High-fiber planting soil planting machine
By designing a high-fiber planting soil rebar machine that combines a rebar structure and a track frame, the problem of existing equipment being unable to automate production has been solved. This has enabled automated operations for drilling, rebar installation, and concrete injection, thereby improving production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- HUBEI NORMAL UNIV
- Filing Date
- 2026-04-30
- Publication Date
- 2026-06-05
AI Technical Summary
Existing high-fiber planting soil rebar installation machines cannot perform continuous automated processing, which affects production efficiency.
A high-strength fiber planting soil rebar installation machine was designed, including a rebar installation structure, a first track frame and a second track frame. Through the combination of drilling components, rebar installation components and support components, the drilling, rebar installation and solidification material injection are automated.
It has enabled the automated production of high-gluten fiber planting soil, improving production efficiency and processing speed.
Smart Images

Figure CN122147883A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of rebar installation machine technology, specifically a rebar installation machine using high-strength fiber planting soil. Background Technology
[0002] Rebar anchoring technology involves drilling holes at the anchoring location and then applying a high-strength chemical adhesive to create a bond between the rebar, anchor rods, and other metal components and the concrete, thus achieving the desired pre-installation effect. Rebar anchoring technology has played a significant role in renovation, expansion, reinforcement, and design changes to existing structures encountered during construction, and has broad application prospects. High-fiber reinforced soil can also facilitate the construction of structures through rebar anchoring. Currently, high-fiber reinforced soil anchoring machines cannot perform continuous automated processing, affecting production efficiency. A device is needed to integrate multiple steps to achieve rapid rebar anchoring. Summary of the Invention
[0003] To address the problems in the existing technology, the present invention provides a high-strength fiber planting soil rebar installation machine.
[0004] The technical solution adopted by the present invention to solve its technical problem is: a high-gluten fiber planting soil rebar installation machine, including a rebar installation structure, a first track frame and a second track frame, the rebar installation structure is slidably provided on the first track frame and the second track frame, and the first track frame and the second track frame are fixed to the top surface;
[0005] The rebar anchoring structure is composed of drilling components, rebar anchoring components, and supporting components. The drilling components are used for drilling, the rebar anchoring components are used for pressing and anchoring the rebar, and the supporting components are used for injecting solidified material and bearing load.
[0006] Specifically, the drilling component includes a first electrically controlled telescopic rod, a movable frame is hinged on the first electrically controlled telescopic rod, the movable frame is fixed to the motor, a sleeve is fixedly provided at the lower end of the motor, a drilling rod is fixedly connected at the lower end of the sleeve, a support connecting rod is inserted into the side end of the movable frame, and a limiting sleeve is fixedly provided at the top of the support connecting rod.
[0007] Specifically, the rebar installation component includes a support base tray, a motor is fixedly installed on the top of the support base tray, the motor controls the internal shaft to rotate, so that the rebar installation mechanism can collect the rebar. The other end of the rebar installation mechanism is connected to the protective sleeve, a rotating rod sleeve is rotatably connected to the protective sleeve, a fixed support rod is fixedly connected to the lower end of the protective sleeve, a protective seat is provided on the upper side of one side of the rebar installation mechanism, and a second electrically controlled telescopic rod is installed on the protective seat.
[0008] Specifically, a connecting plate is fixedly connected to the lower end of the protective base, a third electrically controlled telescopic rod is installed on the lower end of one side of the connecting plate, and a telescopic guide rod is fixedly provided on the side of the connecting plate. The telescopic guide rod is telescopically connected on the nested arc frame.
[0009] Specifically, the rebar installation mechanism includes a sleeve, with a connecting strip fixedly provided on the side end of the sleeve. Several rebars are provided on the connecting strip, and the rebars and the connecting strip are separated by pressing.
