Soil remediation device for ecological environment protection

By combining the shaking component with the heating component, uniform heating of the soil and rapid decomposition of pollutants are achieved, solving the problems of uneven heating and insufficient decomposition in existing technologies, and improving the efficiency and safety of soil remediation.

CN224406046UActive Publication Date: 2026-06-26NANTONG TIELIN INTELLIGENT TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NANTONG TIELIN INTELLIGENT TECHNOLOGY CO LTD
Filing Date
2025-07-24
Publication Date
2026-06-26

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    Figure CN224406046U_ABST
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Abstract

The utility model discloses an ecological environment protection is with soil remediation device belongs to soil remediation field, including shaking component, the top of shaking component is provided with soil placing box, the rear end fixedly connected with electric push rod of shaking component, the transmission end fixedly connected with the connecting top plate of soil placing box top of electric push rod, the bottom fixedly connected with a plurality of equidistance's and with soil placing box adaptation's heating component of connecting top plate, its technical scheme main point is, through shaking component and heating component combination, motor drive axle rod drives half gear and rack cooperation, makes soil placing box realize left and right shaking, at the same time, electric push rod control heating component accurate insertion soil, the heat of electric heating wire is conducted to the wedge through heat -conducting copper pipe fast to the soil even heating, in the process of soil shaking, not only can promote heat more fully infiltrate to the soil inside, can also make soil and heating component full contact, speed up the decomposition or volatilization of pollutant.
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Description

Technical Field

[0001] This utility model relates to the field of soil remediation, and in particular to a soil remediation device for ecological environmental protection. Background Technology

[0002] Soil remediation in ecological and environmental protection refers to the process of restoring or bringing soil, which has been degraded or polluted due to various factors, to its original ecological functions and environmental quality through a series of technical means.

[0003] Chinese patent application number CN202321705454.X discloses a soil remediation device for ecological environmental protection. This solution heats the surrounding soil to the boiling point temperature of pollutants using a heat pipe. However, during the heating process, both the soil and the heat pipe are stationary. The heat pipe can only heat the soil at the current location, while the soil in more distant areas may not be heated sufficiently. This can easily lead to localized overheating and insufficient heating of the soil, which is not conducive to the rapid decomposition or volatilization of pollutants.

[0004] Therefore, we propose a soil remediation device for ecological and environmental protection. Utility Model Content

[0005] To overcome the shortcomings of existing technologies, the purpose of this utility model is to provide a soil remediation device for ecological environmental protection. By combining a shaking component with a heating component, a motor-driven shaft drives a half-gear and a rack to make the soil placement box shake left and right. At the same time, an electric push rod controls the heating component to accurately insert into the soil. The heat generated by the heating wire is quickly conducted to the wedge block through a heat-conducting copper pipe to heat the soil evenly. During the shaking process, not only can the heat be more fully penetrated into the soil, but the soil can also be in full contact with the heating component, accelerating the decomposition or volatilization of pollutants.

[0006] The above-mentioned technical objective of this utility model is achieved through the following technical solution:

[0007] A soil remediation device for ecological environmental protection includes a shaking assembly. A soil placement box is mounted at the top of the shaking assembly. An electric push rod is fixedly connected to the rear end of the shaking assembly. The transmission end of the electric push rod is fixedly connected to a connecting top plate located above the soil placement box. Multiple equidistant heating components adapted to the soil placement box are fixedly connected to the bottom end of the connecting top plate. The shaking assembly includes a fixed box. Two symmetrically arranged guide blocks are fixedly connected to the top of the fixed box. A rack is slidably connected inside the guide blocks. A limit block is fixedly connected inside the fixed box. Two symmetrically arranged shafts are rotatably connected to the upper end of the limit block. Half gears are fixedly connected to both the front and rear ends of each shaft, with the half gears on the two shafts arranged in opposite directions.

[0008] Furthermore, a full gear is fixedly connected to the middle of the shaft and to the rear side of the half gear, and the two full gears are meshed together.

[0009] Furthermore, a worm gear is fixedly connected to the middle of one of the shafts and located behind the full gear.

