Forklift pole head component machining device

By introducing a combined structure of clamping and positioning, transfer assistance, inclined plane guidance and wear compensation into the forklift rod head drilling device, the problems of easy wear of the drill bit positioning block and the danger of manual handling are solved, and efficient and safe drilling operation is achieved.

CN122077053BActive Publication Date: 2026-06-30JINGJIANG GALANTE MACHINERY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
JINGJIANG GALANTE MACHINERY CO LTD
Filing Date
2026-04-27
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In existing forklift rod head drilling devices, the drill bit positioning block is prone to wear, and it is difficult to compensate for the wear, which affects the drilling accuracy and service life. At the same time, manual handling is dangerous and inconvenient, and it is difficult to quickly clamp and position the drill bit.

Method used

It adopts a combination structure of drilling mounting parts, clamping and positioning parts, transfer auxiliary parts, inclined drilling guide parts, wear compensation parts and compensation and verification parts. Through clamping and positioning, transfer assistance, inclined guidance and wear compensation, drilling accuracy and safety are ensured.

Benefits of technology

It improves drilling accuracy and safety, reduces operating costs, simplifies operation procedures, avoids tedious manual adjustments, and extends the service life of the equipment.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses a forklift lever head component processing device, relating to the field of forklift lever head drilling technology; it includes a drilling mounting component, on which a clamping and positioning component is mounted to ensure drilling stability; a transfer auxiliary component is mounted on the drilling mounting component to reduce clamping difficulty; an inclined drilling guide component is mounted on the drilling mounting component; a wear compensation component is mounted on the inclined drilling guide component; the wear compensation component is used to limit the drill bit on the drilling mounting component; by adjusting the compensation slider, wear can be compensated, ensuring that wear can be compensated after long-term use, reducing operating costs; and with the trimming guide ring, trimming can be performed using the drill bit after wear and displacement adjustment of the compensation slider; thus solving the problem that the drill bit positioning block used in current forklift lever head drilling devices is not convenient for compensating wear and for verifying wear.
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Description

Technical Field

[0001] This invention relates to the field of forklift rod head drilling technology, specifically to a forklift rod head component processing device. Background Technology

[0002] In the actual assembly of forklift lever heads, the locating pin is a crucial limiting structure that ensures the stable installation of the forklift lever head on the forklift. After the forklift lever head is machined, holes need to be drilled to install the locating pin. The drilling location for forklift lever heads is usually at an angle to facilitate subsequent positioning and release of the locating pin through rotation. However, drilling at an angle increases the difficulty of drilling. Current forklift lever head drilling devices typically use bench drills. When drilling at angles, drill bit positioning blocks are usually used to guide the drill bit to move steadily downwards, preventing drill bit deviation problems that are prone to occur at angles. However, existing drill bit positioning blocks wear down over time, affecting drilling accuracy, making wear compensation difficult, resulting in a short service life, high cost, and difficulty in verifying wear, affecting the quality of drilling correction. Traditional forklift lever head drilling usually requires manual handling due to its heavy weight, which is not only difficult to transport and quick clamping and positioning, but also poses a high risk of danger during manual handling.

[0003] Therefore, the present invention proposes a forklift lever head component processing device. Summary of the Invention

[0004] The purpose of this invention is to provide a forklift rod head component processing device to solve the problem mentioned in the background art that the drill bit positioning block used in the current forklift rod head drilling device is not convenient for compensating for wear and for verifying the amount of wear.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a forklift lever head component processing device, comprising a drilling mounting component, wherein a clamping and positioning component is mounted on the drilling mounting component to ensure drilling stability; a transfer auxiliary component is mounted on the drilling mounting component to reduce clamping difficulty; an inclined drilling guide component is mounted on the drilling mounting component; a wear compensation component is mounted on the inclined drilling guide component; the wear compensation component is used to limit the drill bit on the drilling mounting component; a compensation verification component is mounted on the inclined drilling guide component; the drilling mounting component includes: a bench drill, a clamping seat, and a groove, wherein the clamping seat is fixedly mounted on the bench drill; the clamping seat has an L-shaped structure; two grooves are formed on the clamping seat; and threaded holes are provided on the clamping seat.

[0006] Preferably, the drilling mounting component further includes: a limiting block, and two rows of limiting blocks are fixedly installed on the clamping seat; the inner sides of the two rows of limiting blocks are chamfered respectively.

