Today's growing awareness of the negative effects of halogens releasing large amounts of smoke and toxic gases when exposed to flames has led to a growing demand for low smoke zero halogen cables (LSZH) in many industries. So what exactly is low smoke zero halogen cable?
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Low smoke zero halogen (LSZH) ethernet bulk cable is constructed with a halogen-free jacket material, providing a flame-retardant solution well-suited for safety-conscious environments. LSZH ethernet bulk cables come in extensive lengthscommonly up to 500 or feet. The LSZH jacket ensures minimal emission of toxic gases in the event of combustion. In particular, they release less than 0.5% hydrochloric acid (HCl) gas when exposed to fire. Additionally, the absence of polyvinyl chloride (PVC) in cable construction not only enhances fire resistance but also greatly reduces the potential for smoke production.
Benefiting from the characteristics of halogen-free, LSZH ethernet bulk cables are popular in Europe, since the European market requires cables used in LANs, WANs, etc. meet LSZH specifications. These cables indeed comply with IEC and the European flame retardant standard CPR, and their compliance solves customers' worries. So how exactly do LSZH ethernet bulk cables perform better than other ethernet bulk cables?
The following four main advantages prompt us to choose low smoke zero halogen bulk cables.
Good safety performance: Adopting a new type of special coating material that is non-polluting to the environment, almost no acid gases like HCL and less smoke are released when LSZH cables burned, so in those important application scenarios like data centers, they will effectively prevent damage to equipment that is susceptible to corrosion and smoke damage to a certain extent. Moreover, the smoke concentration is low and the visibility is high, thereby reducing the risk of fire hazards.
Good fire resistance: LSZH cables have good flame retardancy and high fire resistance. In addition, LSZH cables are self-extinguishing. When they are used in cabling scenarios such as data centers, their self-extinguishing characteristics can inhibit the spread of flames and protect the scene to a certain extent.
Environmentally friendly: LSZH cables use an environmentally friendly insulating layer, sheath, and special oxygen barrier materials, with no halogen elements nor heavy metal elements such as lead, cadmium, chromium, and mercury that are harmful to the human body and the environment. They will almost not cause environmental pollution and are healthy and relatively environmentally friendly.
Easy maintenance: LSZH cables have a lower friction coefficient than some non-low smoke and halogen-free sheaths, making subsequent maintenance and replacement easier.
Now that we learned the above advantages of low smoke zero halogen cables, benefiting from these advantages, what are the appropriate application scenarios of LSZH ethernet bulk cables?
To leverage their intrinsic properties, the most notable of which is their low emission of toxic gases and smoke, LSZH cables are ideally being implemented in environments where ventilation is scarce, population density is high, or air circulation is notably poor. In such scenarios, the dispersal of smoke and toxicants is hampered, rendering the use of cables containing halogenated compounds (such as those with PVC or FEP insulation) inappropriate and potentially hazardous.
Their elevated safety performance and reduced environmental impact render them exceptionally suited to enclosed public spaces, substantial commercial edifices, and data centers where network reliability and human safety are of utmost priority. LSZH ethernet bulk cables are a conscientious commitment to safety and sustainability in densely populated or poorly ventilated constructions.
Halogen elements constitute Group 17 of the periodic table and are comprised of fluorine (F), chlorine (Cl), bromine (Br), iodine (I), and astatine (At). These elements are characterized by their highly reactive nature due to their ability to gain an electron to achieve a stable noble gas electronic configuration. Halogens are excellent low-cost flame retardants, so sometimes halogenated flame retardants are added to cable polymers to reduce their flammability, the most common of which are PVC ethernet bulk cables.
LSZH bulk cables are conventionally not recommended for use in outdoor environments. Since they are not UV-resistant, waterproof, and weatherproof. When exposed to sunlight, moisture, and extreme temp, LSZH cables will become brittle and will largely shorten their lifespan. If there are outdoor application requirements, you are recommended to choose outdoor-rated ethernet bulk cable jacketed with a double-layer PVC and LEDP.
The main differences between LSZH and low smoke and fume cables (LSF) are materials, safety performance, and cost. LSZH cables use a halogen-free sheath and will not release toxic gases when burned. LSF cables use a resistant coating and modified PVC that still contain halogen elements and release toxic gases when burned. So LSZH cables have better safety performance. Given all this, it is recommended that you choose the appropriate cable based on your actual needs.
Explore QSFPTEK's comprehensive guide to armored fiber optic cables, including their uses, types, applications, and installation tips. Learn how armored fiber cables enhance durability and security in various networking environments.
Armored fiber optic cables ensure robust network infrastructures. Understanding armored fiber cables definition, structure, and applications is crucial for optimizing network performance. This guide explores types, applications, and considerations for selecting armored cables, empowering informed decisions in network optimization.
