusting pipe is fixedly arranged on the top opening of the drain pipe, and the top of the adjusting pipe extends to the top opening of the water storage cylinder, a plurality of liquid inlet holes are arranged on the adjusting pipe from top to bottom, and the diameters of the liquid inlet holes gradually decrease from top to bottom.

[0013] Furthermore, the insertion permeation component includes a tube, which is disposed at the bottom opening of the water delivery hose. Multiple perforations are arrayed on the peripheral wall of the tube below the constriction section, and the bottom of each perforation penetrates the bottom of the tube.

[0014] Furthermore, the sleeve includes a clamp and a buckle plate. The clamp has an opening, and slots are provided on both sides of the opening. Buckles are provided on both sides of the buckle plate. The buckles on both sides of the buckle plate are respectively engaged in the slots on the corresponding side walls of the opening. Screw holes with corresponding positions are provided on both sides of the slots and the buckles. Connecting screws are screwed into the screw holes.

[0015] Both the sleeve and the buckle plate have studs screwed in radially. Each stud has a clamping plate rotatably mounted on its screw-in end. Each clamping plate is located inside the sleeve and the buckle plate. Each clamping plate has a stabilizing rod on its outer side wall. Each stabilizing rod slides through the sleeve and the buckle plate.

[0016] Furthermore, the top opening of the water storage cylinder is provided with a cap that can be flipped open, and the cap is provided with a vent hole.

[0017] The beneficial effects of this utility model are:

[0018] 1. By combining the set hoop, sleeve, water storage cylinder, water delivery hose and insertion permeation component, the water storage cylinder is assembled on one side of the hoop using the sleeve, and then the device is installed on the tree trunk using the hoop. By inserting the insertion permeation component into the soil at the root of the tree, and then pouring water into the water storage cylinder, the water enters the insertion permeation component from the water delivery hose, and then seeps directly into the soil at the root of the tree from the insertion permeation component, thereby avoiding water outflow and waste caused by direct irrigation with water pipes.

[0019] 2. By setting up adjustment components, as water is continuously poured into the soil around the tree roots, the soil will gradually become saturated with water, causing the soil permeability to gradually deteriorate. Therefore, adjustment components are set up to regulate the amount of water entering the insertion permeability components later, so that the amount of water entering the insertion permeability components later can be matched with the soil permeability as much as possible, and to prevent the water entering the soil from seeping out of the soil surface due to the deterioration of soil permeability later. Attached Figure Description

[0020] This utility model can be further illustrated by the non-limiting embodiments given in the accompanying drawings;

[0021] Fig. 1 This is a structural diagram of a tree irrigation device according to the present invention;

[0022] Fig. 2 This is a cross-sectional view of the water storage cylinder in a tree irrigation device according to this utility model.

[0023] The attached diagram is labeled as follows:

[0024] 101. Hoop; 102. Opening; 103. Buckle plate; 104. Slot; 105. Locking block; 106. Screw hole; 107. Connecting screw; 108. Stud; 109. Stabilizer bar; 110. Clamp plate; 111. Sleeve; 201. Water storage cylinder; 202. Cylinder cover; 203. Drain pipe; 204. Water delivery hose; 205. Vent hole; 301. Adjusting pipe; 302. Liquid inlet hole; 401. Insertion tube; 402. Opening. Detailed Implementation

[0025] like Figs. 1-2 As shown, a tree irrigation device includes:

[0026] The clip includes a collar 101 and a buckle plate 103. The collar 101 has an opening 102, which facilitates the collar 101 being fitted onto the tree trunk. Each side wall of the opening 102 has a slot 104, and each side end of the buckle plate 103 has a locking block 105. When the collar 101 is fitted onto the tree trunk through the opening 102, the locking blocks 105 on both sides of the buckle plate 103 engage with the corresponding slots 104 on the side walls of the opening 102, thus securing the buckle plate 103. The buckle plate 103 is initially fastened into the opening 102 to close the opening 102. The two side walls of the slot 104 and the buckle block 105 are provided with corresponding screw holes 106. The connecting screws 107 are screwed into the screw holes 106. After the buckle plate 103 is initially fastened into the opening 102, the connecting screws 107 are simultaneously screwed into the screw holes 106 on the two side walls of the slot 104 and the buckle block 105, thereby making the buckle plate 103 securely installed in the opening 102 and preventing the buckle plate 103 from slipping out of the opening 102.

[0027] Both the sleeve 101 and the buckle plate 103 have studs 108 screwed into them radially. Each stud 108 has a clamping plate 110 rotatably mounted on its screw-in end. Each clamping plate 110 is located inside the sleeve 101 and the buckle plate 103. Each clamping plate 110 has a stabilizing rod 109 mounted on its outer side wall. Each stabilizing rod 109 slides through the sleeve 101 and the buckle plate 103. The stabilizing rod 109 can limit the rotation of the clamping plate 110, preventing the clamping plate 110 from rotating when the stud 108 is rotated. The stud 108 can rotate independently relative to the clamping plate 110, that is, the clamping plate 110 will not rotate when the stud 108 rotates.

[0028] After the clamp 101 is put on the tree trunk and the buckle 103 is stably assembled in the opening 102, the corresponding clamp 110 is moved by rotating each stud 108 at the same time, causing each clamp 110 to move and clamp onto the tree trunk, thereby realizing the installation of this device on the tree trunk.