[0007] Preferably, the clamping and positioning component includes: a clamping plate and a clamping bolt, wherein the clamping plate is rotatably mounted on the clamping seat via a hinge; the clamping bolt is inserted into the clamping plate, and the end of the clamping bolt is threaded into a threaded hole on the clamping seat; a rubber pad is provided on the inner side of the clamping plate.

[0008] Preferably, the transfer auxiliary component includes: a transfer bottom plate, a forklift swing arm, a pressure plate, and a limiting plate. Two transfer bottom plates are provided, each for being placed in one of two grooves. Two forklift swing arms are rotatably mounted on each of the two transfer bottom plates, and a pressure plate is fixedly mounted on the end of each of the four forklift swing arms. The bottom of each of the four pressure plates is provided with a rubber coating. A limiting plate is fixedly mounted on the bottom of each of the four forklift swing arms, and the limiting plate has an L-shaped structure.

[0009] Preferably, the transfer auxiliary component further includes: a rod head body, the rod head body is placed inside the two transfer bottom plates, and the rod head body is located below the four pressure plates; the rod head body is placed on the clamping seat, and the rod head body is located between two rows of limiting blocks; the inner side of the clamping plate is attached to the rod head body.

[0010] Preferably, the inclined drilling guide includes: a guide block, a fastening bolt, a guide hole, and a rotating shaft. The guide block is rotatably mounted on the clamping seat. The inner side of the guide block has an inclined structure, and the inclined surface of the inner side of the guide block is used to fit the inclined surface of the drill hole of the rod head body. The guide block is threaded with a fastening bolt. The guide block has a guide hole. The guide hole is aligned with the drill bit on the bench drill. The rotating shaft is fixedly mounted on the guide block.

[0011] Preferably, the inclined drilling guide further includes: a trimming guide ring and a rod head bolt, wherein the trimming guide ring is fixedly installed on the guide block; the trimming guide ring and the guide hole are concentric; two rod head bolts are threadedly connected to the guide block, and the ends of the two rod head bolts are tapered structures; the ends of the two rod head bolts are respectively pressed against the edge of the rod head body.

[0012] Preferably, the wear compensation component includes: a compensation slider, a rotating mounting plate, and a drive screw. The inner side of the compensation slider has an arc-shaped structure; the inner side of the compensation slider and the guide hole are concentric; the rotating mounting plate is fixedly mounted on the compensation slider; the drive screw is rotatably mounted on the rotating mounting plate, and the end of the drive screw is attached to the compensation slider; the drive screw is threadedly connected to the guide block, and the end of the drive screw has a hexagonal hole; the end of the fastening bolt is pressed against the outer side of the drive screw.

[0013] Preferably, the compensation verification component includes: a rotating sleeve and a verification rod, wherein the rotating sleeve is rotatably mounted on a rotating shaft; the rotating sleeve is located inside the guide block; the verification rod is fixedly mounted on the rotating sleeve; and the verification rod is used to swing and verify the wear clearance of the compensation slider.

[0014] Preferably, the compensation verification component further includes a ball bearing, wherein the end of the verification rod is embedded with a ball bearing, and the ball bearing is used to roll and fit against the arc surface of the end of the compensation slider.

[0015] Compared with the prior art, the beneficial effects of the present invention are:

[0016] This invention employs a drilling mounting component in conjunction with a transfer auxiliary component to facilitate quick and easy clamping of the rod head body, ensuring accurate drilling position. Simultaneously, the transfer auxiliary component allows for rapid transfer of the rod head body to the clamping seat via forklift, resulting in high operational efficiency, enhanced safety, and high structural adaptability, eliminating the need for tedious manual adjustments. The transfer auxiliary component automatically clamps and secures the rod head body during forklift transfer, ensuring transfer stability, and automatically releases the clamp after transfer is complete.