[0010] Specifically, the supporting component includes a supporting chassis, a mounting bracket fixedly mounted at the front end of the supporting chassis, a stepper motor fixedly mounted at the lower end of the supporting chassis, a moving wheel driven by the stepper motor, a connecting side block at the rear end of the stepper motor, the connecting side block being fixed to the supporting chassis with screws, an adapter block fixedly connected to the connecting side block, a material storage base on the supporting chassis, a pump mounted on the material storage base, the side end of the pump communicating with a material injection base, the lower end of the material injection base being connected through the supporting chassis, and drilling work being performed through the setting of the drilling component, the first electrically controlled telescopic rod driving the movable frame to move by extending and retracting, so that... The movable frame slides on the supporting connecting rod, changing the position of the drilling rod, sleeve, and motor. At the same time, the motor controls the rotation of the drilling rod and sleeve to perform drilling. Through the setting of the rebar installation component, the rebar installation work is carried out. The rebar installation mechanism guides the rebar to the lower end of the second electrically controlled telescopic rod through transmission. At this time, the third electrically controlled telescopic rod controls the connecting plate to descend, so that the connecting plate can be adjusted by telescopic guide rod on the nested arc frame. When it reaches the bottom, the second electrically controlled telescopic rod performs a secondary compression, so that the rebar completely separates from the connecting strip and enters the hole, completing the rebar installation work and realizing automated production.
[0011] Specifically, a connecting handrail is fixedly connected to the supporting chassis, and a supporting guide rod is fixedly connected to the connecting handrail. The bottom of the supporting guide rod is also fixed to the supporting chassis.
[0012] Specifically, the connecting side block and the adapter block are slidably fitted to the first and second track frames. The stepper motor drives the moving wheel to rotate, causing the rebar structure to slide and adjust on the first and second track frames. The stepper motor operates, driving the moving wheel to rotate and changing the position of the supporting component. Simultaneously, the connecting side block and the adapter block also slide and adjust on the first and second track frames. After adjusting to the appropriate position, the drilling component begins operation. First, the first electrically controlled telescopic rod is pulled down, causing the movable frame to move on the support connecting rod, changing the position of the drilling rod, sleeve, and motor. The motor also operates, driving the drilling rod and sleeve to rotate, achieving the drilling purpose. After resetting, the stepper motor controls the moving wheel to align the injection seat with the hole. At this point, the pump... The machine operates by pumping material from the storage base onto the injection seat, which then guides it into the hole for grouting. Next, the rebar installation component operates. The motor-controlled sleeve rotates, causing the rebar and connecting belt to rewind, bringing the rebar to the lower end of the second electrically controlled telescopic rod. The rotating sleeve also rotates, causing the connecting belt to move via the connecting guide. Once at the designated position, the third electrically controlled telescopic rod operates, moving the connecting disc. The connecting disc extends and retracts via the telescopic guide. When the connecting disc contacts the nested arc frame, the adjustment is complete. The rebar is now pressed through the center hole of the support base. The second electrically controlled telescopic rod then operates, pushing the base again to detach the rebar from the connecting belt and allow it to enter the hole.
[0013] Specifically, the sleeve is fitted onto the shaft at the lower end of the motor. The motor drives the shaft to rotate, thereby causing the sleeve to rewind and changing the position of the reinforcing bar and connecting strip. The side end of the connecting strip is wound around the rotating rod sleeve via a connecting guide and is located at the center of the protective sleeve. The third electrically controlled telescopic rod extends and retracts, driving the connecting disc to move and adjust via the telescopic guide rod. The lower end of the second electrically controlled telescopic rod is equipped with a seat for pressing and controlling the reinforcing bar. Through the setting of the supporting component, the supporting component can move on the first track frame and the second track frame. At the same time, the storage seat is connected to the injection seat via a pump. The lower end of the injection seat is connected to the support base, allowing the slurry to be introduced, thereby achieving the purpose of solidification. The stepper motor controls the rotation of the moving wheel, thereby changing the position of the supporting component. At this time, the adapter block and the connecting side block also move in coordination on the first track frame and the second track frame to achieve reciprocating adjustment, helping to automate the processing and rebar installation.
