Automatic construction system for anchor rods

By designing an automated anchor bolt construction system, the drilling and anchor bolt installation processes have been automated, solving the problem of time-consuming and labor-intensive traditional anchor bolt construction, improving work efficiency and reducing labor intensity.

CN117703460BActive Publication Date: 2026-06-23CCTEG COAL MINING RES INST +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
CCTEG COAL MINING RES INST
Filing Date
2023-12-11
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Traditional anchor bolt construction requires manual operation, resulting in time-consuming and labor-intensive processes, low work efficiency, and insufficient automation.

Method used

An automated anchor bolt construction system was designed, including a drilling rig assembly and an anchor bolt chamber assembly, to automate drilling and anchor bolt installation. The system uses a sliding module and a robotic arm to automatically complete the drilling, anchoring agent injection and anchor bolt installation.

Benefits of technology

It has improved the automation level of anchor bolt construction, reduced labor intensity, increased work efficiency, and simplified construction procedures.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses an automatic construction system of an anchor rod, which comprises a drilling machine assembly and an anchor rod bin assembly. The drilling machine assembly comprises a drilling frame, a drilling box base, a sliding module, a drilling drilling box, a pre-tightening drilling box, a sliding seat group and a sliding drive. The drilling box base is fixed to the drilling frame, and the drilling box base is provided with a slot. The sliding module is matched in the slot and is slidably assembled on the drilling frame. The sliding seat group is slidably assembled on the drilling box base, and the sliding drive is arranged on the drilling box base. The sliding seat group comprises a first sliding seat and a second sliding seat. The drilling drilling box is arranged on the first sliding seat, and the pre-tightening drilling box is arranged on the second sliding seat. The anchor rod bin assembly comprises a manipulator and a plurality of conveying assemblies. The manipulator is arranged at one end of the conveying assembly. The conveying assembly comprises a blocking rod and a conveying rod. The conveying rod is provided with a spiral groove. A plurality of anchor rods are embedded in the spiral groove and are limited by the blocking rod. The construction system can realize the automation of the anchor rod support process such as drilling and anchor rod installation, reduces the labor intensity and improves the operation efficiency.
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Description

Technical Field

[0001] This invention relates to the field of anchor bolt support technology, and more specifically, to an automatic anchor bolt construction system. Background Technology

[0002] During underground mining, timely support of the excavated roadways is necessary. Rock bolt support, as a simple and effective support method, can combine the surrounding rock with stable rock mass, creating a suspension and composite beam effect, thus fully ensuring the safety of roadway construction. However, traditional rock bolt construction often requires manual labor for drilling, installing anchoring agents, and installing rock bolts, resulting in time-consuming and labor-intensive processes, low efficiency and automation, and high labor intensity. Summary of the Invention

[0003] The present invention aims to at least partially solve one of the technical problems in the related art.

[0004] Therefore, this invention proposes an automatic anchor bolt construction system, which can automate anchor bolt support processes such as drilling and anchor bolt installation, thereby reducing labor intensity and improving work efficiency.

[0005] The automatic anchor bolt installation system of this invention includes:

[0006] The drilling rig assembly includes a drill frame, a drill box base, a sliding module, a drilling drill box, a pre-tightening drill box, a sliding seat assembly, and a sliding drive.

[0007] The drill box base is fixed to the drill frame, and the drill box base has a slot in the middle. The sliding module is fitted into the slot and slides along the first direction to be assembled to the drill frame. The drilling box is fixed with a drill rod for drilling. The pre-tightening drill box is used to feed and pre-tighten the anchor rod into the drill hole. The anchor rod has at least two channels for conveying different types of anchoring agent components into the drill hole.

[0008] The sliding seat assembly has a first position and a second position. The sliding seat assembly is slidably mounted on the drill box base along a second direction orthogonal to the first direction. The sliding drive is provided on the drill box base and is used to drive the sliding seat assembly to switch back and forth between the first position and the second position.

[0009] The sliding seat assembly includes a first sliding seat and a second sliding seat. The drilling box is installed on the first sliding seat, and the pre-tightening drilling box is installed on the second sliding seat. In the first position, the second sliding seat cooperates with the sliding module and can slide synchronously with the sliding module along the first direction. In the second position, the first sliding seat cooperates with the sliding module and can slide synchronously with the sliding module along the first direction.

[0010] An anchor bolt magazine assembly, the anchor bolt magazine assembly including a robotic arm and a plurality of parallel and spaced conveying components, the robotic arm being located at one end of the conveying components;

[0011] The conveying assembly includes parallel-arranged stop bars and conveying rods. The conveying rods are provided with spiral grooves extending spirally along the axial direction of the conveying rods. A plurality of anchor rods are laterally embedded in the spiral grooves and stopped and limited by the stop bars. The plurality of anchor rods are used to sequentially convey to the robotic arm when the conveying rods rotate. The robotic arm is used to grasp the anchor rods located at the end of the conveying assembly and transport the grasped anchor rods to the pre-tightening drill box located at the first position.

[0012] The automatic anchor bolt construction system of this invention can automate anchor bolt support processes such as drilling and anchor bolt installation, reducing labor intensity and improving work efficiency.

[0013] In some embodiments, the bolt magazine assembly includes a gearbox located at the other end of the plurality of conveying components, wherein the conveying rods of the plurality of conveying components are kinetically connected to the gearbox so that the gearbox can drive the plurality of conveying rods to rotate synchronously when in operation.

[0014] In some embodiments, a plurality of the stops are fixedly connected to the gearbox, a plurality of the anchors are located between the conveying rod and the stops in each of the conveying components, and the spacing between any two adjacent anchors is consistent with the pitch of the helical groove.

[0015] In some embodiments, the robotic arm includes grippers for gripping the anchor rod being conveyed to the end of the conveying assembly, and the grippers are arranged opposite to the pre-tightening drill box located at the first position in the second direction.

[0016] In some embodiments, the robotic arm further includes:

[0017] The first sliding component has a gripper located at the drive end of the first sliding component, and the first sliding component is used to drive the gripper to finely adjust along the second direction so that the anchor rod gripped by the gripper can be arranged directly opposite the pre-tightening drill box located at the first position in the first direction.

[0018] The second sliding component is attached to the first sliding component, and the second sliding component is used to drive the first sliding component to move along the second direction to achieve the coarse adjustment of the anchor rod gripped by the gripper;

[0019] The third sliding component, the second sliding component is assembled to the third sliding component, and the third sliding component is used to drive the jaws to move in the first direction through the first sliding component and the second sliding component so that the anchor rod gripped by the jaws can cooperate with the pre-tightening drill box.

[0020] In some embodiments, the anchor bolt assembly includes a frame link, and there are multiple robotic arms, each robotic arm being disposed at the end of a plurality of conveying components, and the third sliding component of each of the plurality of robotic arms is connected to the frame link.

[0021] In some embodiments, the drilling assembly includes a clamping mechanism disposed on the drill frame and arranged opposite to the sliding module in the first direction. The clamping mechanism is adjustable and has a first form and a second form. The opening angle of the clamping mechanism in the second form is greater than the opening angle in the first form. In the first form, the clamping mechanism is used to straighten the drill rod or the anchor rod. In the second form, the clamping mechanism allows the drilling box or the pre-tightening drilling box to pass through.