Understanding Armored Fiber Optic Cables
Armoured Fiber Cable Definition and Why Do We Need it?
Armored fiber cable is a fiber optic cable reinforced with additional protective layers to enhance its durability and resistance to external damage. These cables are designed to endure extreme environmental conditions, physical strain, and potential interference. The armor typically consists of materials such as steel or aluminum, providing a strong barrier against crushing, bending, abrasion, and rodent damage. So why do we need to use armored patch cords?
In the past, outdoor fiber optic cables were commonly placed within robust conduits to shield them from external forces. However, this approach was intricate and incurred considerable time and labor expenses. To address this, a protective metal armor was integrated around the fiber core within the cable, giving rise to armored fiber cables. These cables are engineered to endure strong pressure and stretching, making them ideal for rugged outdoor conditions. Furthermore, they provide enhanced flexibility in installation compared to conduit-based methods. Armored fiber cables have now become prevalent in the realm of optical communication.
Structure of Armored Cables
The structure of armored cables typically consists of several key components designed to provide enhanced protection and durability. These components may include:
Fiber Core: This is the central component of the cable, consisting of one or more optical fibers that transmit data signals in the form of light pulses.
Strength Members: Armored cables often incorporate strength members such as aramid fibers (e.g., Kevlar) or fiberglass rods. These provide additional support to the cable, enhancing its resistance to tensile forces and preventing elongation or deformation.
Armor Layer: The armor layer is the outermost protective sheath of the cable, typically made of metal such as steel or aluminum. This layer shields the cable from physical damage caused by crushing, bending, abrasion, or rodent gnawing. The armor may come in various forms, including interlocking metal tape, corrugated metal tape, or metal wire braid.
Outer Jacket: In some armored cable designs, an outer jacket may be added for further protection against environmental factors like moisture, UV radiation, and chemicals. The outer jacket is typically made of materials such as polyethylene (PE), polyvinyl chloride (PVC), or low smoke zero halogen (LSZH) compounds.
Armored VS Unarmoured, What is the Difference?
Armored fiber optic cables, as opposed to standard ones, feature internal stainless steel tubing for enhanced protection, offering greater resistance to compression and tension. Standard fiber optic cables typically consist of tight-buffered fibers, aramid yarn, and an outer jacket, whereas armored cables include an additional layer of stainless steel armor between the tight-buffered fibers and aramid yarn. This reinforcement significantly boosts the cable's ability to withstand lateral pressure without compromising its optical performance, preventing damage from mechanical forces. Additionally, armored cables are resistant to impacts and deter rodent gnawing.
Types of Armoured Cables
Categorization Based on Metal Tubing
Armored fiber optic cable comes in two main varieties based on the metal sheathing: interlock armored fiber cable and corrugated armored cable. Interlocking armor comprises aluminum, tightly wrapped around the cable helically, commonly used in indoor and outdoor cables. This design ensures durability and exceptional crush resistance. On the other hand, corrugated armor consists of a steel tape coated and folded longitudinally around the cable, primarily employed in outdoor cables to provide additional mechanical strength and protection against rodents. Both types of armored fiber cables facilitate installation in hazardous environments, such as those with high levels of dust, oil, gas, moisture, or rodents that could cause damage.
Classification Based on Installation Method
As previously discussed, armored fiber cables feature robust metal sheathing, making termination more challenging than standard fiber optic cables. Field-terminated armored fiber cables exhibit superior performance in certain outdoor settings, whereas many installers prefer pre-terminated options for indoor applications due to their efficient installation process and reliable signal transmission.
Moreover, the market offers primarily two types of pre-terminated armored fiber cables: armored fiber patch cables and armored fiber trunk cables. Armored fiber patch cables are sturdier and more flexible than traditional fiber patch cables, while armored fiber trunk cables consist of a length of armored fiber cable with multiple legs terminated with fiber optic connectors at each end.
Categorization Based on Applications
Armored fiber cables find utility both indoors and outdoors, catering to different installation requirements. Typically, there are two main variants: tight-buffered and loose-buffered armored cables. While both can serve indoor and outdoor purposes, loose-buffered types are predominantly preferred for outdoor settings.
Indoor Armored Fiber Cable:
Indoor applications usually employ armored cables comprising tight-buffered or loose-buffered variants, reinforced with strength members and an inner jacket. A spirally wrapped interlocking metal tap armor often shields the inner jacket for added protection.
Outdoor Armored Fiber Cable:
Outdoor armored cables, with prevalent loose-buffer designs, are engineered to ensure operational reliability in challenging outdoor conditions. They come in two versions: light armor and heavy armor.