[0014] Specifically, the first electrically controlled telescopic rod is hinged to the mounting frame, the reinforcing bar can be adjusted to reach the center hole of the support chassis, the nested arc frame is fixed to the outer ring of the hole, the third electrically controlled telescopic rod is also fixed to the support chassis, the support base plate is fixed to the support chassis, the protective sleeve is fixedly connected to the support chassis through a fixed support rod, the lower end of the support connecting rod is fixed to the support chassis, and the first electrically controlled telescopic rod, through extension and retraction, drives the movable frame, drilling rod, sleeve, and motor to slide and adjust on the support connecting rod, and the drilling rod is located in the front groove of the support chassis.
[0015] The beneficial effects of this invention are:
[0016] First, this invention utilizes a drilling component to perform drilling operations. A first electrically controlled telescopic rod extends and retracts, driving a movable frame to slide on a supporting connecting rod, changing the positions of the drilling rod, sleeve, and motor. Simultaneously, the motor controls the rotation of the drilling rod and sleeve to perform the drilling process. Second, a rebar-planting component performs rebar-planting operations. The rebar-planting mechanism guides the rebar to the lower end of a second electrically controlled telescopic rod. At this point, a third electrically controlled telescopic rod controls the connecting plate to descend, allowing the connecting plate to extend and retract on a nested arc-shaped frame via a telescopic guide rod. Upon reaching the bottom, a second extrusion by the second electrically controlled telescopic rod completely detaches the rebar from the connecting strip and into the hole, completing the rebar-planting operation and achieving automated production.
[0017] Second, through the setting of the supporting component, the supporting component can move on the first track frame and the second track frame. At the same time, the material storage seat is connected to the injection seat through the pump. The lower end of the injection seat is connected to the supporting chassis, which can introduce slurry to achieve the purpose of solidification. The stepper motor controls the rotation of the moving wheel to change the position of the supporting component. At this time, the adapter block and the connecting side block also move in coordination on the first track frame and the second track frame to achieve reciprocating adjustment, which helps to automate the processing and rebar installation. Attached Figure Description
[0018] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0019] Figure 1 This is a three-dimensional structural diagram of the main body from a frontal perspective in this invention;
[0020] Figure 2 This is a side view three-dimensional structural diagram of the main body in this invention;
[0021] Figure 3 This is a three-dimensional structural diagram of the main body from the rear view in this invention;
[0022] Figure 4 This is a three-dimensional view of the rebar anchoring structure in this invention;
[0023] Figure 5This is a perspective view of the drilling component in this invention;
[0024] Figure 6 This is a perspective view of the rebar anchoring component in this invention;
[0025] Figure 7 This is a three-dimensional rear view of the rebar anchoring component in this invention;
[0026] Figure 8 This is a perspective view of the rebar anchoring mechanism in this invention;
[0027] Figure 9 This is a perspective view of the supporting component in this invention.
[0028] In the diagram: 1-Rebar installation structure, 2-First track frame, 3-Second track frame, 4-Drilling component, 5-Rebar installation component, 6-Supporting component, 7-Limiting sleeve, 8-Movable frame, 9-First electrically controlled telescopic rod, 10-Drilling rod, 11-Sleeve, 12-Motor, 13-Supporting connecting rod, 14-Second electrically controlled telescopic rod, 15-Protective seat, 16-Motor, 17-Supporting base tray, 18-Fixed support rod, 19-Protective sleeve, 20 - Rotating rod sleeve, 21- Rebar installation mechanism, 22- Third electrically controlled telescopic rod, 23- Nested arc frame, 24- Telescopic guide rod, 25- Connecting plate, 26- Rebar, 27- Connecting belt, 28- Sleeve, 29- Connecting handrail, 30- Supporting guide rod, 31- Supporting chassis, 32- Mounting frame, 33- Stepper motor, 34- Moving wheel, 35- Connecting side block, 36- Adaptive plug, 37- Storage seat, 38- Pump, 39- Injection seat. Detailed Implementation
[0029] To enable those skilled in the art to better understand the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present application, and not all embodiments. Based on the embodiments in the present application, all other embodiments obtained by those of ordinary skill in the art without creative effort should fall within the scope of protection of the present application.