[0022] In some embodiments, the clamping mechanism includes:

[0023] The base includes a mounting plate, a first protective plate, and a second protective plate. The mounting plate is used to fix the base to the top of the anchor drilling rig. The first protective plate and the second protective plate are both fixed to the top side of the mounting plate, and the first protective plate, the second protective plate, and the mounting plate form an assembly cavity.

[0024] A driver and a transmission component, wherein the driver is assembled in the assembly cavity, the transmission component is connected to the driver, and both clamps are slidably assembled with the transmission component to switch to the first or the second configuration via the slid assembly when the driver drives the transmission component to move.

[0025] In some embodiments, the transmission member is provided with a first slide groove and a second slide groove, the first slide groove and the second slide groove are arranged at intervals and both extend along the extension direction of the transmission member, the driver includes a drive rod, the transmission member is connected to the drive rod and is arranged orthogonally to the drive rod, the first clamp is provided with a first sliding pin, the second clamp is provided with a second sliding pin, the first sliding pin is slidably fitted in the first slide groove and can rotate relative to it in the first slide groove, and the second sliding pin is slidably fitted in the second slide groove and can rotate relative to it in the second slide groove.

[0026] In some embodiments, the drilling rig assembly includes a limit drive and a module drive. The limit drive is disposed on the sliding module. Both the first sliding seat and the second sliding seat are provided with limit holes. In the first position, the limit drive is limited to the limit hole on the second sliding seat. In the second position, the limit drive is limited to the limit hole on the first sliding seat.

[0027] The module driver is located on the drill frame, and the module driver is connected to the sliding module and is used to drive the sliding module to slide along the first direction. Attached Figure Description

[0028] Figure 1 This is a three-dimensional schematic diagram of the automatic anchor bolt construction system according to an embodiment of the present invention.

[0029] Figure 2 This is a three-dimensional schematic diagram of the drilling rig assembly according to an embodiment of the present invention.

[0030] Figure 3 yes Figure 2 Front view schematic diagram of the drilling rig assembly.

[0031] Figure 4 yes Figure 1 3D diagram of the middle anchor bolt assembly Figure 1 .

[0032] Figure 5 yes Figure 1 3D diagram of the middle anchor bolt assembly Figure 2 .

[0033] Figure 6 yes Figure 1 A side view of the central anchor bolt assembly.

[0034] Figure 7 This is a schematic diagram of the robotic arm of the anchor bolt magazine assembly according to an embodiment of the present invention.

[0035] Figure 8 This is a schematic diagram illustrating the cooperation between the sliding module and the second sliding seat in an embodiment of the present invention.

[0036] Figure 9 This is an assembly diagram of the drill box base, sliding module, first sliding seat, and second sliding seat according to an embodiment of the present invention.

[0037] Figure 10 This is a top view of the clamping mechanism in the first configuration according to an embodiment of the present invention.

[0038] Figure 11 This is a top view schematic diagram of the clamping mechanism in the second embodiment of the present invention.

[0039] Figure 12This is a three-dimensional schematic diagram of a portion of the clamping mechanism in the second embodiment of the present invention. Figure 1 .

[0040] Figure 13 This is a three-dimensional schematic diagram of a portion of the clamping mechanism in the second embodiment of the present invention. Figure 2 .

[0041] Figure label:

[0042] Drilling rig assembly 100;

[0043] Drill rig 11;

[0044] Drill box base 12; first plate 121; second plate 122; inclined plate 123; guide groove 124;

[0045] Sliding module 13;

[0046] Drill box 14; Drill rod 141;

[0047] Pre-tightening drill box 15;

[0048] Clamping mechanism 16; base 161; first guard plate 1611; extension 16111; second guard plate 1612; mounting plate 1613; assembly cavity 1614; clamping assembly 162; first clamp 1621; first groove 16211; first slot 16212; first sliding pin 16213; second clamp 1622; second groove 16221; second slot 16222; second sliding pin 16223; interface 1623; driver 163; drive rod 1631; transmission component 164; first slide groove 1641; second slide groove 1642; first pin 165; second pin 166;

[0049] Sliding seat assembly 17; First sliding seat 171; Second sliding seat 172; Limiting hole 173; Guide part 174;

[0050] Sliding drive 18; Pin 181;

[0051] Limit drive 19;

[0052] Anchor bolt assembly 200;

[0053] Robotic arm 21; gripper 211; first sliding component 212; second sliding component 213; third sliding component 214;

[0054] Conveying assembly 22; stop bar 221; conveying rod 222; spiral groove 2221;

[0055] Gearbox 23;

[0056] Frame connecting rod 24;

[0057] Anchor bolt 300. Detailed Implementation

[0058] Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain the present invention, and should not be construed as limiting the present invention.

[0059] like Figure 1 As shown, the automatic anchor bolt construction system (hereinafter referred to as the construction system) of this invention includes a drilling rig assembly 100 and an anchor bolt chamber assembly 200. The drilling rig assembly 100 and the anchor bolt chamber assembly 200 can be connected and fixed, and can be arranged in parallel in the left and right directions, wherein the anchor bolt chamber assembly 200 can be located on the left side of the drilling rig assembly 100.

[0060] like Figure 2 and Figure 3 As shown, the drilling rig assembly 100 may include a drill frame 11, a drill box base 12, a sliding module 13, a drilling box 14, a pre-tightening drill box 15, a clamping mechanism 16, a sliding seat assembly 17, and a sliding drive 18. The drill frame 11 is generally cubic in shape and can be assembled from sheet metal, rods, etc., and generally extends vertically. The drill box base 12 is fixed to the drill frame 11; for example, the drill box base 12 can be fixed to the bottom of the drill box base 12 and located on the front side of the drill frame 11 using bolts or other fasteners.

[0061] The drill box base 12 may have a slot in the middle, which is generally rectangular and runs through the drill box base 12 vertically, with the slot opening facing the front of the drill box base 12. Specifically, the drill box base 12 may be divided into two independent parts, which may be arranged at intervals in the left and right directions. The left drill box base 12 may be fixed to the left side of the drill frame 11, and the right drill box base 12 may be fixed to the right side of the drill frame 11. The slot may be formed between the two independent parts of the drill box base 12, thereby facilitating the formation of the slot.

[0062] The sliding module 13 is fitted into the slot and slidably mounted on the drill frame 11 along the first direction. For example, the sliding module 13 can be a block structure with two guide holes, and the drill frame 11 can have two guide posts. Both guide posts extend along the first direction (vertical direction), and the two guide posts are slidably mounted in the two guide holes, allowing the sliding module 13 to slide back and forth along the first direction. When the sliding module 13 slides to the bottom of the drill frame 11, it is inserted into the slot of the drill box base 12, so that the sliding module 13 and the drill box base 12 are roughly at the same level, facilitating the subsequent switching of the sliding seat assembly 17 between the sliding module 13 and the drill box base 12.

[0063] like Figure 2 As shown, the drilling box 14 and the pre-tightening drilling box 15 can be arranged parallel to each other in the left-right direction. The drilling box 14 is fixed with a drill rod 141 for drilling. The drill rod 141 extends in the vertical direction. When the drilling box 14 is started, the drill rod 141 can be used to drill into the coal wall. The pre-tightening drilling box 15 can be used to install anchor bolts 300. When the pre-tightening drilling box 15 is started, the anchor bolts 300 can be sent into the completed borehole. After the anchoring agent in the borehole has solidified, the pre-tightening drilling box 15 can also drive the pre-tightening nut, thereby achieving the pre-tightening and fixing of the anchor bolts 300.

