Eight Steps to Determine the Right Rugged Connectors for Your Harsh-Environment Application
Rugged connectors are built for harsh-environment conditions. Both the internal and external components of rugged connectors are made to withstand challenging environments, including exposure to moisture or debris, shock and vibration, frequent mating and unmating, and even sterilization. These components aren’t one-size-fits-all; rugged connectors are built for a variety of applications, and requirements will vary depending on the operating environment.Get more news about Harsh Environment Connector,you can vist our website!
Because rugged connectors are often used in military, medical, transportation, and other harsh-environment applications where risk must be minimalized, a careful evaluation and selection process is paramount to success. Adding to that pressure is the increased demand for devices to transmit more data using smaller connectors. Consider all variables when specifying rugged connectors for an application.
To determine if you need a rugged connector, you must understand its intended function and the operating conditions it will endure. If the connector will be subjected to extreme temperatures, hazards ranging from water to dust and dirt, high mating cycles, or sterilization, it will need to be ruggedized. Rugged connectors are also critical for devices that have no margin for error.
Connectors can meet official industry standards through testing even if they don’t carry the official label. It’s up to designers to understand how a manufacturer specifies its connectors’ sealing specs, current ratings, and operating voltages. Review a product’s test standard to learn exactly how their testing was conducted.
The size of the contact, as well as the size of the wire, determine how much electrical current an individual contact can carry. The voltage rating is dependent on contact spacing, insulation materials, and the geometry of the insulator used to isolate the contacts.
When reviewing specifications, pay particular attention to the temperature rise specification, which indicates how much heat will be dissipated at a specific current value, and the compatibility of the contact with the conductor size. This information is critical to preventing overheating, which is a common cause of premature connector failure.Today’s technologically connected world places greater emphasis on data transfer capabilities. Devices must be able to transfer large amounts of data via both local networks and the internet while using specific protocols. In zero-risk environments, that pressure increases. Data transfer must be accurate and unencumbered when equipment and safety depend on it.
A two-part testing process will make absolutely sure you are getting the speed you need. Always test the connector and cable together in this process. The first round, conducted during the design phase, should use software to simulate the compatibility of the connector with the protocol. The second round should involve a physical prototype to test the connector and cable combination using a network analyzer. Your connector manufacturer may also be able to provide test data on recommended connector and cable combinations.
Rugged connectors are built for harsh-environment conditions. Both the internal and external components of rugged connectors are made to withstand challenging environments, including exposure to moisture or debris, shock and vibration, frequent mating and unmating, and even sterilization. These components aren’t one-size-fits-all; rugged connectors are built for a variety of applications, and requirements will vary depending on the operating environment.Get more news about Harsh Environment Connector,you can vist our website!
Because rugged connectors are often used in military, medical, transportation, and other harsh-environment applications where risk must be minimalized, a careful evaluation and selection process is paramount to success. Adding to that pressure is the increased demand for devices to transmit more data using smaller connectors. Consider all variables when specifying rugged connectors for an application.
To determine if you need a rugged connector, you must understand its intended function and the operating conditions it will endure. If the connector will be subjected to extreme temperatures, hazards ranging from water to dust and dirt, high mating cycles, or sterilization, it will need to be ruggedized. Rugged connectors are also critical for devices that have no margin for error.
Connectors can meet official industry standards through testing even if they don’t carry the official label. It’s up to designers to understand how a manufacturer specifies its connectors’ sealing specs, current ratings, and operating voltages. Review a product’s test standard to learn exactly how their testing was conducted.
The size of the contact, as well as the size of the wire, determine how much electrical current an individual contact can carry. The voltage rating is dependent on contact spacing, insulation materials, and the geometry of the insulator used to isolate the contacts.
When reviewing specifications, pay particular attention to the temperature rise specification, which indicates how much heat will be dissipated at a specific current value, and the compatibility of the contact with the conductor size. This information is critical to preventing overheating, which is a common cause of premature connector failure.Today’s technologically connected world places greater emphasis on data transfer capabilities. Devices must be able to transfer large amounts of data via both local networks and the internet while using specific protocols. In zero-risk environments, that pressure increases. Data transfer must be accurate and unencumbered when equipment and safety depend on it.
A two-part testing process will make absolutely sure you are getting the speed you need. Always test the connector and cable together in this process. The first round, conducted during the design phase, should use software to simulate the compatibility of the connector with the protocol. The second round should involve a physical prototype to test the connector and cable combination using a network analyzer. Your connector manufacturer may also be able to provide test data on recommended connector and cable combinations.