A high-quality crimp termination will usually exceed the service life of the product in which it is installed. On the other hand, a marginal quality crimp termination can cause electrical failures early in a product’s life. Since a high percentage of product failures can be traced to poor electrical connections, crimp quality is of paramount importance.
Many factors can affect crimp quality. Knowing the relevant factors, and to what extent each factor affects the end result, will help process engineers achieve the best possible results.
Quality In, Quality Out
The best place to begin the journey to improving crimp quality is to review the wire and terminal combination. The terminals must be made from quality materials and have very tight tolerances. Variation in material stock thickness will make monitoring in-process crimp quality more difficult. The window will be too wide.
Some terminals are rated to handle three or four wire sizes. Usually these terminals work well for the middle wire sizes, but the results are marginal for wire sizes at either end of the spectrum. For example, crimping a 24 AWG wire in a terminal rated for 20 to 24 AWG might not work as well as crimping a 24 AWG wire in a terminal rated for 24 to 28 AWG.
When loading a crimping press, handle the reels gently to prevent the terminals from getting bent. It will go a long way in improving how well the terminal is positioned over the anvil before crimping.
Pressing Matters
To obtain consistent high-quality results, you need a crimping press that provides a repeatable shut height under load and has a consistent crimping speed. These are fundamental criteria that should be held constant to prevent variation out of the crimping process.
The applicator tooling must provide a crimp that meets the manufacturer’s specifications for crimp height and crimp width. Check the crimp height and perform a pull test to determine if the crimped wire and terminal combination are within the terminal manufacturer’s specification.
Going one step further, a crimp micrograph is the best way to analyze what’s going on inside of the crimp barrel. It allows you to see voids due to under-compression; count strands; check symmetry; and take several other measurements that determine whether a crimped termination is acceptable or not. More and more, OEM’s require crimp micrographs (in addition to crimp height and pull tests) to verify and document these additional parameters.
Keep an Eye on the Process
Once you’ve checked crimp height, performed a pull test, and taken a micrograph, actual production can begin. The only way to monitor in-process quality is to use a crimp force monitor (CFM) to measure the force applied to each and every crimp. Many factors affect successful implementation of crimp force monitors, but that is beyond the scope of this article. I will mention that applicator and press quality play a huge role in CFM reliability and effectiveness. An applicator and press that are in poor condition will introduce variation (noise) that the CFM will see. This will reduce its ability to detect a good crimp vs. a bad one. The best way to ensure that your CFM has the best chance for success is to implement a regular maintenance plan for your crimping presses and applicators.
How can improving crimp quality increase productivity? The short answer is that by addressing all the factors that can reduce crimp quality up front, fewer defective crimps will be produced. In a fully automated machine, the CFM will detect whether a crimp is out of tolerance. If so, the machine will cut the crimped terminal off of the wire and eject the defective wire into the collection tray. This is done so operators cannot mix bad product with good product. The machine will make a new wire assembly to replace the defective one. This time and material spent for producing defective wire assemblies is a complete loss.
There is a cost for good crimping quality, and it requires an investment in high quality equipment and tooling as well as an ongoing preventive maintenance program. By building quality into the process and doing things right the first time, rejects and rework are reduced and productivity is greatly increased. In almost all cases, the return on investment for good quality is very short, and the dividends pay out indefinitely.
high-quality crimp termination will usually exceed the service life of the product in which it is installed. On the other hand, a marginal quality crimp termination can cause electrical failures early in a product’s life. Since a high percentage of product failures can be traced to poor electrical connections, crimp quality is of paramount importance.
Many factors can affect crimp quality. Knowing the relevant factors, and to what extent each factor affects the end result, will help process engineers achieve the best possible results.
Quality In, Quality Out
The best place to begin the journey to improving crimp quality is to review the wire and terminal combination. The terminals must be made from quality materials and have very tight tolerances. Variation in material stock thickness will make monitoring in-process crimp quality more difficult. The window will be too wide.
Some terminals are rated to handle three or four wire sizes. Usually these terminals work well for the middle wire sizes, but the results are marginal for wire sizes at either end of the spectrum. For example, crimping a 24 AWG wire in a terminal rated for 20 to 24 AWG might not work as well as crimping a 24 AWG wire in a terminal rated for 24 to 28 AWG.
When loading a crimping press, handle the reels gently to prevent the terminals from getting bent. It will go a long way in improving how well the terminal is positioned over the anvil before crimping.
Pressing Matters
To obtain consistent high-quality results, you need a crimping press that provides a repeatable shut height under load and has a consistent crimping speed. These are fundamental criteria that should be held constant to prevent variation out of the crimping process.
The applicator tooling must provide a crimp that meets the manufacturer’s specifications for crimp height and crimp width. Check the crimp height and perform a pull test to determine if the crimped wire and terminal combination are within the terminal manufacturer’s specification.
Going one step further, a crimp micrograph is the best way to analyze what’s going on inside of the crimp barrel. It allows you to see voids due to under-compression; count strands; check symmetry; and take several other measurements that determine whether a crimped termination is acceptable or not. More and more, OEM’s require crimp micrographs (in addition to crimp height and pull tests) to verify and document these additional parameters.
Keep an Eye on the Process
Once you’ve checked crimp height, performed a pull test, and taken a micrograph, actual production can begin. The only way to monitor in-process quality is to use a crimp force monitor (CFM) to measure the force applied to each and every crimp. Many factors affect successful implementation of crimp force monitors, but that is beyond the scope of this article. I will mention that applicator and press quality play a huge role in CFM reliability and effectiveness. An applicator and press that are in poor condition will introduce variation (noise) that the CFM will see. This will reduce its ability to detect a good crimp vs. a bad one. The best way to ensure that your CFM has the best chance for success is to implement a regular maintenance plan for your crimping presses and applicators.
How can improving crimp quality increase productivity? The short answer is that by addressing all the factors that can reduce crimp quality up front, fewer defective crimps will be produced. In a fully automated machine, the CFM will detect whether a crimp is out of tolerance. If so, the machine will cut the crimped terminal off of the wire and eject the defective wire into the collection tray. This is done so operators cannot mix bad product with good product. The machine will make a new wire assembly to replace the defective one. This time and material spent for producing defective wire assemblies is a complete loss.
There is a cost for good crimping quality, and it requires an investment in high quality equipment and tooling as well as an ongoing preventive maintenance program. By building quality into the process and doing things right the first time, rejects and rework are reduced and productivity is greatly increased. In almost all cases, the return on investment for good quality is very short, and the dividends pay out indefinitely.
