| Availability: | |
|---|---|
| Quantity: | |
| Material No. | [ M ]Material | [ S ]Surface Treatment | [ H ]Hardness | P Selectable | P Configurable | P, L, B Configurable | |||
| Type | D Tol. & Shape | Type | D Tol. & Shape | Type | D Tol. & Shape | ||||
| (1) | O1 Tool Steel Equivalent | — | Treated Hardness: 60~63 HRC min. | JPQ | SB m6 SPB p6 | JPQ | SA m6 SPA p6 SD m6 SPD p6 | FPQ | SA m6 SPA p6 SD m6 SPD p6 |
| (2) | O1 Tool Steel Equivalent | Chrome Plating | Hardness: 50~55 HRC min. Plating Hardness :750 HV min. | — | GJPQ | GFPQ | |||
| (3) | 304 Stainless Steel Equivalent | — | — | SJPQ | SJPQ | SFPQ | |||
| (4) | 304 Stainless Steel Equivalent | Chrome Plating | Plating Hardness :750 HV min. | — | HJPQ | HFPQ | |||
| (5) | 440C or 420 Stainless Steel | — | Treated Hardness: 50~55 HRC min. | CJPQ | CJPQ | CFPQ | |||
| (6) | O1 Tool Steel Equivalent | Buffed Surface | Treated Hardness: 60~63 HRC min. | — | MJPQ | MFPQ | |||
| (7) | O1 Tool Steel Equivalent | Chrome Plating + Buffed Surface | Treated Hardness: 50~55 HRC min. | — | MGJPQ | MGFPQ | |||
| (8) | 440C or 420 Stainless Steel | Buffed Surface | Treated Hardness: 50~55 HRC min. | — | MCJPQ | MCFPQ | |||

Frequently asked questions about this product (FAQ)
1. Will the positioning pins rust? If so, are there any measures to prevent it?
Positioning pins without surface treatment and non SUS3 series materials can rust. It is recommended to regularly apply rust preventive oil for maintenance or purchase positioning pins with surface treatment, which can prevent rust in normal atmospheric environments.
2. Why is there a undercut in the neck of the positioning pin?
Because of its high coaxiality, the neck also needs to be ground. The neck grinding process requires a back groove to ensure that the rib of the positioning pin does not produce an R angle.
3. Can shapes and sizes beyond the specifications recorded in the catalog be customized?
Can be customized with special attention. However, please provide drawings and have certain requirements for quantity when customizing. Details can be consulted jennyguo@fazcwj.com
4. Is a full inspection conducted during the quality management of positioning pins?
Strictly inspect each process link. And conduct a full inspection of the main process steps. Conduct a full inspection upon final shipment.
Introducing our high-quality Locating Pin, designed to provide precise positioning of your work piece with controlled and fine tolerance. Our locating pins are expertly crafted to ensure that your work piece is accurately aligned and secured in place.
Constructed from durable and reliable materials, our locating pins are built to last, ensuring that you can rely on them for a long time. Thanks to their top-quality design, they provide exceptional performance, allowing you to work with confidence and precision.
Our locating pins are perfect for a wide range of applications, whether you are working in the manufacturing, construction, or engineering industry. They are incredibly easy to use, making them a popular choice among professionals who demand the best in accuracy and quality.
So if you are looking for a reliable and high-performing locating pin, look no further than our product. With its exceptional features and exceptional performance, it is a must-have tool that will make your work easier, faster, and more efficient. Invest in our locating pin today and experience the difference for yourself!
Specifying fastening hardware in load-bearing environments carries incredibly high stakes. Mechanical failure is simply not an option. You rely on these components to hold massive structures and critical machinery together under immense stress.
Specify the wrong dimensions for a push button locking pin, and the assembly either fails to lock entirely or suffers from excessive axial play. This loose tolerance accelerates mechanical wear. The most common point of failure in procurement involves confusing "overall length" and "grip length."
Exacting engineering environments leave absolutely no room for guesswork. A fraction of a millimeter often determines whether an assembly holds under immense pressure or fails catastrophically.
In mission-critical applications—from aerospace rigging to medical structural supports—the failure of a quick-release fastener is not just a maintenance nuisance. It is a system-level vulnerability. Engineers often over-index on static shear strength when evaluating these components.
Industrial engineers often face a frustrating terminology paradox. You might hear procurement teams use hardware terms loosely. They ask for ball lock pins today. They ask for push button pins tomorrow. They assume these represent completely different fastening systems.
In precision industrial environments, every second of assembly time counts. Engineers require reliable, tool-less fastening solutions. You need components built for speed and absolute security. The push button locking pin meets this demand perfectly.
Manual fastening in high-vibration or load-bearing environments often forces a difficult engineering trade-off. Technicians must usually choose between maximum physical security and rapid operational speed. Traditional threaded fasteners require tedious manual tightening.
A push button locking pin acts as a critical failure point in high-load, fast-assembly environments. From aerospace assemblies and line array audio systems to heavy lifting and industrial Lockout/Tagout (LOTO) protocols, these small components carry massive operational stakes.
Push button locking pins appear as incredibly simple, reliable mechanisms at first glance. Yet, specifying the wrong pin compromises structural integrity, operator safety, and overall application efficiency. Even a minor oversight can lead to catastrophic system failure.
Selecting the exact right positive locking mechanism demands a rigorous balance. Engineers must weigh rapid manual actuation against sheer strength and environmental resilience. For decision-makers, the stakes remain incredibly high.
A push button locking pin is often a low-cost component. Yet, it frequently secures high-value industrial assets. Sizing errors carry severe operational consequences. They lead to excessive machine downtime. They cause mechanical binding during daily assembly.
Engineers constantly seek efficient ways to secure moving parts in complex assemblies. A push-pull spring plunger serves as a critical mechanical component for indexing, positioning, and locking these mechanisms seamlessly.
Engineers often drop a detent pin into a design blindly. You might expect it to handle whatever mechanical forces come its way. However, this assumption introduces severe mechanical risks.
Designing mechanical assemblies often hinges on a single, vital interaction point. You must perfectly match a spring plunger to its mating surface. This tiny engagement zone dictates the tactile feel and reliability of the entire mechanism.
Manufacturing thrives on absolute precision and repeatable actions. Engineers constantly seek reliable mechanical components designed to apply accurate, repeatable spring end-forces in tooling, fixtures, and automated machinery.
Repeatable precision in manufacturing, tooling, and product assembly depends heavily on minor mechanical components. They must function reliably over thousands of continuous cycles to prevent production halts.
In precision machinery and industrial applications, choosing the right mechanical locking or positioning component is critical for reliability, safety, and efficiency. Two common devices used for positioning and locking are indexing plungers and ball lock pins.
Indexing plungers are vital mechanical components used to secure, position, and lock movable parts in machinery, fixtures, jigs, and industrial equipment.
Custom indexing plungers are essential components in specialized machinery, industrial equipment, and precision assemblies.
Indexing plungers are essential mechanical components used across various industries to ensure precise positioning, secure locking, and repeatable alignment in machinery, fixtures, jigs, and other adjustable assemblies.