[0010] Furthermore, a motor is fixedly connected inside the fixed box, and a worm gear meshing with a worm wheel is fixedly connected to the transmission end of the motor.

[0011] Furthermore, the heating assembly includes a housing, and a connecting block that is fixedly connected to a connecting top plate is fixedly connected to the top of the housing.

[0012] Furthermore, a plug is fixedly connected to the bottom end of the outer casing.

[0013] Furthermore, wedge-shaped blocks are fixedly connected to both the left and right ends of the outer shell.

[0014] Furthermore, an electric heating wire is fixedly connected inside the outer shell, and multiple equidistant heat-conducting copper tubes located inside the wedge-shaped block are fixedly connected to the outer wall of the electric heating wire.

[0015] In summary, this utility model has the following beneficial effects:

[0016] 1. By combining the shaking component with the heating component, the motor-driven shaft drives the half gear and rack to make the soil placement box shake left and right; at the same time, the electric push rod controls the heating component to accurately insert into the soil, and the heat generated by the heating wire is quickly conducted to the wedge block through the heat-conducting copper pipe to heat the soil evenly. During the shaking process, not only can the heat be more fully penetrated into the soil, but the soil can also be in full contact with the heating component, which accelerates the decomposition or volatilization of pollutants.

[0017] 2. The meshing transmission of the full gear in the shaking component ensures the synchronous rotation of the two shafts, maintains the coordination of the half gear movements, achieves the reciprocating motion of the rack, and ensures the stability of the device operation. The worm gear transmission has a self-locking characteristic, which can prevent the shaking component from reversing due to external forces when the motor stops running, thus enhancing the safety of the device. The wedge-shaped block design of the heating component is not only easy to insert into the soil, but also breaks up soil clumps during shaking, optimizing the contact between the soil and the heating component. The configuration of the plug and heat-conducting copper pipe achieves precise heat conduction and uniform distribution, improving the heating effect. The outer shell protects the internal components, extending the service life of the device, thus balancing practicality and durability. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the structure of the heating component entering the soil placement box in this embodiment;

[0019] Figure 2 This is a schematic diagram of the structure in this embodiment where the heating component is placed away from the soil;

[0020] Figure 3 This is a schematic diagram of the structure where the shaking component and the soil placement box are separated in this embodiment;

[0021] Figure 4 This is a schematic diagram of the disassembled shaking component in this embodiment;

[0022] Figure 5 This is a schematic diagram of the half gear and the full gear in this embodiment;

[0023] Figure 6 This is a schematic diagram of the cross-sectional structure of the heating component in this embodiment.

[0024] In the diagram, 1. Shaking assembly; 2. Electric push rod; 3. Connecting top plate; 4. Heating assembly; 5. Soil placement box; 101. Fixing box; 102. Guide block; 103. Rack; 104. Limiting block; 105. Shaft; 106. Half gear; 107. Full gear; 108. Worm gear; 109. Motor; 110. Worm; 401. Housing; 402. Connecting block; 403. Heating wire; 404. Heat-conducting copper pipe; 405. Wedge block; 406. Plug. Detailed Implementation

[0025] The present invention will be further described in detail below with reference to the accompanying drawings.

[0026] Identical parts are indicated by the same reference numerals. It should be noted that the terms "front," "rear," "left," "right," "up," and "down" used in the following description refer to directions in the accompanying drawings, while the terms "bottom surface," "top surface," "inner," and "outer" refer to directions toward or away from the geometric center of a specific part, respectively.