[0030] The invention will be further described below with reference to the accompanying drawings.
[0031] Example
[0032] like Figure 1-9 As shown, the present invention provides a high-strength fiber planting soil rebar installation machine, which includes a rebar installation structure 1, a first track frame 2, and a second track frame 3. The rebar installation structure 1 is slidably mounted on the first track frame 2 and the second track frame 3, and the first track frame 2 and the second track frame 3 are fixed to the top surface.
[0033] The rebar anchoring structure 1 is assembled by drilling component 4, rebar anchoring component 5, and supporting component 6. Drilling component 4 is used for drilling, rebar anchoring component 5 is used for pressing and anchoring, and supporting component 6 is used for injecting solidified material and bearing load.
[0034] The drilling component 4 includes a first electrically controlled telescopic rod 9, a movable frame 8 is hinged on the first electrically controlled telescopic rod 9, the movable frame 8 is fixed to the motor 12, a sleeve 11 is fixedly provided at the lower end of the motor 12, a drilling rod 10 is fixedly connected at the lower end of the sleeve 11, a support connecting rod 13 is inserted into the side end of the movable frame 8, and a limiting sleeve 7 is fixedly provided at the top of the support connecting rod 13.
[0035] The rebar anchoring component 5 includes a supporting base tray 17. A motor 16 is fixedly mounted on the top of the supporting base tray 17. The motor 16 controls the rotation of an internal shaft, causing the rebar anchoring mechanism 21 to collect the rebar. The other end of the rebar anchoring mechanism 21 is connected to a protective sleeve 19. A rotating rod sleeve 20 is rotatably connected to the protective sleeve 19. A fixed support rod 18 is fixedly connected to the lower end of the protective sleeve 19. A protective seat 15 is provided on the upper side of one side of the rebar anchoring mechanism 21. A second electrically controlled telescopic rod 14 is installed on the protective seat 15. A stepper motor 33 operates to drive the rebar anchoring mechanism 21. The rotating wheel 34 changes the position of the supporting component 6. Simultaneously, the connecting side block 35 and the adapter block 36 slide and adjust on the first track frame 2 and the second track frame 3. After adjusting to the appropriate position, the drilling component 4 begins operation. First, the first electrically controlled telescopic rod 9 is pulled down, causing the movable frame 8 to move on the supporting connecting rod 13, changing the positions of the drilling rod 10, the sleeve 11, and the motor 12. The motor 12 then operates, driving the drilling rod 10 and the sleeve 11 to rotate, achieving the drilling purpose. Afterwards, it resets. Then, stepper motor 33 controls the movement of moving wheel 34, aligning the injection seat 39 with the hole. At this time, pump 38 operates, pumping the material in storage seat 37 into injection seat 39, and then into the hole through injection seat 39 to achieve grouting. Afterwards, rebar assembly 5 operates. At this time, motor 16 controls sleeve 28 to rotate, driving rebar 26 and connecting belt 27 to rewind, so that rebar 26 reaches the lower position of the second electrically controlled telescopic rod 14. At this time, rotating rod sleeve 20 also rotates, so that the connecting... The belt 27 moves in coordination with the connecting guide belt. After reaching the designated position, the third electrically controlled telescopic rod 22 works first, driving the connecting plate 25 to move. The connecting plate 25 is then adjusted by telescopic guide rod 24. When the connecting plate 25 contacts the nested arc frame 23, the adjustment is completed. At this time, the steel bar 26 has been pressed and penetrates the central hole of the supporting base 31. Then, the second electrically controlled telescopic rod 14 works, causing the base to push again, so that the steel bar 26 is disengaged from the connecting belt 27 and enters the hole.
[0036] A connecting plate 25 is fixedly connected to the lower end of the protective base 15. A third electrically controlled telescopic rod 22 is installed on the lower side of one side of the connecting plate 25. A telescopic guide rod 24 is fixedly provided on the side of the connecting plate 25. The telescopic guide rod 24 is telescopically connected to the nested arc frame 23.