[0017] The use of a beveled drilling guide in conjunction with a wear compensation component can guide the drill bit of a bench drill to move downwards during drilling, avoiding the problem of drill bit deviation when the drill head's main body is beveled. The guide hole ensures drilling accuracy and vertical drilling. Simultaneously, this structure can compensate for wear by adjusting the compensation slider, ensuring that wear is compensated even after long-term use, thus reducing operating costs. The addition of a trimming guide ring facilitates trimming work using the drill bit after wear and displacement adjustment of the compensation slider, ensuring accurate slider position accuracy. The compensation calibration component allows operators to quickly adjust the required displacement compensation amount of the compensation slider, simplifying the adjustment process without tedious manual measurement, and ensuring accurate displacement compensation distance, avoiding excessive adjustment of the compensation slider. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of a forklift lever head component processing device according to the present invention;

[0019] Figure 2 This is a schematic diagram of the clamping and positioning component structure of the present invention;

[0020] Figure 3 For the present invention Figure 1 Enlarged view of the structure of region A in the middle;

[0021] Figure 4 This is a schematic diagram of the drilling mounting component structure of the present invention;

[0022] Figure 5 This is a schematic diagram of the structure of the transfer auxiliary component of the present invention;

[0023] Figure 6 This is a schematic diagram of the top structure of the inclined drilling guide of the present invention;

[0024] Figure 7This is a schematic diagram of the bottom structure of the inclined drilling guide of the present invention;

[0025] Figure 8 This is a cross-sectional view of the wear compensation component structure of the present invention;

[0026] Figure 9 This is a cross-sectional view of the position of the compensation slider during the calibration of the compensation calibration component of the present invention.

[0027] In the diagram: 1. Drilling mounting component; 101. Bench drill; 102. Clamping seat; 1021. Groove; 1022. Limiting block; 2. Clamping positioning component; 201. Clamping plate; 202. Clamping bolt; 3. Transfer auxiliary component; 301. Transfer bottom plate; 302. Forklift swing arm; 3021. Lower pressure plate; 3022. Limiting plate; 303. Rod head body; 4. Angled drilling guide component; 401. Guide block; 4011. Fastening bolt; 4012. Guide hole; 4013. Rotating shaft; 402. Trimming guide ring; 403. Rod head bolt; 5. Wear compensation component; 501. Compensation slider; 502. Rotary mounting plate; 503. Drive screw; 6. Compensation calibration component; 601. Rotating sleeve; 602. Calibration rod; 603. Ball bearing. Detailed Implementation

[0028] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0029] Example 1: Please refer to Figures 1 to 9 As shown:

[0030] This invention provides a technical solution: a forklift lever head component processing device, including a drilling mounting component 1, a clamping and positioning component 2 mounted on the drilling mounting component 1 to ensure drilling stability; a transfer auxiliary component 3 mounted on the drilling mounting component 1 to reduce clamping difficulty; a beveled drilling guide component 4 mounted on the drilling mounting component 1; a wear compensation component 5 mounted on the beveled drilling guide component 4 to limit the drill bit on the drilling mounting component 1; a compensation verification component 6 mounted on the beveled drilling guide component 4; the drilling mounting component 1 includes: a bench drill 101, a clamping seat 102 and a groove 1021, the clamping seat 102 is fixedly mounted on the bench drill 101; the clamping seat 102 has an L-shaped structure; two grooves 1021 are formed on the clamping seat 102; and threaded holes are provided on the clamping seat 102.