[0029] A water storage cylinder 201 is mounted on one side of a retainer via a sleeve 111. A drain pipe 203 is located at the bottom of the water storage cylinder 201, and a water delivery hose 204 is fitted onto the bottom opening of the drain pipe 203. An insertion permeation component is installed at the bottom opening of the water delivery hose 204. The insertion permeation component includes an insertion tube 401, which is located at the bottom opening of the water delivery hose 204. Multiple perforations 402 are arrayed on the peripheral wall of the insertion tube 401 below its contraction section, with the bottom of each perforation 402 penetrating the bottom of the insertion tube 401. When this... After the device is installed on the tree trunk, the insertion tube 401 is inserted into the soil around the tree roots and the opening 402 is completely buried in the soil. When irrigating the tree, irrigation water can be periodically filled into the water storage tank 201. The irrigation water in the water storage tank 201 can be discharged into the water delivery hose 204 through the drain pipe 203 and then enter the insertion tube 401. The irrigation water in the insertion tube 401 can directly seep into the soil around the tree roots through each opening 402, thereby avoiding water waste caused by directly irrigating the soil surface with water pipes.

[0030] As water is continuously poured into the soil around the tree roots, the soil gradually becomes saturated, which leads to a gradual decrease in soil permeability and a slower rate at which the soil absorbs irrigation water. Therefore, the following regulating components are installed to adjust the amount of water entering the soil later.

[0031] An adjusting component is provided at the top opening of the drain pipe 203. The adjusting component includes an adjusting pipe 301, which is fixedly provided at the top opening of the drain pipe 203. The top of the adjusting pipe 301 extends to the top opening of the water storage cylinder 201. Multiple liquid inlet holes 302 are arranged in an array from top to bottom on the adjusting pipe 301, and the diameter of each liquid inlet hole 302 gradually decreases from top to bottom.

[0032] When the water storage tank 201 is filled with irrigation water, all the inlet holes 302 are submerged in water, meaning that irrigation water can enter the regulating pipe 301 through all the inlet holes 302. This allows a large flow of irrigation water to enter the insertion pipe 401 and seep into the soil through the openings 402. As the water level in the water storage tank 201 gradually decreases, some of the inlet holes 302 will be exposed above the water surface. At the same time, since the diameter of each inlet hole 302 gradually decreases from top to bottom, the amount of irrigation water entering the regulating pipe 301 in the later stages will gradually decrease as the irrigation time extends. This ensures that the amount of water entering the insertion pipe 401 in the later stages can be matched as closely as possible to the soil's infiltration and absorption rate, preventing the water from seeping out of the soil surface due to decreased soil permeability in the later stages.

[0033] The top opening of the water storage cylinder 201 is provided with a flip-out cap 202, and the cap 202 is provided with a vent hole 205. The cap 202 can seal the top opening of the water storage cylinder 201 to prevent water from evaporating and escaping from the water storage cylinder 201. The vent hole 205 allows air to pass through the inside and outside of the water storage cylinder 201 to balance and regulate the atmospheric pressure inside and outside the water storage cylinder 201, and to prevent the inside of the water storage cylinder 201 from being under negative pressure during the process of draining irrigation water.

[0034] The present invention has been described in detail above. The specific embodiments are provided only to help understand the method and core idea of ​​the present invention. It should be noted that those skilled in the art can make various improvements and modifications to the present invention without departing from its principles, and these improvements and modifications also fall within the protection scope of the claims of the present invention.

Claims

1. A tree irrigation device, characterized in that: include: Card sleeve; A water storage cylinder (201) is provided on one side of the sleeve through a sleeve (111). A drain pipe (203) is provided at the bottom of the water storage cylinder (201), and a water delivery hose (204) is sleeved at the bottom opening of the drain pipe (203). An adjusting component is provided at the top opening of the drain pipe (203); An insertion permeation component is provided at the bottom opening of the water delivery hose (204).

2. The tree irrigation device according to claim 1, characterized in that: The regulating component includes a regulating pipe (301), which is fixedly installed at the top of the drain pipe (203) and extends to the top of the water storage cylinder (201). Multiple liquid inlet holes (302) are arranged in an array from top to bottom on the regulating pipe (301), and the diameter of each liquid inlet hole (302) gradually decreases from top to bottom.

3. The tree irrigation device according to claim 1, characterized in that: The insertion permeation component includes a tube (401), which is located at the bottom of the water delivery hose (204). Multiple punctures (402) are arranged in an array on the peripheral wall below the constriction of the tube (401), and the bottom of each puncture (402) penetrates the bottom of the tube (401).

4. A tree irrigation device according to claim 1, characterized in that: The sleeve includes a sleeve (101) and a buckle plate (103). The sleeve (101) has an opening (102). The two side walls of the opening (102) are provided with slots (104). The two sides of the buckle plate (103) are provided with blocks (105). The blocks (105) on the two sides of the buckle plate (103) are respectively locked in the slots (104) on the corresponding side walls of the opening (102). The two side walls of the slots (104) and the blocks (105) are provided with corresponding screw holes (106). A connecting screw (107) is screwed into the screw hole (106). Both the sleeve (101) and the buckle plate (103) have studs (108) screwed into them in the radial direction. Each stud (108) has a clamping plate (110) rotatably installed at its screw-in end. Each clamping plate (110) is located inside the sleeve (101) and the buckle plate (103). Each clamping plate (110) has a stabilizing rod (109) installed on its outer side wall. Each stabilizing rod (109) slides through the sleeve (101) and the buckle plate (103).

5. A tree irrigation device according to claim 1, characterized in that: The top opening of the water storage cylinder (201) is provided with a rotatable cylinder cover (202), and the cylinder cover (202) is provided with a vent hole (205).