[0037] The rebar anchoring mechanism 21 includes a sleeve 28, with a connecting strip 27 fixedly attached to the side end of the sleeve 28. Several reinforcing bars 26 are mounted on the connecting strip 27, and the reinforcing bars 26 and the connecting strip 27 are separated by pressing. Drilling is performed using the drilling component 4. The first electrically controlled telescopic rod 9 extends and retracts, driving the movable frame 8 to move, causing the movable frame 8 to slide on the supporting connecting rod 13, changing the positions of the drilling rod 10, the sleeve 11, and the motor 12. Simultaneously, the motor 12 controls the rotation of the drilling rod 10 and the sleeve 11 to perform the drilling. In the process of rebar installation, the rebar installation component 5 is used to install the rebar. The rebar installation mechanism 21 transmits the rebar 26 to the lower end of the second electrically controlled telescopic rod 14. At this time, the third electrically controlled telescopic rod 22 controls the connecting plate 25 to descend, so that the connecting plate 25 can be adjusted on the nested arc frame 23 by telescopic guide rod 24. When it reaches the bottom, it is squeezed a second time by the second electrically controlled telescopic rod 14, so that the rebar 26 completely separates from the connecting strip 27 and enters the hole, completing the rebar installation work and realizing automated production.
[0038] The supporting component 6 includes a supporting chassis 31. A mounting bracket 32 is fixedly mounted on the front end of the supporting chassis 31. A stepper motor 33 is fixedly mounted on the lower end of the supporting chassis 31. A moving wheel 34 is driven and connected to the stepper motor 33. A connecting side block 35 is provided at the rear end of the stepper motor 33. The connecting side block 35 is fixed to the supporting chassis 31 by screws. An adapter plug 36 is fixedly connected to the connecting side block 35. A material storage seat 37 is provided on the supporting chassis 31. A pump 38 is mounted on the material storage seat 37. The side end of the pump 38 is connected to the injection seat 39. The lower end of the injection seat 39 is connected to the supporting chassis 31. The support component 6 is designed to move on the first track frame 2 and the second track frame 3. At the same time, the storage seat 37 is connected to the injection seat 39 through the pump 38. The lower end of the injection seat 39 is connected to the support base 31, which can introduce slurry to achieve solidification. The stepper motor 33 controls the moving wheel 34 to rotate, thereby changing the position of the support component 6. At this time, the adapter block 36 and the connecting side block 35 also move in coordination on the first track frame 2 and the second track frame 3 to achieve reciprocating adjustment, which helps to automate the rebar installation process.
[0039] A connecting handrail 29 is also fixedly connected to the supporting chassis 31, and a supporting guide rod 30 is fixedly connected to the connecting handrail 29. The bottom of the supporting guide rod 30 is also fixed to the supporting chassis 31.
[0040] The connecting side block 35 and the adapter plug 36 are adapted to slide and set with the first track frame 2 and the second track frame 3. The stepper motor 33 drives the moving wheel 34 to rotate, thereby driving the rebar structure 1 to slide and adjust on the first track frame 2 and the second track frame 3.
[0041] The sleeve 28 is sleeved on the shaft at the lower end of the motor 16. The motor 16 drives the shaft to rotate, thereby driving the sleeve 28 to rewind and change the position of the steel bar 26 and the connecting strip 27. The side end of the connecting strip 27 is wound and sleeved on the rotating rod sleeve 20 through the connecting guide belt and is located at the center of the protective sleeve seat 19. The third electrically controlled telescopic rod 22 drives the connecting plate 25 to move and adjust through the telescopic guide rod 24 by telescopic extension and retraction. The lower end of the second electrically controlled telescopic rod 14 is provided with a seat to control the pressing of the steel bar 26.