[0064] The anchor bolt 300 has at least two channels for delivering different types of anchoring agent components into the borehole. For example, the anchor bolt 300 may have two channels, both extending along the axial direction of the anchor bolt 300, with the inlet of each channel located at the bottom of the anchor bolt 300 and the outlet of each channel located at the top of the anchor bolt 300.

[0065] In use, one channel allows for the introduction of anchoring agent component A, while the other channel allows for the introduction of anchoring agent component B. Components A and B then flow out from their respective channel outlets and can flow in the opposite direction towards the borehole opening, thus filling the gap between the anchor rod 300 and the borehole. It should be noted that components A and B mix and rapidly solidify in the annular space between the anchor rod 300 and the borehole, thereby achieving anchoring of the anchor rod 300.

[0066] The clamping mechanism 16 is arranged opposite to the sliding module 13 in a first direction, for example, as Figure 2 As shown, the clamping mechanism 16 can be fixed to the top of the drill frame 11. The clamping mechanism 16 can be arranged directly opposite the sliding module 13 in the vertical direction. The clamping mechanism 16 is located on the drill frame 11 and has two clamps. The angle of the two clamps can be adjusted to allow the clamping mechanism 16 to have a first form and a second form. The opening angle of the clamping mechanism 16 in the second form is greater than the opening angle in the first form. In the first form, the clamping mechanism 16 is used to straighten the drill rod 141 or the anchor rod 300. In the second form, the clamping mechanism 16 allows the drilling box 14 or the pre-tightening drilling box 15 to pass through.

[0067] Specifically, such as Figure 10 As shown, the clamping mechanism 16 may include a base 161 and a clamping assembly 162. The clamping assembly 162 has a first form and a second form and includes a first clamp 1621 and a second clamp 1622 that can be opened and closed. One end of the first clamp 1621 and the second clamp 1622 are rotatably connected to the base 161. The other end of the first clamp 1621 is provided with a first groove 16211, and the other end of the second clamp 1622 is provided with a second groove 16221.

[0068] For example, such as Figures 10 to 12 As shown, both the first clamp 1621 and the second clamp 1622 can be cast parts. Both clamps 1621 and 1622 can be arranged generally along the front-to-back direction, and can be arranged opposite each other in the left-to-right direction, with the first clamp 1621 located to the left of the second clamp 1622. The rear ends of both clamps 1621 and 1622 can be pivotally mounted to the base 161, allowing them to swing relative to each other in the left-to-right direction, thus satisfying the need to adjust the opening angle of the clamps 1621 and 1622.

[0069] The front end of the first clamp 1621 is provided with a first groove 16211, which can be located on the right side of the first clamp 1621. The front end of the second clamp 1622 is provided with a second groove 16221, which can be located on the left side of the second clamp 1622. Both the first groove 16211 and the second groove 16221 can be semi-circular grooves.

[0070] Since the first clamp 1621 and the second clamp 1622 can swing relative to each other and adjust their opening and closing angles, during the swing adjustment process, the clamp assembly 162 has a first shape, specifically as follows: Figure 10 As shown, at this time, the opening angle of the first clamp 1621 and the second clamp 1622 can be minimized, and the openings of the first groove 16211 and the second groove 16221 can be aligned and joined together to form a through hole, which is a circular hole. Therefore, the anchor rod 300 and the drill rod 141 can fit into the through hole formed by the joining of the first groove 16211 and the second groove 16221. The hole wall of the through hole can act as a limiting force, thereby correcting and assisting in the straightening of the anchor rod 300 and the drill rod 141.

[0071] When the opening angle of the first clamp 1621 and the second clamp 1622 increases, the clamp assembly 162 can switch to the second mode. At this time, as... Figure 11 and Figure 12 As shown, the opening angle formed by the first clamp 1621 and the second clamp 1622 can be maximized, thereby allowing the size of the space between the first clamp 1621 and the second clamp 1622 to be larger, which meets the usage requirements for the drilling box 14 and the pre-tightening drilling box 15 to pass through. In addition, it also meets the usage requirements for the passage of large-sized components such as the tray on the anchor rod 300.

[0072] like Figure 9As shown, the sliding seat assembly 17 has a first position and a second position and includes a first sliding seat 171 and a second sliding seat 172. Both the first sliding seat 171 and the second sliding seat 172 can be generally square plate-shaped structures. The first sliding seat 171 and the second sliding seat 172 are slidably assembled on the drill box base 12 along a second direction (left-right direction) orthogonal to the first direction. The sliding drive 18 is provided on the drill box base 12. The sliding drive 18 can be a telescopic hydraulic cylinder, specifically a single rod extension hydraulic cylinder.

[0073] In use, the sliding drive 18 can be connected to the first sliding seat 171 and the second sliding seat 172. Then, by extending and retracting the sliding drive 18, the first sliding seat 171 and the second sliding seat 172 can be synchronously switched between the first position and the second position. Figure 9 The first sliding seat 171 and the second sliding seat 172 are in the first position.

[0074] like Figure 3 As shown, the drilling box 14 is installed on the first sliding seat 171, and the pre-tightening drilling box 15 is installed on the second sliding seat 172, as... Figure 3 As shown, at this time, the sliding seat assembly 17 is in the first position. In the first position, the drilling box 14 is located beside the sliding module 13 (which can be on the right side) and is idle. The pre-tightening drilling box 15 is engaged with the sliding module 13 and can slide synchronously with the sliding module 13 in the first direction. When the sliding seat assembly 17 is in the second position, the pre-tightening drilling box 15 is located beside the sliding module 13 (which can be on the left side) and is idle. The drilling box 14 is engaged with the sliding module 13 and can slide synchronously with the sliding module 13 in the first direction.

[0075] The bolt magazine assembly 200 includes a robotic arm 21 and multiple parallel, spaced-apart conveying assemblies 22, with the robotic arm 21 located at one end of each conveying assembly 22. For example, as... Figure 4 As shown, there can be two robotic arms 21 and two transmission components 22. Both transmission components can extend in the front-to-back direction, and the two transmission components 22 can be arranged at intervals in the vertical direction. The two robotic arms 21 can be correspondingly located at the top of the two transmission components.

[0076] like Figure 5 As shown, the conveying assembly 22 includes a stop bar 221 and a conveying rod 222 arranged in parallel. The stop bar 221 can be a rectangular plate, and the conveying rod 222 can be generally cylindrical. Both the stop bar 221 and the conveying rod 222 can extend in the front-back direction, and the stop bar 221 can be arranged in parallel on the right side of the conveying rod 222. The conveying rod 222 has a spiral groove 2221 that extends spirally along the axial direction of the conveying rod 222. The spiral groove 2221 spirally penetrates the conveying rod 222 along the axial direction of the conveying rod 222, and multiple anchor rods 300 are laterally embedded in the spiral groove 2221 and stopped and limited by the stop bar 221.