[0027] Reference Figure 1 outrigger Figure 6 As shown, a preferred embodiment of the present invention provides a soil remediation device for ecological environmental protection, comprising a shaking component 1, a soil placement box 5 at the top of the shaking component 1, an electric push rod 2 fixedly connected to the rear end of the shaking component 1, a connecting top plate 3 located above the soil placement box 5 fixedly connected to the transmission end of the electric push rod 2, and a plurality of equidistant heating components 4 adapted to the soil placement box 5 fixedly connected to the bottom end of the connecting top plate 3; the shaking component 1 includes a fixed box 101, two symmetrically arranged guide blocks 102 fixedly connected to the top of the fixed box 101, a rack 103 slidably connected inside the guide blocks 102, a limiting block 104 fixedly connected inside the fixed box 101, two symmetrically arranged shafts 105 rotatably connected to the upper end of the limiting block 104, and half gears 106 fixedly connected to both the front and rear ends of the shafts 105, with the half gears 106 on the two shafts 105 arranged in opposite directions;

[0028] The electric push rod 2 drives the connecting top plate 3 to move up and down, thereby controlling the heating component 4 to move closer to or further away from the soil, realizing the start and stop of the heating operation. The heating component 4 is adapted to the soil placement box 5 to ensure that the heating range covers the soil. The shaking component 1 works in conjunction with the heating component 4 to heat the soil while shaking it, enhancing the soil remediation effect and promoting the decomposition or volatilization of pollutants. The sliding connection between the guide block 102 and the rack 103 in the shaking component 1 restricts the movement trajectory of the rack 103, ensuring that it moves smoothly in the horizontal direction, which facilitates the left and right offset shaking of the soil placement box 5. The half gears 106 are arranged in opposite directions. When the shaft 105 rotates, the half gears 106 on the two shafts 105 alternately mesh with the rack 103, pushing the rack 103 to move back and forth, thereby driving the soil placement box 5 to shake, realizing the uniform turning of the soil. The limiting block 104 limits the position of the shaft 105 to ensure the stability of the meshing of the half gears 106.

[0029] A full gear 107 is fixedly connected to the middle of the shaft 105 and to the rear side of the half gear 106, and the two full gears 107 are meshed.

[0030] The meshing transmission of the two full gears 107 ensures that the two shafts 105 rotate synchronously, making the movement of the half gear 106 coordinated and consistent, avoiding jamming caused by uneven force on the rack 103, and effectively improving the stability of the device operation.

[0031] A worm gear 108 is fixedly connected to the middle of one of the shafts 105 and to the rear side of the full gear 107;

[0032] The worm gear 108, in conjunction with the worm 110 (mentioned later), drives the shaft 105 to rotate.

[0033] A motor 109 is fixedly connected inside the fixed box 101, and a worm 110 that meshes with a worm gear 108 is fixedly connected to the transmission end of the motor 109.

[0034] The motor 109 drives the worm gear 110 to rotate, which in turn drives the worm wheel 108 to rotate, thereby driving the shaft 105 and the half gear 106 to move, realizing the automated drive of the swaying component 1; and the worm wheel 108 and worm gear 110 transmission has self-locking property, which can prevent the swaying component 1 from reversing due to external force when the motor 109 stops running, ensuring the safe operation of the device.

[0035] The heating component 4 includes a housing 401, and a connecting block 402 that is fixedly connected to the top of the housing 401 is fixedly connected to the connecting top plate 3;

[0036] The connecting block 402 ensures that the heating component 4 is securely installed on the connecting top plate 3, guaranteeing the accuracy of the heating position and preventing it from shaking and falling off during operation.

[0037] A plug 406 is fixedly connected to the bottom of the outer casing 401;

[0038] The plug 406 is used for insertion into the soil.

[0039] Both ends of the outer casing 401 are fixedly connected with wedge blocks 405;

[0040] The sharp shape of the wedge block 405 makes it easy to insert into the soil and keep it close to the soil, which facilitates the heating of the soil; and during the shaking process, the wedge block 405 can also help break up soil clumps and enhance the repair effect.

[0041] A heating wire 403 is fixedly connected inside the outer casing 401, and multiple heat-conducting copper tubes 404 that are equidistant and located inside the wedge block 405 are fixedly connected to the outer wall of the heating wire 403.

[0042] Heat is generated when the heating wire 403 is energized, serving as the heat source for the heating component 4. The heat-conducting copper pipe 404 can quickly conduct the heat from the heating wire 403 to the wedge block 405, so that the heat is evenly distributed in the soil, avoiding local overheating or uneven heating, and ensuring the uniformity and effectiveness of soil remediation. At the same time, the outer shell 401 can protect the internal heating wire 403 and other components from damage caused by the soil or external environment.

