Data Cables
- High Quality Performance
- Multiple Length Options
- Competitive Prices
Data cable is designed for use in computer systems, allowing data transmission between multiple machines over a single network. It can also be used for Power Over Ethernet (POE) applications.
We offer a wide range of data cabling that perform at different transmission speeds to suit a variety of applications.
Benefits of using our data cable range include:
- High quality cable at competitive prices
- Highly secure, more so than wireless networks
- Minimal interference from electrical & radio frequencies
- High quality performance
- Provides consistent connection that will not be affected by data transmission
- Variety of foiled and armoured screen types to prevent crosstalk
- Data cables in the category include:
If you have any questions about our range of data cabling, please contact our team for assistance.
Does the Length of a Cable Affect the Speed?
Network speed is not significantly affected by the length of an ethernet cable, especially with current/recent cables and networks.Nonetheless, that does not mean you can attach one end of a data cable to one end of the world and the other to your device and think it will operate the same way as a connection to a nearby router.To put it another way, there is a limit to how long a cable can be. Although there is no set limit to the length of the cable, a long ethernet cable can result in a reduction in delay.What Is The Reason?The reduction is mostly due to the length of time a signal must travel through the cable. The longer the travel distance, the more likely there are to be interferences. That is extremely unlikely to be noticed, especially when comparing two wires.The impacts are barely evident until the wire get beyond 100m in length. However, the maximum bandwidth supported by your ethernet cable will have a big impact on this.For example:- Running a Cat 5 cable or Cat 5e for less than 100m – no speed change- Running the same cables for more than 100m – a speed drop Types of Cable and Their Maximum LengthsHere are the different types of cables:VGA cable – maximum length before a signal is lost or disrupted – between 10 and 15 mHDMI cable – maximum length before a signal is lost or disrupted – 15mUSB 2.0 – maximum length before a signal is lost or disrupted – 5mUSB 3.0 – maximum length before a signal is lost or disrupted – 3mCat5 and Cat6 ethernet cable – maximum length before a signal is lost or disrupted – 100mNormal fibre optic – maximum length before a signal is lost or disrupted – 10mQuality fibre optic – maximum length before a signal is lost or disrupted – 60mWhat Does Speed Mean?The often referred ‘speed’ in fact means signal strength – the amount provided over how long is a signal strength factor. After 100m, your signal strength will plummet because of bandwidth loss from signal loss throughout the length of the run, increasing noise from crosstalk, and leakage.ConclusionTo conclude, depending on the sort of ethernet cable you have, anything less than 100 to 110m in length will have an insignificant effect on your speeds. However, bear in mind that across long distances, latency will be increased.For more information on our range of data and ethernet cables, get in touch with our expert team!
Is Data and Ethernet Cable the Same?
Network cable is a broad phrase that covers a wide range of uses and types of data cable. Ethernet is a technique for connecting to a local area network. Any cable that allows you to connect to a system/device within a Lan may be called an ‘ethernet cable’ or a ‘network cable.’Ethernet CablesA system that is wired is an ‘ethernet’ connection, contrary to a wireless one (‘Wi-fi’). The most popular type of an ethernet cable is the Unshielded Twisted Pair (UTP). hyperlink to the article about the different types of data cables. This cable comes in a range of classifications, the most common of which is the Cat 5 cable.These cables have a lengthy progression from 10 to 100 megabytes, and later from 1 to 10 gigabytes. Certain data centres have even exceeded 40 gigabytes, and in some cases, 100 gigabytes.LAN CableLan cable is a type of data connection that is used in computer networking. It is designed to be used across short distances. It includes most types of coaxial cables as well as equipment with BNC or ethernet connectors. To connect or retrieve any data, these LANs utilise wired connections.Different characteristics of LAN cablesNetwork topology - it refers to the physical location of devices and the method by which a local area network is connected Media characteristics - it refers to the device's physical connection to the network Different LAN cables based on protocolsClient/server (two-tier) - made up of complex computers known as networks, which aid in the management of disc drives, printers, and network traffic, these LANs service personal computers, workstations, and aid in the execution of programmes Peer-to-peer – do not function well when subjected to high workloads – there is a limit on the number of computers they support and the distance at which they can transmit data What Are the Differences Between Ethernet and Data (Network) Cables?Range: Ethernet cable refers to network cables that are used in Ethernet contexts such as LAN, MAN, and WAN. It is typically used to refer to a copper or aluminium cable. However, network cable includes a wide range of cable types, such patch cable and glass optical fibre. Every connection used in a network is a network cable. Categorization: Present-day ethernet functions on twisted pair cables with a RJ45 connector. They come in a wide variety such as Cat5e, Cat6, etc. The concepts of ethernet and network cables are becoming increasingly similar as a result of the evolution of ethernet. Application: While ethernet requires a wired connection, network cabling does not necessarily – it can include both wired network, WLAN and Wi-fi. ConclusionThe category of network cable includes Ethernet cable. The term "ethernet cable" refers to a cable that is only used in an Ethernet context, whereas "network cable" refers to all cable types utilised in various network situations.For more information on our range of data and ethernet cables, get in touch with our expert team!