[0077] In use, the conveyor rod 222 can be driven to rotate. Since the anchor rod 300 is confined within the space enclosed by the spiral groove 2221 and the stop rod 221, and under the action of the spiral groove 2221, the rotation of the conveyor rod 222 can be converted into the action of driving the anchor rod 300 to translate in the front-back direction, so that the anchor rod 300 can be sequentially conveyed to the robot arm 21. The robot arm 21 can grab the anchor rod 300 conveyed to the top of the conveyor assembly 22, and then the robot arm 21 can move the anchor rod 300 to directly above the pre-tightening drill box 15 located in the first position through translation, swinging and other actions. Then, the upward movement of the sliding module 13 drives the pre-tightening drill box 15 to move upward, and then the anchor rod 300 can be anchored into the drill hole through the pre-tightening drill box 15.

[0078] The construction system of the present invention may include the following steps when in use:

[0079] S1: The sliding seat group 17 can be driven to the second position by the sliding drive 18. At this time, the drilling box 14 slides onto the sliding module 13 through the first sliding seat 171, and the pre-tightening drilling box 15 slides to the side of the sliding module 13 through the second sliding seat 172.

[0080] S2: Switch the clamping mechanism 16 to the first state and clamp the drill rod 141 between the two clamps. The clamping mechanism 16 can play a straightening role. Then the drilling box 14 can be started and the sliding module 13 can be driven to move upward, thereby realizing the drilling construction.

[0081] S3: When the drilling box 14 is near the clamping mechanism 16, the clamping mechanism 16 can be switched to the second state, so that the drilling box 14 can pass through the clamping mechanism 16.

[0082] S4: After the drilling is completed, the sliding module 13 can be reset, and then the sliding base can be switched to the first position using the sliding drive 18. At this time, the pre-tightening drill box 15 slides onto the sliding module 13 through the second sliding seat 172, and the drilling drill box 14 slides to the other side of the sliding module 13 through the first sliding seat 171.

[0083] S5: Then the two conveyor rods 222 can rotate synchronously and transport an anchor rod 300 to the robot arm 21. The robot arm 21 can then grab the anchor rod 300 and transfer it to the top of the pre-tightening drill box 15. In some embodiments, the robot arm 21 can also be used to drive the anchor rod 300 downward, so that the anchor rod 300 can be inserted into the corresponding hole of the pre-tightening drill box 15, thereby realizing the assembly of the anchor rod 300 and the pre-tightening drill box 15.

[0084] S6: Then the sliding module 13 can be driven to move upward again and the clamping mechanism 16 can be switched to the first state again, so that the anchor rod 300 can be inserted into the borehole. When the tray on the anchor rod 300 and the pre-tightening drill box 15 pass through the clamping mechanism 16, the clamping mechanism 16 can be switched to the second state to improve the passability.

[0085] S7: Then, different anchoring agent components can be pumped into the channel of the anchor bolt 300 via the pumping system.

[0086] S8: After the different anchoring agent components are mixed and cured in the borehole, the pre-tightening drill box 15 can be driven to rotate in the opposite direction and the pre-tightening nut can be fixed, thereby realizing the construction of the anchor rod 300, and then the pre-tightening drill box 15 can be reset.

[0087] The automatic anchor bolt construction system of this invention simplifies the construction process of anchor bolt 300, improves the automation of the entire anchor bolt 300 construction process, thereby improving work efficiency and reducing the labor intensity of workers.

[0088] In some embodiments, the bolt housing assembly 200 includes a gearbox 23, which is located at the other end of a plurality of transmission components 22. The transmission rods 222 of the plurality of transmission components 22 are all connected to the gearbox 23 so that the gearbox 23 can drive the plurality of transmission rods 222 to rotate synchronously when it is in operation.

[0089] For example, such as Figures 4 to 6 As shown, the gearbox 23 may include a housing and a gear system. The housing may be fixed to the rear end of the transmission assembly 22, and the gear system may be installed inside the housing. The gear system may include a motor and multiple gears. Each transmission rod 222 may have a gear fixed to its rear end, and the gear system meshes with the gears at the rear end of each transmission rod 222. In use, the motor or other means can drive the gear system to operate, thereby achieving synchronous linkage drive of multiple transmission rods 222, ensuring the consistency and synchronicity of the rotation of multiple transmission rods 222.

[0090] It should be noted that the style, specifications, and dimensions of the multiple conveyor rods 222 are completely identical, and the positions and directions of the multiple spiral grooves 2221 on the multiple conveyor rods 222 are also consistent during assembly. In this way, when the multiple conveyor rods 222 rotate, the consistency of conveying and lifting of the individual anchor rod 300 can be guaranteed, avoiding interference during the conveying process.

[0091] In some embodiments, such as Figure 5 and Figure 6As shown, multiple stop bars 221 are connected and fixed to the gearbox 23. For example, the stop bars 221 can be installed on the left side of the gearbox 23 by welding, fastener fixing, etc. Each transmission rod 222 can be rotatably mounted on the top of the gearbox 23, and the multiple transmission rods 222 and multiple stop bars 221 are arranged opposite each other in the left-right direction. Multiple anchor bars 300 are located between the transmission rods 222 and the stop bars 221 of each transmission assembly, and each anchor bar 300 is fitted into the recess of the spiral groove 2221 facing the stop bar 221, and the spacing between any two adjacent anchor bars 300 is consistent with the pitch of the spiral groove 2221.

[0092] Therefore, when multiple transmission rods 222 rotate synchronously for one revolution, each anchor rod 300 can move forward by one pitch, thus ensuring the consistency of the transmission cycle of any two adjacent anchor rods 300, which helps to simplify the overall transmission method.

[0093] In some embodiments, the robotic arm 21 includes a gripper 211 for gripping the anchor rod 300 being conveyed to the end of the conveying assembly 22, and the gripper 211 is arranged opposite to the pre-tightening drill box 15 located in the first position in a second direction.

[0094] For example, such as Figure 7 As shown, the gripper 211 may include a first gripper and a second gripper. The first gripper and the second gripper can be arranged opposite each other in the front-back direction, and the first gripper and the second gripper can be rotated and assembled. In use, the opening angle between the first gripper and the second gripper can be adjusted, thereby fulfilling the needs of gripping and releasing the anchor rod 300.

[0095] In some other embodiments, one of the first claw and the second claw may also translate relative to the other in the front-back direction, thereby making the distance between the first claw and the second claw adjustable, and the grasping and releasing actions can also be completed by adjusting the distance.

[0096] like Figure 7 As shown, under normal conditions, the gripper 211 and the pre-tightening drill box 15 located in the first position can be roughly located in the same vertical plane orthogonal to the front and back directions. In this way, after the gripper 211 grabs the anchor rod 300, it can be aligned with the pre-tightening drill box 15 by translating in the left and right directions. This facilitates the transfer of the anchor rod 300 grabbed by the robot arm 21 to the pre-tightening drill box 15, simplifies the alignment process, and improves the ease of use.

[0097] In some embodiments, such as Figure 7 As shown, the robotic arm 21 also includes a first sliding component 212, a second sliding component 213, and a third sliding component 214. The first sliding component 212, the second sliding component 213, and the third sliding component 214 can all be sliding hydraulic cylinders.