[0031] The drilling mounting component 1 further includes: a limiting block 1022, with two rows of limiting blocks 1022 fixedly mounted on the clamping seat 102; the inner sides of the two rows of limiting blocks 1022 are chamfered respectively; the clamping and positioning component 2 includes: a clamping plate 201 and a clamping bolt 202, the clamping plate 201 is rotatably mounted on the clamping seat 102 via a hinge; the clamping bolt 202 is inserted into the clamping plate 201, and the end of the clamping bolt 202 is threaded into the threaded hole on the clamping seat 102; a rubber pad is provided on the inner side of the clamping plate 201; the transfer auxiliary component 3 includes: a transfer bottom plate 301, a forklift swing arm 302, a lower pressure plate 3021 and a limiting plate 3022, the transfer bottom plate 3021 and the forklift swing arm 302 are respectively mounted on the clamping seat 102. Two transfer bottom plates 301 are provided, each for being placed in one of the two grooves 1021. Two forklift swing arms 302 are rotatably mounted on each of the two transfer bottom plates 301, and each of the four forklift swing arms 302 has a lower pressure plate 3021 fixedly mounted at its end, with rubber pads at the bottom of each of the four lower pressure plates 3021. Limiting plates 3022 are fixedly mounted at the bottom of each of the four forklift swing arms 302, and the limiting plates 3022 have an L-shaped structure. The transfer auxiliary component 3 also includes a rod head body 303, which has an L-shaped structure. The rod head body 303 is placed inside the two transfer bottom plates 301, and the rod head body 303 is positioned... Below the four pressure plates 3021; ​​the rod head body 303 is placed on the clamping seat 102, and the rod head body 303 is located between the two rows of limiting blocks 1022; the inner side of the clamping plate 201 is attached to the rod head body 303; the use of the drilling mounting part 1 in conjunction with the transfer auxiliary part 3 can facilitate quick clamping of the rod head body 303, ensuring accurate drilling position. At the same time, the transfer auxiliary part 3 can facilitate quick transfer of the rod head body 303 to the clamping seat 102 for clamping by forklift, which is highly efficient, safer, and has high structural adaptability. It does not require tedious manual operation and adjustment. Using the groove 1021, it is not necessary to remove the transfer bottom plate 301 after transferring the rod head body 303. The transfer bottom plate 301 can be directly placed in the groove 1021. At the same time, the transfer auxiliary component 3 can automatically clamp and fix the rod head body 303 when the forklift transfers it, ensuring the stability of the transfer. It can also automatically release the clamp after the transfer is completed, making the structure more reasonable. By inserting the two rod heads of the forklift between the forklift swing arm 302 and the limiting plate 3022, and then raising the forklift swing arm 302, the lower pressure plate 3021 at the end of the forklift swing arm 302 will rotate downward to clamp the rod head body 303 under the action of its own weight, improving the stability of the transfer. Subsequent transfers can be carried out by clamping the rod head body 303 with the transfer auxiliary component 3.

[0032] The inclined drilling guide 4 includes: a guide block 401, a fastening bolt 4011, a guide hole 4012, and a rotating shaft 4013. The guide block 401 is rotatably mounted on the clamping seat 102. The inner side of the guide block 401 has an inclined structure, which is used to fit the inclined surface of the drill hole on the rod head body 303. The fastening bolt 4011 is threaded onto the guide block 401. The guide hole 4012 is provided on the guide block 401. The guide hole 4012 is aligned with the drill bit on the bench drill 101. The rotating shaft 4013 is fixedly mounted on the guide block 401. The inclined drilling guide 4 also includes: a trimming guide ring 402 and a rod head bolt 403 for trimming. The guide ring 402 is fixedly installed on the guide block 401; the trimmed guide ring 402 and the guide hole 4012 are concentric; two rod head bolts 403 are threadedly connected to the guide block 401, and the ends of the two rod head bolts 403 are tapered structures; the ends of the two rod head bolts 403 are respectively pressed against the edge of the rod head body 303; the wear compensation component 5 includes: a compensation slider 501, a rotary mounting plate 502 and a drive screw 503, the inner side of the compensation slider 501 is an arc structure; the inner side of the compensation slider 501 and the guide hole 4012 are concentric; the rotary mounting plate 502 is fixedly installed on the compensation slider 501; the drive screw is rotatably installed on the rotary mounting plate 502. 503, and the end of the drive screw 503 is attached to the compensation slider 501; the drive screw 503 is threadedly connected to the guide block 401, and the end of the drive screw 503 has a hexagonal hole; the end of the fastening bolt 4011 is pressed against the outside of the drive screw 503. The inclined drilling guide 4 and the wear compensation part 5 are used to guide the drill bit of the bench drill 101 to move down and drill, so as to avoid the problem that the drill bit is prone to deviation when the drill bit moves down to drill because the drilling surface of the rod head body 303 is inclined; the drilling accuracy is ensured by the guide hole 4012 to ensure vertical drilling. At the same time, this structure can compensate for wear by adjusting the compensation slider 501, which can ensure long-term stability. After wear occurs during use, the wear can be compensated, reducing operating costs. Adjustment is simple and quick. With the trimming guide ring 402, it is convenient to compensate for wear and displacement of the compensation slider 501. After adjustment and compensation, the drill bit is used for trimming to ensure the accurate position of the compensation slider 501. As the number of drillings increases, each time the drill bit moves down to drill, the lateral force generated by the inclined surface at the top of the drill hole of the rod head body 303 will cause the drill bit to wear the bottom of the compensation slider 501. This will cause tilting wear in the area of ​​the bottom of the compensation slider 501 near the drill bit. At this time, the drive screw 503 can be rotated to drive the compensation slider 501 forward to compensate for the wear distance.