Light Armored Cable:
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The light armor variant features a protective plastic jacket offering durability akin to stainless steel but with reduced weight. This makes it suitable for diverse applications ranging from interconnects to industrial setups and moderately harsh environments.
Heavy Armored Cable:
In contrast, the heavy armored cable is encased in a wire circle, providing robust protection against gnawing animals and damages, especially during direct burial installations. It finds application in environments like river beds and ocean floors.
Applications of Armored Network Cables
Where are Armored Fiber Optic Cables Typically Used?
Armored fiber optic cables are used in various applications where additional protection against physical damage or environmental hazards is required. Some common uses include:
Outdoor Installations: Armored fiber optic cables are often used for outdoor installations where they may be exposed to harsh weather conditions, moisture, and physical damage from rodents or digging equipment.
Industrial Environments: In industrial settings such as manufacturing plants or chemical facilities, armored fiber optic cables protect against mechanical stress, chemicals, and other hazards present in these environments.
Underground Installations: When fiber optic cables are buried underground, they are susceptible to damage from digging activities, rocks, or other objects. Armored cables provide an extra layer of protection against such threats.
Data Centers: In data center environments, where cable management can be complex and cables may be routed through tight spaces, armored fiber optic cables help prevent accidental damage during installation and maintenance activities.
How to Install Armored Patch Cords?
To streamline the process of handling armored fiber optic cable during installation, follow these steps to address potential challenges:
Bend and Separate: Begin by bending the armored cable approximately 10 inches from its end. Apply pressure with your hand to separate the coils of the armor. If manual force isn't sufficient, utilize pliers or an alternative cutting tool.
Twist and Release: Firmly grip the armored cable on both sides of the cut and twist until the armor coil separates, moving away from the wires. If necessary, employ two pairs of pliers for added leverage.
Trim Exposed Coil: Use side cutters to trim away the exposed coil of sheathing. You may need to maneuver the cutters back and forth to facilitate the opening and cutting process.
Wire Cutting: If you adjust the cable length, retract the sheathing and cut through the wires accordingly. Alternatively, discard any excess material after removing the waste piece.
Final Touches: Employ side cutters to remove protruding sharp edges from the sheathing. Eliminate the paper wrapping and any residual plastic strips for a clean finish.
How to Cut Armored Fiber Cables?
To cut armored fiber optic cables effectively and safely, you have several tool options at your disposal. The recommended choice is cable cutters specifically engineered for this purpose. However, if these are unavailable, you can utilize diagonal cutters or a hacksaw as alternatives. Follow these steps for precise and secure cable cutting:
Measure accurately: Determine the required cable length and mark the outer sheath at the designated cutting point.
Adjust blade depth: Ensure the tool's depth is appropriately set for cutting through the armor without damaging the inner components.
Secure in place: Position the cable within the wire guide of the cutter, aligning it precisely with the marked cutting point, and securely fasten it in position.
Execute the cut: With caution, proceed to cut the marked point.
Retrieve the cut cable: Once the cut is complete, carefully remove the newly cut section from the cutter, ensuring a clean and precise outcome.
Considerations for Selecting Armored Fiber Optic Patch Cables
When selecting armored fiber cables for your project, there are several key considerations to remember.
Environmental Conditions: Assess the environmental factors where the cables will be installed. Consider whether the cables will be exposed to extreme temperatures, moisture, chemicals, or physical damage. Choose armored cables with appropriate protective features to withstand these conditions.
Installation Environment: Evaluate the installation environment, including indoor or outdoor settings, and aerial, buried, or direct burial applications. Select armored fiber cables with suitable designs for the specific installation environment to ensure optimal performance and longevity.
Flexibility and Bend Radius: Consider the flexibility and bend radius of the armored fiber cables, especially if they need to be routed through tight spaces or around corners. Choose cables with appropriate flexibility and bend radius specifications to facilitate installation and minimize stress on the fibers.
Compatibility: Ensure compatibility with existing infrastructure, equipment, and connectors. Select armored cables compatible with standard fiber optic connectors, termination methods, and networking devices to streamline installation and integration with existing systems.
Cost and Budget: Evaluate the cost of armored fiber cables concerning your budget constraints. Consider the total cost of ownership, including installation, maintenance, and potential future upgrades or expansions. Balance cost considerations with the cables' desired performance, reliability, and longevity.
Conclusion
In summary, armored fiber optic cables offer resilient protection for network infrastructures against physical stress and environmental hazards. Understanding the features, applications, and types of armored fiber optic cables empowers informed decision-making during selection and installation. Consulting professionals and adhering to safety regulations are crucial for ensuring proper installation and optimal project performance.
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