[0098] The gripper 211 is located at the drive end (right end) of the first sliding member 212, and the first sliding member 212 is used to drive the gripper 211 to finely adjust along the second direction (left-right direction) so that the anchor rod 300 gripped by the gripper 211 can be arranged directly opposite the pre-tightening drill box 15 located in the first position in the first direction (up-down direction). Specifically, in use, the first sliding member 212 can be driven to move first, and the first sliding member 212 can drive the gripper 211 to move slightly in the left-right direction, thereby facilitating the gripper 211 to grip the anchor rod 300 at the end of the conveying assembly 22.

[0099] The first sliding member 212 is assembled to the second sliding member 213, and the second sliding member 213 is used to drive the first sliding member 212 to move along a second direction to achieve coarse adjustment of the anchor rod 300 gripped by the gripper 211. For example, as Figure 7 As shown, the second sliding member 213 can extend in the left and right direction, and the first sliding member 212 can be connected and fixed to the sliding part of the second sliding member 213.

[0100] In use, the second sliding component 213 can drive the first sliding component 212 and the gripper 211 to move synchronously in the left and right direction, which facilitates moving the anchor rod 300 gripped by the gripper 211 to the upper end of the pre-tightening drill box 15. Then, the anchor rod 300 can be aligned with the pre-tightening drill box 15 in the vertical direction by fine adjustment of the first sliding component 212.

[0101] The second sliding member 213 is assembled to the third sliding member 214, and the third sliding member 214 is used to drive the gripper 211 to move in a first direction via the first sliding member 212 and the second sliding member 213 so that the anchor rod 300 gripped by the gripper 211 can engage with the pre-tightened drill box 15. For example, as Figure 7 As shown, the third sliding member 214 can extend along the vertical direction, and the second sliding member 213 can be connected and fixed to the sliding part of the third sliding member 214.

[0102] In use, the third sliding component 214 can drive the gripper 211, the first sliding component 212, and the second sliding component 213 to move synchronously in the up and down direction, so that the anchor rod 300 can be fitted into the corresponding hole of the pre-tightening drill box 15, which facilitates the docking of the anchor rod 300 and the pre-tightening drill box 15.

[0103] In some embodiments, such as Figures 4 to 6As shown, the anchor bolt assembly 200 includes a frame connecting rod 24, which can be a long plate and can extend in the vertical direction. Multiple robotic arms 21 are provided, each corresponding to one end of a multiple conveying assembly 22, and the third sliding component 214 of each robotic arm 21 is connected to the frame connecting rod 24. Specifically, two robotic arms 21 can be provided, and the two robotic arms 21 can be fixed to the upper and lower ends of the frame connecting rod 24 respectively, thereby achieving integrated and unified installation of multiple robotic arms 21.

[0104] In some embodiments, as shown in 8, the construction system includes a limit drive 19, which is disposed in the sliding module 13. For example, the limit drive 19 can be a limit cylinder. The limit drive 19 can be fixed in the sliding module 13, and the driving end of the limit drive 19 can move in the front-back direction.

[0105] Both the first sliding seat 171 and the second sliding seat 172 are provided with limiting holes 173. In the first position, the limiting drive 19 engages with the limiting hole 173 on the second sliding seat 172, thereby enabling the connection and fixation of the second sliding seat 172 and the sliding module 13, facilitating the up-and-down movement of the second sliding seat 172 driven by the sliding module 13. When switched to the second position, the limiting drive 19 engages with the limiting hole 173 on the first sliding seat 171, thereby also enabling the connection and fixation of the first sliding seat 171 and the sliding module 13, facilitating the up-and-down movement of the first sliding seat 171 driven by the sliding module 13.

[0106] In some embodiments, the sliding drive 18 is located below the sliding base. The sliding drive 18 is provided with a plurality of pins 181. The first sliding base 171 and the second sliding base 172 are detachably connected to the sliding drive 18 through corresponding pins 181, and each pin 181 extends along a first direction.

[0107] For example, such as Figure 9 As shown, the sliding drive 18 may be provided with two pins 181, both of which can be cylindrical, and the two pins 181 are spaced apart in the second direction, and both pins 181 extend along the vertical direction. The first sliding seat 171 may be integrally formed with a first plug block, and the first plug block may be provided with a first plug hole. The second sliding seat 172 may be integrally formed with a second plug block, and the second plug block may be provided with a second plug hole. The two pins 181 on the sliding drive 18 can be inserted into the first plug hole and the second plug hole respectively.

[0108] When the sliding seat assembly 17 needs to switch between the first and second positions, the two pins 181 are respectively inserted into the corresponding sockets, thereby driving the first sliding seat 171 and the second sliding seat 172 to slide synchronously. Secondly, when the sliding module 13 moves up or down, the pins 181 that are inserted into the first or second socket can automatically disengage or automatically complete the insertion and assembly, thus facilitating the driving connection and automatic separation of the first sliding seat 171 and the second sliding seat 172 from the sliding drive 18, making it convenient to use.

[0109] In some embodiments, the drill rod 141 is provided with a liquid passage hole, which extends axially along the drill rod 141 and is used to supply liquid to the drill bit of the drill rod 141. The inlet of the liquid passage hole can be located at the bottom end of the drill rod 141, and the outlet of the liquid passage hole can be located at the top end of the drill rod 141. When the drill rod 141 is drilling, liquids such as water can be introduced into the liquid passage hole, thereby achieving cooling of the drill bit of the drill rod 141.

[0110] In some embodiments, the construction system includes a module drive, which is mounted on the drill frame 11 and connected to the sliding module 13 to drive the sliding module 13 to slide along a first direction. Specifically, the module drive can be a chain drive, a hydraulic cylinder drive, etc. This facilitates the sliding adjustment of the vertical position of the sliding module 13.

[0111] In some embodiments, such as Figure 8 As shown, the limiting hole 173 is an elongated hole that extends along the first direction, and the two opposite holes of the limiting hole 173 in the first direction are both arc surfaces. The driving end of the limiting drive 19 can be cylindrical. Thus, the length of the limiting hole 173 can play a certain role in compensating for assembly errors and ensuring the stability of the insertion assembly of the limiting drive 19 and the limiting hole 173.

[0112] On the other hand, the arc surface design can increase the contact area between the limit drive 19 and the hole wall of the limit hole 173, thereby improving the stability of the first sliding seat 171 and the second sliding seat 172 in cooperation with the limit drive 19. It also helps to reduce the pressure effect and avoid the reaction force generated during the drilling process being applied to the limit drive 19, which could easily cause damage to the limit drive 19.

[0113] In some embodiments, the output speed of the drilling box 14 is greater than the output speed of the pre-tensioning drilling box 15, and the output torque of the drilling box 14 is less than the output torque of the pre-tensioning drilling box 15. Compared with the requirements of the prior art for high speed and high torque of the drilling box in the operation of anchor bolts in China 300, the present invention achieves the separation of the construction process by setting two drilling boxes, so that high speed and high torque can be applied to different drilling boxes respectively, which helps to reduce the manufacturing cost and difficulty of the drilling boxes.