What is the Best Ethernet Cable for Networking?
Ethernet cables are a type of data cable. ‘Ethernet’ is the technique used for connection to a local area network, hence the origin of the name of the cables. Cabling is one of your network's most critical components.Which is the Best Data Cable?There are three major data cable types which can be categorised – Coaxial (copper), Twisted Pair (copper), and Fibre Optic (fibre).Those made from copper are typically more affordable but can reach up to 10GB rates while those made from fibre are more costly but faster and stronger when it comes to the signal deterioration. However, both options offer a superior data transmission.Your choice would be determined by your present network, future networking demands, and applications, which include bandwidth, distances, environment, cost, and other factors.Copper has traditionally been used in lower-speed, short-distance networks, while fibre has traditionally been utilised in higher-speed, long-distance networks. However, with the introduction of copper cable capable of 10-gigabit speeds, this maxim is no longer valid. A hybrid network with a fibre backbone and copper horizontal cable may be the best option.What to consider before you make a decisionThe cable you select will be influenced by the kind of network you wish to run. Calculate the maximum distance between the network and the farthest computer on your network Take into account the bend radius and the amount of space available for cable runs in the floor and ceiling. Check for any electromagnetic interference Check for any physical limitations that may affect the cable of your choice What is the Best Ethernet Cable for Networking?Ethernet cable specs can be complicated, and there are several factors to consider while selecting one, including the cable's length, category, and design.Whether speed is your primary priority or security is more important to you, the decision should be based on the cable’s category rating:Cat5eCat 5e cables carry fast connection and timely transmissions across long distance. They are also cost-effective compared to the others.Cat 6Cat 6 cables carry much faster data transmission speeds over longer distances. They also can reduce crosstalk – a disruption occurrence on your communication channels when the signal transfers.Cat 7Cat 7a cables have a double shielding which makes them more resilient to interference. They are much more modern and reliable for a Smart Home.For more information on our range of data and ethernet cables, get in touch with our expert team!
Does Data Move Through Cables?
Data transmission through cable follows the same principles as electricity transmission via a length of metal wire - data transmitted through a wire is turned into binary code - a series of 1s and 0s.The data-transmission device will send current over the wire at two distinct voltages (for example, 0V and 5V), with one voltage representing 1s and the other 0. The device receiving the information will read the current as binary code, which it will then convert back to the data's original format.What Flows Through A Wire?A current flows through the wire. That current essentially is flowing electrons. The electrons' speed is determined by the voltage supplied. Current and voltage are indivisible, meaning they cannot be separated. Because there is a voltage on the wire and a conductive channel from that voltage to a lower value, current is flowing.How Does A Fibre Optic Cable's Data Move Through Cables?Fibre optic cables operate in a similar way to other ethernet cables but rather than transmitting electrons down a wire, they send pulses of light. For instance, picture a torch switching on and off – when the light is on, transmitting data is 1, and when it is off, it is 0. Because light travels at a greater distance and speed than electrons, fibre optic connections can transfer significantly more data than copper wires. You can also find out more about the different types of data cables.ConclusionAlmost every business in today's digitised world depends on data flowing via cables. Data centres, telecommunications, industrial automation, financial services, healthcare, and emergency services all rely on data transmission across cables, often over long distances.This is often due to the fact that data travels faster and is more reliable over cables than it does over wireless connections – so in emergency services, where the speed with which data is delivered can literally save lives, a high-quality cable network is favoured over a wireless connection for data transfer.For more information on our range of data and ethernet cables, explore the range today or get in touch with our expert team!