[0042] The first electrically controlled telescopic rod 9 is hinged to the mounting frame 32. The reinforcing bar 26 can be adjusted to reach the center hole of the support base 31. The nested arc frame 23 is fixed to the outer ring of the hole. The third electrically controlled telescopic rod 22 is also fixed to the support base 31. The support base tray 17 is fixed to the support base 31. The protective sleeve 19 is fixedly connected to the support base 31 through the fixed support rod 18. The lower end of the support connecting rod 13 is fixed to the support base 31. The first electrically controlled telescopic rod 9, through extension and retraction, drives the movable frame 8, the drilling rod 10, the sleeve 11, and the motor 12 to slide and adjust on the support connecting rod 13. The drilling rod 10 is located in the front groove of the support base 31.
[0043] The working principle is as follows: In use, the stepper motor 33 first operates, driving the moving wheel 34 to rotate, changing the position of the supporting component 6. Simultaneously, the connecting side block 35 and the adapter block 36 slide and adjust on the first track frame 2 and the second track frame 3. After adjusting to the appropriate position, the drilling component 4 operates. First, the first electrically controlled telescopic rod 9 is pulled down, driving the movable frame 8 to move on the supporting connecting rod 13, changing the position of the drilling rod 10, the sleeve 11, and the motor 12. At this time, the motor 12 also operates, driving the drilling rod 10 and the sleeve 11 to rotate, achieving the drilling purpose. After resetting, the stepper motor 33 controls the moving wheel 34 to move, aligning the injection seat 39 with the hole. At this time, the pump 38 operates, pumping the material in the storage seat 37 into the injection seat 39, and then into the hole. Inside the body, grouting is performed, and then the rebar installation component 5 operates. At this time, the motor 16 controls the sleeve 28 to rotate, driving the rebar 26 and connecting belt 27 to rewind, so that the rebar 26 reaches the lower end of the second electrically controlled telescopic rod 14. At this time, the rotating rod sleeve 20 also rotates, so that the connecting belt 27 moves in coordination with the connecting guide belt. After reaching the designated position, the third electrically controlled telescopic rod 22 operates first, driving the connecting plate 25 to move, so that the connecting plate 25 is adjusted by telescopic guide rod 24. When the connecting plate 25 contacts the nested arc frame 23, the adjustment is completed. At this time, the rebar 26 has been pressed and penetrates the central hole of the supporting base 31. Then the second electrically controlled telescopic rod 14 operates, so that the base is pushed again, so that the rebar 26 is disengaged from the connecting belt 27 and enters the hole, completing the rebar installation work.
[0044] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A high-gluten fiber planting soil rebar installation machine, characterized in that: It includes a rebar structure (1), a first track frame (2) and a second track frame (3). The rebar structure (1) is slidably mounted on the first track frame (2) and the second track frame (3). The first track frame (2) and the second track frame (3) are fixed to the top surface. The rebar structure (1) is set up by combining a drilling component (4), a rebar installation component (5), and a support component (6). The drilling component (4) is used for drilling, the rebar installation component (5) is used for pressing and installing the rebar, and the support component (6) is used for injecting solidified material and bearing the load.
2. The high-gluten fiber planting soil rebar installation machine according to claim 1, characterized in that: The drilling component (4) includes a first electrically controlled telescopic rod (9), a movable frame (8) is hinged on the first electrically controlled telescopic rod (9), the movable frame (8) is fixed to the motor (12), a sleeve (11) is fixedly provided at the lower end of the motor (12), a drilling rod (10) is fixedly connected at the lower end of the sleeve (11), a support connecting rod (13) is inserted into the side end of the movable frame (8), and a limiting sleeve (7) is fixedly provided at the top of the support connecting rod (13).
3. The high-gluten fiber planting soil rebar installation machine according to claim 2, characterized in that: The rebar installation component (5) includes a support base tray (17), a motor (16) is fixedly installed on the top of the support base tray (17), the motor (16) controls the internal shaft to rotate, so that the rebar installation mechanism (21) collects the rebar. The other end of the rebar installation mechanism (21) is connected to the protective sleeve (19), a rotating rod sleeve (20) is rotatably connected to the protective sleeve (19), a fixed support rod (18) is fixedly connected to the lower end of the protective sleeve (19), a protective seat (15) is provided on the upper side of one side of the rebar installation mechanism (21), and a second electrically controlled telescopic rod (14) is installed on the protective seat (15).