[0114] In some embodiments, such as Figure 9 As shown, both the sliding module 13 and the drill box base 12 are provided with guide grooves 124. The guide grooves 124 extend along the second direction, and their cross-sections can be circular. When the sliding module 13 is located within the slot, the guide grooves 124 on the sliding module 13 and the guide grooves 124 on the drill box base 12 are connected in the second direction. That is, the guide grooves 124 on the sliding module 13 and the drill box base 12 can be connected into a single through slot, thereby facilitating the switching of the first sliding seat 171 and the second sliding seat 172 on the sliding module 13 and the drill box base 12.

[0115] like Figure 8 As shown, both the first sliding seat 171 and the second sliding seat 172 are provided with guide portions 174. The guide portion 174 can be cylindrical. The guide portion 174 is slidably assembled in the guide groove 124 and is engaged and limited by the guide groove 124. That is, the width dimension of the groove opening of the guide groove 124 is smaller than the radial dimension of the guide portion 174, thereby preventing the guide portion 174 from coming out of the groove opening of the guide groove 124 and improving the structural stability of the assembly.

[0116] In some embodiments, such as Figure 9 As shown, the drill box base 12 includes a first plate 121, two second plates 122 and multiple inclined plates 123. The guide groove 124 of the drill box base 12 is provided on one side of the first plate 121 (which can be the front side). The two second plates 122 are fixed to the other side of the first plate 121 (which can be the rear side), and the two second plates 122 are arranged at intervals in the second direction. The drill frame 11 is fitted between the two second plates 122. The interval between the two second plates 122 can form the above-mentioned slot. At this time, the first plate 121 is also considered to include two independent plate parts. The two independent plate parts are respectively connected to the two second plates 122 one by one, and the slot is also located between the two independent plate parts.

[0117] An inclined plate 123 is disposed on the outside of the two second plates 122 and fixed at the angle formed by the first plate 121 and the second plate 122, and the inclined plate 123 is arranged perpendicular to both the first plate 121 and the second plate 122. The inclined plate 123 can enhance the structural strength, thereby fully meeting the technological requirements of downhole construction.

[0118] In some embodiments, the clamping mechanism 16 further includes a base 161, a driver 163, and a transmission component 164. The base 161 includes a mounting plate 1613, a first protective plate 1611, and a second protective plate 1612. The mounting plate 1613 can be generally flat. During assembly, the mounting plate 1613 can be arranged horizontally and fixed to the top of the anchor bolt 300 drilling rig. The fixing method can be bolts, snap-fit, etc.

[0119] The first protective plate 1611 and the second protective plate 1612 are both fixed to the top side of the mounting plate 1613, and the first protective plate 1611, the second protective plate 1612, and the mounting plate 1613 form an assembly cavity 1614. For example, as Figure 10 and Figure 11 As shown, both the first protective plate 1611 and the second protective plate 1612 can be fixed to the top side of the mounting plate 1613 by bolts. The first protective plate 1611 can be located on the left side of the mounting plate 1613, and the second protective plate 1612 can be located on the right side of the mounting plate 1613. The first protective plate 1611 and the second protective plate 1612 can be arranged at intervals in the left-right direction. The space between the first protective plate 1611 and the second protective plate 1612 can form the assembly cavity 1614. In some other embodiments, the mounting plate 1613, the first protective plate 1611, and the second protective plate 1612 can also be integrally formed.

[0120] The driver 163 is assembled in the assembly cavity 1614, the transmission component 164 is connected to the driver 163, and the first clamp 1621 and the second clamp 1622 are both slidably assembled with the transmission component 164 so as to switch to the first mode or the second mode by sliding assembly when the driver 163 drives the transmission component 164 to move.

[0121] For example, the actuator 163 can be linearly driven, meaning it can extend and retract along the front-to-back direction. The actuator 163 can be fixed within the assembly cavity 1614 and can be mounted and fixed to the mounting plate 1613 using bolts or other fasteners. The transmission component 164 can be fixed to the drive end of the actuator 163, and both the first clamp 1621 and the second clamp 1622 can be slidably assembled with the transmission component 164. In use, the actuator 163 can drive the transmission component 164 to move back and forth. For example, when the transmission component 164 moves forward, both the first clamp 1621 and the second clamp 1622 will swing inward, thereby reducing the opening angle of the first clamp 1621 and the second clamp 1622, allowing the clamp assembly 162 to be adjusted to a first configuration. When the transmission component 164 moves backward, both the first clamp 1621 and the second clamp 1622 will swing outward, thereby increasing the opening and closing angle of the first clamp 1621 and the second clamp 1622, so that the clamp assembly 162 can be adjusted to the second form.

[0122] The clamping mechanism 16 of this invention not only assists in straightening the anchor bolt 300 and drill rod 141, but also allows the drill box to pass through, making switching operations convenient and improving the automation of anchor bolt 300 support construction. Secondly, since the driver 163 is installed inside the assembly cavity 1614, the mounting plate 1613, the first protective plate 1611, and the second protective plate 1612 can shield and conceal the driver 163, thereby protecting it and preventing it from being easily damaged by falling coal gangue, thus improving its stability during use.

[0123] In some embodiments, the transmission member 164 is provided with a sliding groove, the extension direction of which is orthogonal to the direction in which the driver 163 drives the transmission member 164 to move. For example, the driver 163 can drive the transmission member 164 to reciprocate in the front-back direction, and the sliding groove can extend in the left-right direction. The first clamp 1621 is provided with a first sliding pin 16213, which can be integrally formed on the first clamp 1621. The second clamp 1622 is provided with a second sliding pin 16223, which can be integrally formed on the second clamp 1622. Both the first sliding pin 16213 and the second sliding pin 16223 are slidably assembled in the sliding groove. This simplifies the sliding assembly form of the first clamp 1621, the second clamp 1622 and the transmission member 164, and also ensures the structural stability and reliability of the sliding assembly.

[0124] In some embodiments, such as Figure 13 As shown, the actuator 163 is a hydraulic cylinder and includes a drive rod 1631. The transmission member 164 is connected to the front end of the drive rod 1631 and is arranged orthogonally to the drive rod 1631. For example, the transmission member 164 can be a long plate and extend in the left-right direction, and the drive rod 1631 can be a round rod and extend in the front-back direction.

[0125] like Figure 13 As shown, the slide includes a first slide 1641 and a second slide 1642. Both the first slide 1641 and the second slide 1642 can be waist-shaped. The first slide 1641 and the second slide 1642 are arranged at intervals in the left and right direction and both extend along the extension direction (left and right direction) of the transmission member 164. The first sliding pin 16213 is slidably assembled in the first slide 1641 and can rotate relative to it in the first slide 1641. The second sliding pin 16223 is slidably assembled in the second slide 1642 and can rotate relative to it in the second slide 1642.

[0126] Specifically, both the first sliding pin 16213 and the second sliding pin 16223 can be cylindrical, which can reduce the contact area with the slide groove and ensure smooth sliding. On the other hand, the swinging of the first clamp 1621 and the second clamp 1622 will cause the first sliding pin 16213 and the second sliding pin 16223 to rotate in the corresponding slide groove, thereby avoiding interference from the rotation of the sliding pin in the corresponding slide groove.

[0127] In some embodiments, the first clamp 1621 is provided with a first slot 16212, the second clamp 1622 is provided with a second slot 16222, the first clamp 1621 is engaged in the second slot 16222, and the drive rod 1631 and the drive member are engaged in the first slot 16212.