Data Cable Types
Data cables are used to transmit electronic data from one location to another. Data cabling is either copper or fibre optics, and it is widely utilised in computer and communications systems.They can be classified into three major types:Coaxial cables (copper) Twisted pair cables (copper) Optic cables (fibre) Each has distinct properties that makes them identifiable.CoaxialCoaxial cable carries high frequency signals, and it is mostly used in older computer networks. These types of cable have a solid wire core conductor that is enclosed in an insulator and covered by a metal foil outer conductor. The circuit is completed by this outer conductor, and the entire cable is secured by a plastic cover.Though coaxial cables have a larger bandwidth, they have a far higher attenuation than twisted-pair cables. It's common in digital telephone cable wiring networks, where a single cable may transmit up to 600 Mbps of data.Coax cabling requires the use of a specific connection known as a BNC connector, which is used to connect the cable's end to a device.Twisted PairTwisted pair cables are primarily used for telecommunications and computer networks. They are made up of two copper cores that are twisted together, and each have their own plastic insulation – one carries the signal while the other is used as ground reference.The benefit of twisting is that external factors affect both wires equally. The twisting of the wires protects data transfers from signal deterioration. However, the typical length of a twisted pair cable before signal loss is around 300 feet.Types of Twisted Pair CablesUTP (Unshielded Twisted Pair) STP (Shielded Twisted Pair) cable – has one additional metal shield covering the insulated twisted pair conductors Fibre Optic CableFibre optic cables provide fast connections to the Internet via data signals in the form of light. They are primarily used in cable and telephony companies.The light channel consists of two major parts:Core Cladding – protective cover of the core Fibre optic cable is lightweight, and unlike the other two data connections, it does not suffer from signal deterioration. Fibre optic cable, on the other hand, is more costly and more delicate due to the glass sections of the cable.Types of ConnectorsSC connector – used for cable TV ST connector – used for connecting cable to networking devices Different Types of Connector for Data CablesRegistered Jack 45 (RJ45) – found in UTP & STP cables Straight Tip (ST) – usually found on the end of a multi-mode cable Subscriber Connector (SC) – found on Multimode and Single Mode optical fibre cables Lucent Connector (LC) – found on high-density deployments where multiple fibres would be terminated in a confined space Multi-fibre Push On (MPO) – duplex connector that was created with the intention of being able to be connected several times without causing any possible connection troubles What is the Most Used Cable Type for Networking?Unshielded Twisted Cable is the most popular and, in most cases, the best solution for LANs. In some situations, however, the Shielded Twisted Pair may be preferable.For more information on our range of data and ethernet cables, get in touch with our expert team!
Connecting Data Cables
Ethernet connections provide a better and more secure connection than wireless ones. The cables are also affordable, simple to locate, and utilise - one end is connected to your router, while the other is connected to the device.When you need extra length than a single cable can allow, instead of buying a longer cable, you may consider connecting two shorter ethernet cables.How to Connect Two Ethernet CablesTo connect two data cables (Ethernet) you can use a traditional RJ45 coupler. It is inexpensive and simple to use. The coupler has two ethernet ports, one on each end, in order to form one longer cable by bridging the gap between them.However, if more than one coupler is used, the signal may be degraded, or the strength of the connection could be affected. The alternative option is to re-size the cable by cutting it to the needed/required length, for which you will still need a coupler as well as wire cutters and a crimping tool.How to Cut an Ethernet Cable at the Ideal LengthStarting with a single lengthy cord is a simple and affordable approach to connecting ethernet cables. You may buy inexpensive cables in a variety of lengths; simply select the one that is long enough for your installation/arrangement.Another thing to consider is there are several types of data cable such as Cat 5e and Cat 6 cable – they function the same way but have different data transmission rates.Follow the guide below, to cut the cable in six simple steps:Step 1: Measure the length of the cable – do not cut the exact same length that you need, always leave a bit more and then clip it using the wire cutters Step 2: Strip off the protective outer jacket – using the crimping tool remove a few inches of it carefully not to damage the thin wires Step 3: Divide the wires – separate the four pairs of wires, when finished you should be left with eight individual ones instead Step 4: Put the wires in the correct order – there is an exact order in which the wires should be put- the most common method used is the T-568B: Orange/White > Orange > Green/White > Blue > Blue/White > Green > Brown/White > Brown.Step 5: Organise the wires - ensure that they are in the same order on both sides of the cable then press them together. When they are straight and there is no gap between them, cut off the excess, leaving approximately half an inch behind. Make sure you cut them straight down the middle and not at an angle. Step 6: Put the connector on - with the clip part of the connection facing away from you, carefully slip it over the wires. Each wire will be able to fit into a slot. When all the wires are at the connector's edge, push down on the RJ45 coupler using your crimping tool. How Many Data Cables Can RJ45 Couplers Connect?There is no limit on how many cables can be connected to RJ45 couplers. Nonetheless, the data transmission should be prioritised. Ethernet cables transmit connection to each other and having multiple couplers or/and cables will decrease both the quality and the speed of the connection.ConclusionCutting the length of a cable is probably the most reliable option for long-term use, but using connectors can be an easy, quick, and inexpensive fix.For more information on our range of data and ethernet cables, get in touch with our expert team!