[0043] Specific implementation process: First, the soil to be repaired is poured into the soil placement box 5. The power supply to the motor 109 and the heating component 4 is connected, and the motor 109 is started. The motor 109 drives the worm gear 110 to rotate. The worm gear 110 meshes with the worm wheel 108, driving one of the shafts 105 to rotate. Through the meshing transmission of two full gears 107, the other shaft 105 rotates synchronously. The half gears 106 on the shaft 105 alternately mesh with the rack 103, pushing the rack 103 to slide back and forth in the guide block 102, thereby causing the soil placement box 5 to shake left and right, achieving uniform soil turning. Then, the electric push rod 2 is started. The electric push rod 2 drives the connecting top plate 3 to move downward, causing the heating component to... The plug 406 of component 4 is inserted into the soil, and the wedge block 405 also penetrates into the soil. At this time, the heating wire 403 is energized and heats up. The heat is quickly conducted to the wedge block 405 through the heat-conducting copper pipe 404 and evenly distributed into the soil to heat and repair it. During the shaking of the soil placement box 5, the wedge block 405 not only assists in heating but also breaks up soil clumps, allowing the soil to make fuller contact with the heating component 4 and improving the repair effect. After the repair is completed, the power supply to the motor 109 and the heating wire 403 is turned off, and the electric push rod 2 is started to move the connecting top plate 3 upward, pulling the heating component 4 out of the soil. Finally, the repaired soil is taken out of the soil placement box 5, completing one soil repair operation.

[0044] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claims. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A soil remediation device for ecological environmental protection, characterized in that: The device includes a shaking assembly (1), a soil placement box (5) is provided at the top of the shaking assembly (1), an electric push rod (2) is fixedly connected to the rear end of the shaking assembly (1), a connecting top plate (3) located above the soil placement box (5) is fixedly connected to the transmission end of the electric push rod (2), and a plurality of equidistant heating components (4) adapted to the soil placement box (5) are fixedly connected to the bottom end of the connecting top plate (3). The shaking assembly (1) includes a fixed box (101), with two symmetrically arranged guide blocks (102) fixedly connected to the top of the fixed box (101). A rack (103) is slidably connected inside the guide block (102). A limit block (104) is fixedly connected inside the fixed box (101). Two symmetrically arranged shafts (105) are rotatably connected to the upper end of the limit block (104). Half gears (106) are fixedly connected to both the front and rear ends of the shafts (105). The half gears (106) on the two shafts (105) are arranged in opposite directions.

2. The soil remediation device for ecological environmental protection according to claim 1, characterized in that: A full gear (107) is fixedly connected to the middle of the shaft (105) and to the rear side of the half gear (106), and the two full gears (107) are meshed.

3. The soil remediation device for ecological environmental protection according to claim 2, characterized in that: A worm gear (108) is fixedly connected to the middle of one of the shafts (105) and to the rear side of the full gear (107).

4. The soil remediation device for ecological environmental protection according to claim 1, characterized in that: The fixed box (101) is internally connected to a motor (109), and the transmission end of the motor (109) is fixedly connected to a worm (110) that meshes with a worm wheel (108).

5. The soil remediation device for ecological environmental protection according to claim 1, characterized in that: The heating component (4) includes a housing (401), and a connecting block (402) that is fixedly connected to the top of the housing (401) is fixedly connected to the connecting top plate (3).

6. A soil remediation device for ecological environmental protection according to claim 5, characterized in that: A plug (406) is fixedly connected to the bottom end of the outer casing (401).

7. A soil remediation device for ecological environmental protection according to claim 6, characterized in that: Both ends of the outer shell (401) are fixedly connected with wedge blocks (405).

8. A soil remediation device for ecological environmental protection according to claim 7, characterized in that: The inner side of the outer shell (401) is fixedly connected to a heating wire (403), and the outer wall of the heating wire (403) is fixedly connected to a plurality of equidistant heat-conducting copper tubes (404) located inside the wedge block (405).