[0128] For example, such as Figure 12 As shown, the first slot 16212 can be provided in the rear half of the first clamp 1621, and the first slot 16212 can penetrate the first clamp 1621 in the left-right direction, with the slot opening facing rearward. Similarly, the second slot 16222 can be provided in the rear half of the second clamp 1622, and the second slot 16222 can penetrate the second clamp 1622 in the left-right direction, with the slot opening facing rearward.

[0129] The rear end of the first clamp 1621 can be rotatably mounted within the second slot 16222, while the drive rod 1631 and the drive component are both located within the first slot 16212 and the second slot 16222. This design serves two purposes: firstly, it conceals and hides the drive rod 1631 and the drive component, thus providing protection; secondly, it allows the drive rod 1631 and the drive component to utilize the space within the first clamp 1621 and the second clamp 1622, improving the compactness of the structural assembly and ensuring structural strength.

[0130] In some embodiments, the clamping mechanism 16 includes a first pin 165 and a second pin 166, which are coaxially arranged. The first clamp 1621 and the second clamp 1622 on one side of the first slot 16212 are rotatably connected to one of the first guard plate 1611 and the second guard plate 1612 via the first pin 165. The first clamp 1621 and the second clamp 1622 on the other side of the first slot 16212 are rotatably connected to the mounting plate 1613 via the second pin 166.

[0131] For example, such as Figure 13As shown, in the vertical direction, the portions of the first clamps 1621 on both the upper and lower sides of the first slot 16212 can form first arms, and the first slot 16212 is formed between the two first arms. Similarly, the portions of the second clamps 1622 on both the upper and lower sides of the second slot 16222 can form second arms, and the second slot 16222 is formed between the two second arms.

[0132] The first pin 165 can pass through the first guard plate 1611, the first arm on the upper side of the first clamp 1621, and the second arm on the upper side of the second clamp 1622, enabling pivotal assembly of the three. The second pin 166 can pass through the mounting plate 1613, the first arm on the lower side of the first clamp 1621, and the second arm on the lower side of the second clamp 1622, also enabling pivotal assembly of the three. This avoids interference between the pins and the driving components and the driving rod 1631, improving assembly convenience.

[0133] In some embodiments, such as Figure 10 As shown, the first guard plate 1611 can be integrally formed with an extension 16111, which extends toward the second guard plate 1612. For example, the extension 16111 can generally extend in a left-right direction and can be positioned horizontally at the top opening of the mounting cavity 1614. The first pin 165 passes through the upper first arm of the first clamp 1621 and the upper second arm of the second clamp 1622 and is pivotally connected to the extension 16111. The extension 16111 improves the ease of installation.

[0134] In some embodiments, the included angle formed by the first clamp 1621 and the second clamp 1622 in the second configuration is greater than the opening angle of the first clamp 1621 and the second clamp 1622 in the first configuration, and in the second configuration, the transmission member 164 abuts against at least one of the bottom of the first slot 16212 and the bottom of the second slot 16222 to limit the upper limit of the opening angle of the first clamp 1621 and the second clamp 1622 in the second configuration.

[0135] For example, such as Figure 12 As shown, in the second configuration, the outer edge of the bottom of the second slot 16222 can abut against the front surface of the transmission component 164, thereby preventing the second clamp 1622 from continuing to swing to the right, and thus limiting the swing of the first clamp 1621 to the left. This avoids the situation where the opening and closing angle of the first clamp 1621 and the second clamp 1622 is too large and it is easy to generate a dead point, thus ensuring the stability of use.

[0136] In some other embodiments, in the second configuration, the transmission member 164 can simultaneously engage with the first clamp 1621 and the second clamp 1622.

[0137] In some embodiments, the projection of the first clamp 1621 on the mounting plate 1613 and the projection of the second clamp 1622 on the mounting plate 1613 are both V-shaped, and the bends of the first clamp 1621 and the second clamp 1622 are arranged opposite to each other.

[0138] For example, such as Figure 10 and Figure 11 As shown, the rear half of the first clamp 1621 can extend in the front-rear direction, and the front half of the first clamp 1621 can generally extend in the direction from left front to right rear. The rear half of the second clamp 1622 can extend in the front-rear direction, and the front half of the second clamp 1622 can generally extend in the direction from right front to left rear. The assembly cavity 1614 can be formed between the rear half of the first clamp 1621 and the rear half of the second clamp 1622. The front and rear ends of the first clamp 1621 and the second clamp 1622 can be fixed by bolts.

[0139] This design allows for a wide and relatively balanced distribution of fastening forces, thereby improving the overall structural stability.

[0140] In some embodiments, in a first configuration, the end face of the slot opening of the first slot 16211 and the end face of the slot opening of the second slot 16221 are attached together to form an interface 1623, and the interface 1623 is not perpendicular to the sliding direction of the sliding assembly and the driving direction of the driver 163.

[0141] Specifically, such as Figure 10 As shown, the interface 1623 of the first clamp 1621 and the second clamp 1622 in the first configuration can be shown as a dashed line. The interface 1623 can be arranged at an angle from right front to left rear. As a result, the direction of the force at the interface 1623 and the direction of the force applied by the driver 163 to the transmission member 164 form an angle, realizing the cross arrangement of different forces, which is conducive to interlocking and enhancing the clamping effect on the anchor rod 300 and the drill rod 141.

[0142] The construction system of this invention has the following beneficial effects:

[0143] (1) The device of this invention is used in conjunction with a hollow anchor injection integrated anchor rod, which reduces the traditional anchor rod operation process of 6 steps (drilling-removing drill rod-installing anchoring agent-installing anchor rod and tray-mixing anchoring agent and pre-tightening) to 4 steps (drilling-installing anchor rod and tray-pumping anchoring agent-pre-tightening), simplifies the process of removing drill rod and installing anchoring agent, realizes full automation of anchor rod operation, and also realizes automation of anchor rod installation on drilling rig assembly, without the need for manual intervention, thus improving the automation level and operation efficiency of anchor rod operation;

[0144] (2) The drill rod is always fixedly connected to the drilling box, avoiding processes such as putting on and taking off the drill rod, and realizing the automation of the drilling process;

[0145] (3) The process of pump injection of anchoring agent avoids the problem of manual application of the agent roll, and improves the automation level and efficiency of anchor bolt operation.

[0146] (4) Traditional anchor bolting processes require high rotation speed and high torque from the drill box. In this invention, the construction process is split into two drill boxes. One drill box achieves high rotation speed, and the other drill box achieves high torque, which reduces the manufacturing cost and difficulty of the drill box.

[0147] (5) The design scheme of two drilling boxes, one drilling box is responsible for drilling and the other drilling box is responsible for grouting and pre-tightening, which avoids the problems of complex structure and low reliability of the integrated anchoring and grouting drilling box. The two drilling box schemes reduce the structural complexity of the drilling box and improve the reliability of the equipment by process separation.

[0148] (6) The clamping mechanism adopts a direct-push sliding mechanism (which can be regarded as the assembly of the driver and transmission components). It can achieve the control of the large-angle opening and closing of the left and right clamps through the small displacement sliding in the groove of the special-shaped oil cylinder, so as to meet the direct passage of the large tray and the drill box, and also play the role of straightening the drill rod in the early stage of drilling.

[0149] In the description of this invention, it should be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," and "circumferential" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of describing this invention and simplifying the description, and are not intended to indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.