Can you Repair a Cut Data Cable?
Fibre optic cable can be damaged, cut, or fractured by mistake. A major cause of optical fibre failure is backhoe fade, accidental damage which can cut or completely sever a data cable during digging.How to Repair a Broken Fibre Optic CableAn Optical Time Domain Reflectometer (OTDR) is required – it is used for measuring fibre length, transmission and joint attenuation, and fault localisation.Below is a step-by-step guide on how to repair a broken cable:Step 1: Use OTDR to locate the break – the reflectometer, mentioned above, works as a radar which sends a light pulse to the optical fibre cable Step 2: Cut the damaged cable using fibre optic cutters – dig up the fibre optic cable that is damaged after determining its location and then proceed to cut it out Step 3: Strip the cable using fibre optic stripper – strip it on both ends and peel carefully to expose the tube inside, cut any sheath and/or yarn Step 4: Trim the damage on the cable using high precision fibre cleaver Step 5: Clean the striped cable – it is important to make sure that you have a clean wire strip; use alcohol and lint-free wipes, once cleaned the fibre should not touch anything Step 6: Join the fibre optic cable back together – that can be done using two different methods, mechanical splicing or fusion splicing. Step 7: Carry out a connection test with OTDR After this, you’re done!Explore our range of data cables here, check out this guide to the types of data cable, or find a wholesaler near you today.
Core Materials Guide
In the majority of cases, the electrical cabling around your home or business will contain pure copper, or at least mostly copper wire.The properties of these cables can vary due to the sheathing or insulation used, but cables can also perform differently when their cores are made from alternative metals.Here are some of the most common core materials available.Pure Metal CoresCopperCopper is one of the highest standard materials used for electrical conductors. Although not quite as conductive as silver, copper is a far more economical and widely supplied material, making it the standard for most cabling applications.Sometimes, copper can be hard to solder unless a ‘flux’ is used – this is a compound used in the soldering process that cleans the surface in preparation for bonding. Using a flux can result in corrosive residues being left behind, so in some cases, copper will be tinned or plated to avoid this – see more about copper-clad cables below.Pure copper, however, is the gold standard of conduction and is suited for pressure terminations too. Copper is also incredibly malleable and can be bent into any shape or direction - although the sheathing material used can have limitations on this ability.AluminiumAluminium is favoured for cable conductors due to its lightweight nature. It is slightly less conductive than copper, but when balancing this with its weight, performs on a similar level.Aluminium is also relatively inexpensive, but cannot be soldered easily, so is often plated with copper to gain the benefits of both materials in a single wire.SilverSilver is an incredibly good conductor, better than copper in fact. It is, however, substantially more expensive. Silver-plated wire is more common, as it utilises the conductive benefits of silver and allows the wire to operate over a wide temperature range (from -65°C to 200°C).There are a few niche uses where silver’s extremely low resistance is a key element – scientific instruments and cryogenics may utilise pure silver conductors for this reason.GoldGold is a common form of plating for brass connector pins – though it’s not that commonly used for cables due to the expense of the materials.Easily soldered, gold has good corrosion resistance. It’s not as good a conductor as copper and silver, but resists oxidation far better, which is why it is used as a plated layer to protect some inner components.Tinned CableTin is generally not used on its own as a cable conductor, but is used as corrosion protection for copper without affecting its conductivity. Coating a copper cable in tin can also make it far easier to solder.Nickel-PlatedNickel-plated wire also operates in extreme conditions over a wide temperature range. If the nickel-plating is thick, it can withstand temperatures up to 750°C. Nickel also acts as an excellent layer of corrosion resistance.Metal Clad CoresCopper Clad AluminiumCopper clad aluminium cable is aluminium cable plated in copper. This makes the cable less expensive than pure copper, but lighter too, as aluminium in itself is an incredibly lightweight material.However, CCA cable allows the aluminium element to gain more electrical conductivity when combining this with copper, as well as adding to the strength of pure aluminium.Copper Clad SteelCopper clad steel is comprised of a steel wire plated with copper. As copper is more expensive than steel, it allows the cable to combine the benefits of both materials for a lower price.CCS cable is not quite as conductive as pure copper, but this level of conductivity is not needed in every application. Copper clad steel wire has double the mechanical strength of solid copper wire, giving it longevity in harsher environments and under frequent movement.For more information about our range of cables, get in touch with our friendly team.