[0033] In Example 2, based on Example 1, the compensation verification component 6 includes: a rotating sleeve 601 and a verification rod 602. The rotating sleeve 601 is rotatably mounted on the rotating shaft 4013; the rotating sleeve 601 is located inside the guide block 401; the verification rod 602 is fixedly mounted on the rotating sleeve 601; the verification rod 602 is used to swing and verify the wear clearance of the compensation slider 501; the compensation verification component 6 also includes: a ball bearing 603, the end of the verification rod 602 is embedded with a ball bearing 603, and the ball bearing 603 is used to roll and fit against the arc surface at the end of the compensation slider 501. Using the compensation verification component 6 can facilitate the operation of workers. The required displacement compensation amount for the compensation slider 501 can be quickly adjusted. The adjustment is simple, requiring no tedious manual measurement, and ensures accurate displacement compensation distance. It avoids excessive displacement adjustment of the compensation slider 501, and the structure and operation are simple and reasonable. If the compensation slider 501 is worn to a high degree, a gap will exist between the compensation slider 501 and the ball 603. The drive screw 503 can be rotated directly to drive the compensation slider 501 forward and make it fit the ball 603, thus accurately compensating for the gap. During normal drilling operations, the rotatable sleeve 601 does not affect the operation of the clamping rod head body 303.

[0034] The working principle of this embodiment is as follows: First, when drilling is required on the rod head body 303, the two transfer bottom plates 301 are placed on the ground. Then, the rod head body 303 is hoisted onto the two transfer bottom plates 301. Subsequently, the two rod heads of the forklift are inserted between the forklift swing arm 302 and the limiting plate 3022. Then, the forklift swing arm 302 is raised. Under the weight of the rod head body 303, the lower pressure plate 3021 at the end of the forklift swing arm 302 will rotate downward to clamp the rod head body 303, improving the stability of the transfer. Subsequent transfers are all carried out by clamping the rod head body 303 with the transfer auxiliary component 3. The rod head body 303 is transferred to the clamping seat 102 using a forklift. Two rows of limiting blocks 1022 are used to limit the rod head body 303. The rod head body 303 is then lowered, and the clamping plate 201 can be rotated to clamp it. The clamping bolts 202 are manually threaded into the threaded holes on the clamping seat 102 and tightened. After clamping the rod head body 303, the guide block 401 can be rotated to adhere to the rod head body 303. Then, the two rod head bolts 403 are tightened, using the tapered ends of the bolts 403 to clamp and position the rod head body 303. Finally, the drill bit 101 can be controlled. The drill bit moves down and rotates to perform drilling. The drill bit first passes through the guide hole 4012, and is guided from the outside by the guide hole 4012 and the compensating slider 501. Simultaneously, the compensating slider 501 mainly stops the drill bit on its side, keeping it vertically downward during drilling. After drilling is complete, the rod head body 303 can be disassembled. However, with each drilling operation, the lateral force generated by the inclined surface at the top of the rod head body 303 during drilling causes wear on the bottom of the compensating slider 501, resulting in tilted wear in the area near the drill bit's drilling point. In a zero-wear state, rotating the rotary sleeve 601 can drive the calibration rod 602 to be placed horizontally and attached to the bottom edge of the guide hole 4012. At this time, the ball bearing 603 will roll and fit against the compensation slider 501. However, if the compensation slider 501 is worn to a high degree later, there will be a gap between the compensation slider 501 and the ball bearing 603. The drive screw 503 can be rotated directly to drive the compensation slider 501 to move forward and fit against the ball bearing 603, thus accurately compensating for the gap. The operation is simple. After checking and adjusting the gap, the calibration rod 602 can be rotated to separate from the compensation slider 501, and the subsequent drilling operation can be carried out normally.

[0035] Because the compensation slider 501 is mainly worn at the bottom, when the compensation slider 501 moves forward to compensate, the top of the compensation slider 501 will protrude excessively. When the drill bit drills again, with the guidance of the trimming guide ring 402, the drill bit first passes through the trimming guide ring 402. At this time, the drill bit will automatically trim the protruding area at the top of the compensation slider 501. After the drill bit passes the compensation slider 501, the inner side of the compensation slider 501 will return to vertical, keeping the drill bit guided to move downward to carry out the drilling work.