[0150] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. In the description of this invention, "a plurality of" means at least two, such as two, three, etc., unless otherwise explicitly specified.

[0151] In this invention, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection, an electrical connection, or a connection that allows communication between them; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components, unless otherwise explicitly limited. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.

[0152] In this invention, unless otherwise explicitly specified and limited, "above" or "below" the second feature can mean that the first feature is in direct contact with the second feature, or that the first feature is in indirect contact with the second feature through an intermediate medium. Furthermore, "above," "over," and "on top" of the second feature can mean that the first feature is directly above or diagonally above the second feature, or simply that the first feature is at a higher horizontal level than the second feature. "Below," "below," and "under" the second feature can mean that the first feature is directly below or diagonally below the second feature, or simply that the first feature is at a lower horizontal level than the second feature.

[0153] In this invention, the terms "one embodiment," "some embodiments," "example," "specific example," or "some examples," etc., refer to a specific feature, structure, material, or characteristic described in connection with that embodiment or example, which is included in at least one embodiment or example of the invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. Moreover, without contradiction, those skilled in the art can combine and integrate the different embodiments or examples described in this specification, as well as the features of different embodiments or examples.

[0154] Although the above embodiments have been shown and described, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention. Any changes, modifications, substitutions and variations made to the above embodiments by those skilled in the art are within the protection scope of the present invention.

Claims

1. An automatic anchor bolt construction system, characterized in that, include: The drilling rig assembly includes a drill frame, a drill box base, a sliding module, a drilling drill box, a pre-tightening drill box, a sliding seat assembly, and a sliding drive. The drill box base is fixed to the drill frame, and the drill box base has a slot in the middle. The sliding module is fitted into the slot and slides along the first direction to be assembled to the drill frame. The drilling box is fixed with a drill rod for drilling. The pre-tightening drill box is used to feed and pre-tighten the anchor rod into the drill hole. The anchor rod has at least two channels for conveying different types of anchoring agent components into the drill hole. The sliding seat assembly has a first position and a second position. The sliding seat assembly is slidably mounted on the drill box base along a second direction orthogonal to the first direction. The sliding drive is provided on the drill box base and is used to drive the sliding seat assembly to switch back and forth between the first position and the second position. The sliding seat assembly includes a first sliding seat and a second sliding seat. The drilling box is installed on the first sliding seat, and the pre-tightening drilling box is installed on the second sliding seat. In the first position, the second sliding seat cooperates with the sliding module and can slide synchronously with the sliding module along the first direction. In the second position, the first sliding seat cooperates with the sliding module and can slide synchronously with the sliding module along the first direction. An anchor bolt magazine assembly, the anchor bolt magazine assembly including a robotic arm and a plurality of parallel and spaced conveying components, the robotic arm being located at one end of the conveying components; The conveying assembly includes parallel arranged stop bars and conveying rods. The conveying rods are provided with spiral grooves that extend spirally along the axial direction of the conveying rods. A plurality of anchor rods are laterally embedded in the spiral grooves and stopped and limited by the stop bars. The plurality of anchor rods are used to sequentially convey to the robot arm when the conveying rods rotate. The robot arm is used to grab the anchor rods located at the end of the conveying assembly and transport the grabbed anchor rods to the pre-tightening drill box located at the first position. The drilling rig assembly includes a clamping mechanism, which is disposed on the drill frame and arranged opposite to the sliding module in the first direction. The clamping mechanism has two clamps, and the angles of the two clamps can be adjusted to allow the clamping mechanism to have a first form and a second form. The opening angle of the clamping mechanism in the second form is greater than the opening angle in the first form. In the first form, the clamping mechanism is used to straighten the drill rod or the anchor rod. In the second form, the clamping mechanism allows the drilling box or the pre-tightening drilling box to pass through. The clamping mechanism includes: The base includes a mounting plate, a first protective plate, and a second protective plate. The mounting plate is used to fix the base to the top of the drill frame. The first protective plate and the second protective plate are both fixed to the top side of the mounting plate, and the first protective plate, the second protective plate, and the mounting plate form an assembly cavity. A driver and a transmission component, wherein the driver is assembled in the assembly cavity, the transmission component is connected to the driver, and both clamps are slidably assembled with the transmission component to switch to the first or the second configuration through the sliding assembly when the driver drives the transmission component to move. The transmission component is provided with a first slide groove and a second slide groove. The first slide groove and the second slide groove are arranged at intervals and both extend along the extension direction of the transmission component. The driver includes a drive rod. The transmission component is connected to the drive rod and arranged orthogonally to the drive rod. The first clamp is provided with a first sliding pin, and the second clamp is provided with a second sliding pin. The first sliding pin is slidably assembled in the first slide groove and can rotate relative to it in the first slide groove. The second sliding pin is slidably assembled in the second slide groove and can rotate relative to it in the second slide groove.

2. The automatic anchor bolt construction system according to claim 1, characterized in that, The bolt housing assembly includes a gearbox located at the other end of the plurality of conveying components. The conveying rods of the plurality of conveying components are all connected to the gearbox so that the gearbox can drive the plurality of conveying rods to rotate synchronously when in operation.

3. The automatic anchor bolt construction system according to claim 2, characterized in that, Multiple stop bars are fixedly connected to the gearbox, and multiple anchor bars are located between the conveying rod and the stop bar of each conveying assembly, and the distance between any two adjacent anchor bars is consistent with the pitch of the spiral groove.

4. The automatic anchor bolt construction system according to claim 1, characterized in that, The robotic arm includes grippers for gripping the anchor rod being conveyed to the end of the conveying assembly, and the grippers are arranged opposite to the pre-tightening drill box located in the first position in the second direction.

5. The automatic anchor bolt construction system according to claim 4, characterized in that, The robotic arm also includes: The first sliding component has a gripper located at the drive end of the first sliding component, and the first sliding component is used to drive the gripper to finely adjust along the second direction so that the anchor rod gripped by the gripper can be arranged directly opposite the pre-tightening drill box located at the first position in the first direction. A second sliding component is provided, wherein the first sliding component is mounted on the second sliding component, and the second sliding component is used to drive the first sliding component to move along the second direction to achieve coarse adjustment of the anchor rod gripped by the gripper; A third sliding component, wherein the second sliding component is assembled to the third sliding component, and the third sliding component is used to drive the jaws to move in the first direction through the first sliding component and the second sliding component so that the anchor rod gripped by the jaws can cooperate with the pre-tightening drill box.

6. The automatic anchor bolt construction system according to claim 5, characterized in that, The anchor bolt assembly includes a frame link, and there are multiple robotic arms, each robotic arm being disposed at the end of a plurality of conveying components, and the third sliding component of each of the plurality of robotic arms is connected to the frame link.

7. The automatic anchor bolt construction system according to any one of claims 1-6, characterized in that, The drilling rig assembly includes a limit drive and a module drive. The limit drive is located on the sliding module. Both the first sliding seat and the second sliding seat are provided with limit holes. In the first position, the limit drive is limited to the limit hole on the second sliding seat. In the second position, the limit drive is limited to the limit hole on the first sliding seat. The module driver is located on the drill frame, and the module driver is connected to the sliding module and is used to drive the sliding module to slide along the first direction.