Braiding vs Screening vs Shielding
Cables use screening and shielding to protect the cable and add resistance to interference from other cables or devices.Many people often get confused between braiding, shielding, screening and other terms, so we’ve made a handy guide to what all of these types of protection mean! Shielding or Screening?Shielding and screening are the same! They are both a protective layer added over the conductors to protect the cable from, or prevent it from causing, electrical interference. Disturbance can cause lower quality signal or data loss and can therefore result in equipment failure, therefore it is essential to choose the right screening for the right purpose.Shielding and screening come in many different forms, each with a specific purpose.Types of ShieldingBraidingBraiding is when cables are woven in a lattice of thin tin or copper wire, looking like a braid as the name suggests.The coverage of the braid (often referred to as the density) depends on the number of strands or wires within each plait. It also depends on the thickness of the braid strands. The diameter of the braid wires also specifies the level of damage the cable can withstand.Braiding is used for mechanical protection against any electrical or electromagnetic interference, as well as to add strength to the cable. Braiding is usually applied either over the inner sheath if there is one, or directly over the core bundle.Braiding can be applied in different materials for very specific purposes:Copper - used for screening against electromagnetic interference Steel - used for mechanical protection Glass or Ceramic fibres - used for high temperature environments Rayon - used for torsional strength Although braided shielding can be more costly and time consuming to produce, it is flexible and versatile, and performs well at all frequency types.FoilingFoil screening involves wrapping the cable cores in aluminium or polyester laminated tape to increase durability. The foils must be in contact with a bare wire to act as an earthing point.Foil shielding can offer up to 100% coverage and can withstand high-frequency applications. It's also quick, cost-effective and easy to produce due to its lightweight nature.However it is slightly less durable than traditional braiding, so it is not recommended to use foil shielding in areas where a lot of flex is needed.ArmouringArmouring is not a form of screening, but it is a common method of protection for cables. It is often constructed by winding galvanised steel wires over the cable in the form of a spiral.Armouring is often used when cables are to be laid in an outside environment - it prevents vermin and termites from attacking and damaging the cable.Though armoured cable can be less flexible and harder to terminate, there is no better way to protect a cable from this sort of interference.For more information about cable screening, get in touch with our friendly team, or shop our wide range of cables today.