4. The high-gluten fiber planting soil rebar installation machine according to claim 3, characterized in that: The lower end of the protective base (15) is fixedly connected to a connecting plate (25). A third electrically controlled telescopic rod (22) is installed on the lower end of one side of the connecting plate (25). A telescopic guide rod (24) is fixedly provided on the side of the connecting plate (25). The telescopic guide rod (24) is telescopically connected on the nested arc frame (23).
5. The high-gluten fiber planting soil rebar installation machine according to claim 4, characterized in that: The rebar installation mechanism (21) includes a sleeve (28), and a connecting strip (27) is fixedly provided on the side end of the sleeve (28). Several steel bars (26) are provided on the connecting strip (27), and the steel bars (26) and the connecting strip (27) are separated by pressing.
6. The high-gluten fiber planting soil rebar installation machine according to claim 5, characterized in that: The supporting component (6) includes a supporting chassis (31), a mounting bracket (32) is fixedly provided at the front end of the supporting chassis (31), a stepper motor (33) is fixedly installed at the lower end of the supporting chassis (31), a moving wheel (34) is driven and connected to the stepper motor (33), a connecting side block (35) is provided at the rear end of the stepper motor (33), the connecting side block (35) is fixed to the supporting chassis (31) by screws, an adapter plug (36) is fixedly connected to the connecting side block (35), a storage seat (37) is provided on the supporting chassis (31), a pump (38) is installed on the storage seat (37), the side end of the pump (38) is connected to the injection seat (39), and the lower end of the injection seat (39) is connected to the supporting chassis (31).
7. The high-gluten fiber planting soil rebar installation machine according to claim 6, characterized in that: A connecting handrail (29) is also fixedly connected to the supporting chassis (31), and a supporting guide rod (30) is fixedly connected to the connecting handrail (29). The bottom of the supporting guide rod (30) is also fixed to the supporting chassis (31).
8. The high-gluten fiber planting soil rebar installation machine according to claim 7, characterized in that: The connecting side block (35) and the adapter plug (36) are adapted to slide and set with the first track frame (2) and the second track frame (3). The stepper motor (33) drives the moving wheel (34) to rotate, thereby driving the rebar structure (1) to slide and adjust on the first track frame (2) and the second track frame (3).
9. A high-strength fiber planting soil rebar installation machine according to claim 8, characterized in that: The sleeve (28) is sleeved on the shaft at the lower end of the motor (16). The motor (16) drives the shaft to rotate, thereby driving the sleeve (28) to rewind and change the position of the steel bar (26) and the connecting strip (27). The side end of the connecting strip (27) is wound and sleeved on the rotating rod sleeve (20) through the connecting guide belt and is located at the center of the protective sleeve seat (19). The third electric telescopic rod (22) drives the connecting plate (25) to move and adjust through the telescopic guide rod (24) by telescopic extension and retraction. The lower end of the second electric telescopic rod (14) is provided with a seat to control the pressing of the steel bar (26).
10. A high-strength fiber planting soil rebar installation machine according to claim 9, characterized in that: The first electrically controlled telescopic rod (9) is hinged to the mounting frame (32). The steel bar (26) can be adjusted to reach the center hole of the support base (31). The nested arc frame (23) is fixed at the outer ring of the hole. The third electrically controlled telescopic rod (22) is also fixed to the support base (31). The support base plate (17) is fixed to the support base (31). The protective sleeve (19) is fixed to the support base (31) through the fixed support rod (18). The lower end of the support connecting rod (13) is fixed to the support base (31). The first electrically controlled telescopic rod (9) extends and retracts, driving the movable frame (8), drilling rod (10), sleeve (11), and motor (12) to slide and adjust on the support connecting rod (13). The drilling rod (10) is located in the front groove of the support base (31).