[0036] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0037] 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 forklift lever head component processing device, comprising a drilling mounting component (1), wherein a clamping and positioning component (2) is mounted on the drilling mounting component (1), characterized in that: The drilling installation component (1) is equipped with a transfer auxiliary component (3); A beveled drilling guide (4) is installed on the drilling mounting component (1); a wear compensation component (5) is installed on the beveled drilling guide (4); the wear compensation component (5) is used to limit the drill bit on the drilling mounting component (1); The inclined drilling guide (4) is equipped with a compensation and verification component (6). The drilling mounting component (1) includes: a bench drill (101), a clamping seat (102), and a groove (1021). The clamping seat (102) is fixedly mounted on the bench drill (101). Two grooves (1021) are provided on the clamping seat (102). The clamping and positioning component (2) includes: a clamping plate (201) and a clamping bolt (202). The clamping plate (201) is rotatably mounted on the clamping seat (102). The clamping bolt (202) is inserted into the clamping plate (201), and the end of the clamping bolt (202) is threaded into the threaded hole on the clamping seat (102). The transfer auxiliary component (3) includes: a transfer bottom plate (301), a forklift swing arm (302), a pressure plate (3021), and a limiting plate (3022). There are two transfer bottom plates (301), which are respectively placed in two grooves (1021). Two forklift swing arms (302) are rotatably mounted on each of the two transfer bottom plates (301), and the pressure plates (3021) are fixedly mounted on the ends of the four forklift swing arms (302). The limiting plates (3022) are fixedly mounted on the bottom of the four forklift swing arms (302). The transfer auxiliary component (3) further includes: a rod head body (303), in which the rod head body (303) is placed in the two transfer bottom plates (301), and the rod head body (303) is located below the four pressure plates (3021); the rod head body (303) is placed on the clamping seat (102), and the rod head body (303) is located between the two rows of limiting blocks (1022); the inner side of the clamping plate (201) is attached to the rod head body (303).

2. The forklift lever head component processing device according to claim 1, characterized in that: The drilling installation component (1) further includes: a limiting block (1022), and two rows of limiting blocks (1022) are fixedly installed on the clamping seat (102).

3. The forklift lever head component processing device according to claim 1, characterized in that: The inclined drilling guide (4) includes: a guide block (401), a fastening bolt (4011), a guide hole (4012), and a rotating shaft (4013). The guide block (401) is rotatably mounted on the clamping seat (102). The inner side of the guide block (401) is an inclined structure, and the inclined surface of the inner side of the guide block (401) is used to fit the inclined surface of the drill hole of the rod head body (303). The fastening bolt (4011) is threaded on the guide block (401). The guide hole (4012) is provided on the guide block (401). The guide hole (4012) is aligned with the drill bit on the bench drill (101). The rotating shaft (4013) is fixedly mounted on the guide block (401).

4. The forklift lever head component processing device according to claim 3, characterized in that: The inclined drilling guide (4) further includes: a trimming guide ring (402) and a rod head bolt (403). The trimming guide ring (402) is fixedly installed on the guide block (401). The trimming guide ring (402) and the guide hole (4012) are concentric. Two rod head bolts (403) are threadedly connected to the guide block (401). The ends of the two rod head bolts (403) are respectively pressed against the edge of the rod head body (303).

5. The forklift lever head component processing device according to claim 3, characterized in that: The wear compensation component (5) includes: a compensation slider (501), a rotating mounting plate (502), and a drive screw (503). The inner side of the compensation slider (501) has an arc-shaped structure. The inner side of the compensation slider (501) is concentric with the guide hole (4012). The rotating mounting plate (502) is fixedly mounted on the compensation slider (501). The drive screw (503) is rotatably mounted on the rotating mounting plate (502). The drive screw (503) is threadedly connected to the guide block (401).

6. The forklift lever head component processing device according to claim 5, characterized in that: The compensation verification component (6) includes a rotating sleeve (601) and a verification rod (602). The rotating sleeve (601) is rotatably mounted on the rotating shaft (4013). The rotating sleeve (601) is located inside the guide block (401). The verification rod (602) is fixedly mounted on the rotating sleeve (601). The verification rod (602) is used to swing and verify the wear gap of the compensation slider (501).

7. The forklift lever head component processing device according to claim 6, characterized in that: The compensation verification component (6) further includes a ball bearing (603), wherein the end of the verification rod (602) is embedded with a ball bearing (603), and the ball bearing (603) is used to roll and fit against the arc surface at the end of the compensation slider (501).