Fiber Optic Patch Cords
Fiber optic patch cords are used to connect equipment. There are several considerations when selecting patch cables including panel location, housing design, panel capacity & port density and panel compatibility.
Single-mode cable has a blue connector on the end whereas multi-mode patch cables have LC connectors. It is also important to consider future expansion and scalability when choosing patch cord length.
Optical Fiber
Fiber optic patch cables have standardized connectors on both fiber-optic-patch-cord-cable-assembly ends and are used for connecting networking devices. They’re suitable for use in environments that require high-density cabling, like data centers and telecom rooms. The optical fibers in these cords channel light from a device to a receiver or a sensor.
The core of an optical fiber is a single, continuous strand of glass or plastic. It’s measured in diameter (in microns) to determine its capacity to transport optical signals, and it’s classified as either multimode or single mode based on the number of modes that can be transmitted. Multimode fibers have a larger core, so they can support multiple wavelengths over long distances. Single-mode fibers, on the other hand, have a smaller core and can only transmit a single wavelength over short distances.
A layer of cladding surrounds the core and helps to limit the loss of optical signals. The cladding is made from materials like Kevlat4, wire strands, or gel-filled sleeves. These materials help strengthen the core and protect it from crushing forces or excessive cable bends.
A buffer coating covers the cladding and the core. It’s also designed to prevent dust, dirt, and oils from contaminating the optical fiber. There are two types of buffer coatings, including aramid and polymer. The latter is typically used for fiber to the home applications, while aramid is preferred for outside plant and long-haul communications.
Connectors
The most critical components of a fiber optic patch cord are the connectors. They enable you to mate the patch cord to other fiber cable and equipment. These connectors are usually plastic or metal. They have a housing that holds the ferrule, which is an optical component that allows light to pass through it. The ferrule is a round or square shaped element that may be made of ceramic, metal, or glass. The cladding of the ferrule is coated with an abrasion-resistant material to protect it from damage.
The housing of the connector also has a crimp sleeve and strain relief boot attached to it. These two parts keep stress off the connector and ensure it is not damaged during installation. The crimp sleeve is made of a soft, lightweight multimode fiber optic cable assemblies manufacturer material, such as aluminum or brass. A technician compresses it with a crimping tool to create a mechanical connection between the sleeve and the connector. The sleeve provides tensile strength, pullout strength, and strain relief.
The most common type of connector used in fiber optic patch cords is the SC, which stands for Subscriber Connector. This connector has been in use since the 1990s and is commonly found in Datacom and telecom applications. It has a 1.25mm diameter ferrule and uses a push-pull connection, which makes it easy to use. Another popular type of connector is the LC, which was developed by Lucent Technologies to address criticism that SC and ST connectors were too large and easily dislodged. It has a smaller footprint than SC, making it the preferred choice in high-density patch applications.
End-Fittings
Fiber optic patch cables are terminated with connectors on both ends. These connectors allow the cable to be coupled with equipment, such as an optical switch, so that signals can be sent and received. They are available in single-mode and multi-mode options. They are also available in different colors, cable sizes and connector types. Other specialty options include polarization maintaining patch cords, node cable assemblies and mode conditioning patch cables.
Miami Stainless manufactures a variety of end-fittings for use with pipe systems in industrial applications. The most common type of end-fitting is the flange connection, which is used to connect the flexible tubing to the pipe. The flange provides a secure, durable connection that is easy to install and maintain. It is important to choose a flange connection that is compatible with the pipe’s diameter and pressure rating.
Other end-fittings include the coupling, cap and union. These fittings are typically used in smaller diameter pipe systems where more flexibility is needed. They are also used for connecting flexible tubing to other pipes, such as those used in chemical processes. They can be purchased in a range of materials, such as steel, stainless steel and brass. Some of these types of end-fittings are rated to withstand high pressure, while others are suitable for low-pressure applications. They can also be used with different diameters of pipes.
Cable Length
A fiber optic patch cord has connectors on both ends and can be a single-mode or multimode cable. They can be a few meters long or dozens of meters. Some cables are marked with different colors to mark polarity or they have a colored end-boot on the connector to indicate which side is connected to the hardware. The actual fiber is usually a glass or plastic optical fiber. Consumer-grade TOSLINK cables are a good example; they use plastic optical fibers for transmitting digital audio signals.
The transparent core allows light to travel through the cable with minimal loss. The aramid yarns and outer jacket strengthen the cable and minimize physical damage. Various jacket materials are used; some have a better chemical or UV resistance than others. The choice of a jacket material also affects how much the cable can be bent or twisted without increasing attenuation.
The fiber patch cord is pre-terminated with a connector at either end, allowing it to be rapidly and conveniently plugged into CATV, an optical switch or other telecommunication equipment in FTTH network constructions. They are also commonly used in data centers, enterprise networks, telecom rooms, server farms, cloud storage networks, and other high-density wiring applications. They meet Telcordias GR-326 and Rohs requirements.