Sheathing Material Guide
With a wide range of cable sheathing options available, it’s hard to know which is best for your installation.A range of factors from population density, temperature and flexibility can all impact your choice of cable.Take a look at our guide and find out all the benefits and drawbacks of the most common sheath materials on the market! PVCPVC, or polyvinyl chloride, is one of the most common sheathing options for cables. It’s low-cost to manufacture, as well as offering durability, flexibility and resistance to oil and water.PVC is suitable only for indoor use as it is vulnerable to UV light and can become brittle when exposed to bright sunlight. It gives off harmful halogen gases when burned, so is not suitable for densely populated buildings or in any situation where it may be exposed to fire.PEPE (polyethylene) is an excellent choice for outdoor cable installations, such as those involving direct burial. When UV stabilised, the material provides great resistance to moisture and extreme weather.PE is tough and rigid in comparison to other sheathing counterparts, and it does not burn but melts and reforms when cool, making it a safer option too. PE sheathing is commonly used for data transmission cables.RubberRubber is one of the most popular material choices for sheathing. It is waterproof, flexible and chemically resistant.Since rubber is more of a high-cost material, sometimes synthetic rubber compounds are used to mimic the effect without such a high price.Rubber sheathing is used when an installation requires water resistance and flexibility in extreme temperatures.LSFLSF stands for ‘Low Smoke and Fume’. This material is a modified PVC material that produces less gas and smoke than traditional PVC when the polymer is burnt.LSF sheathed cables do not meet the highest standard of fire safety (see LSZH cables) as they can still emit up to 22% Hydrogen Chloride gas, however they do meet further standards than standard PVC sheathing would (up to 28%).LSZHLSZH (Low Smoke Zero Halogen) cables are also known as ‘LS0H’ and ‘0HLS’ (Zero Halogen Low Smoke) are similar to PVC but behave differently in the event of exposure to fire.The main feature of these cables is that they do not release large amounts of toxic fumes or smoke when burned. Their fire retardance is much higher, making them often used in commercial or densely populated buildings due to their better quality and safety elements – anything they release is not harmful to humans when burned. This also means they conform to higher fire regulations than many other cables.SiliconeSilicone is a sheathing material that can operate from –50 to 180 degrees Celsius. It is resistant to heat, chemicals and even bacteria growth, making is a great choice for installations in food or medical environments.Silicone boasts UV resistance and does not produce any harmful smoke or gases when burned.This sheathing material is more expensive than most to produce and has limited options for recycling at its end of life, which doesn’t make it the best choice for everyday cabling. However, for specialist applications, its benefits cannot be beaten.PURPUR stands for polyurethane, a material that offers great chemical and mechanical resistance.PUR can be used in temperatures between –40 and 125 degrees Celsius. Some blends can be halogen free and flame retardant, but this depends entirely on the specific make up.Much like silicone, the material is resistant to bacteria growth and can therefore be used in food or medical-grade installations.PTFEPTFE, or Teflon, is a material used in applications that involve extreme temperatures or corrosive environments.Its benefits are that the material is non-toxic and environmentally friendly, as well as being flexible and non-flammable, making it a safe option for many installations.PTFE boasts thermal, chemical and electrical resistance. It can operate between –75 degrees Celsius and up to 200 degrees Celsius. It is also unaffected by most fuels, oils and fluids.FEPFEP is a fluoropolymer incredibly similar to PTFE, with similar benefits such as the ability to operate in extreme temperatures and low chemical reactivity.NeopreneNeoprene is a form of synthetic rubber. The sheathing material provides oil and chemical resistance, as well as strength and flexibility at lower temperatures.NylonNylon is an incredibly abrasive and chemically resistant material for sheathing, though less flexible that its counterparts.For more help or information regarding sheathing, get in touch with our team!
Smart Home Cabling & the Options Available
This article was first published on pewholesaler.co.uk on 16th January 2023. Click here for the original article.The Home Automation market is growing at a rapid pace. The demand for smarter homes, operated with home automation, is growing significantly. This is in part due to a rise in awareness of the smart home concept which has started being adopted globally, despite hampered growth levels during the COVID-19 pandemic.Did You Know?There are approximately 2.22 million smart homes in the UK! (Calculated by the number of households in the UK – 27.8 million – alongside the percentage of homes that own at least two smart devices, which is 8%, according to YouGov).What is a Smart Home?A smart home refers to an accessible home setup which allows homeowners to control appliances, thermostats, lights, and other devices remotely using a smartphone or tablet through an internet connection. For example, you can even use voice commands through Google Home or Amazon Alexa to complete basic tasks in your smart home.What is the Difference between ‘Home Automation’ and ‘Smart Home’?Home Automation is a system that allows your Smart Home to run automated services you may have set up. They will be pre-programmed by the user to deliver pre-defined preferences. The idea behind this, is that some things which you may do all the time on a routine basis should and can be fully automated. For example, with certain lighting, you might like it set to a preferred state which adjusts automatically to how you want it each time.Smart Home on the other hand, as mentioned can be controlled by the user via an app on their phone or by using an internet connection to connect to these devices, which in this context could be smart or dimmable bulbs.Why are Smart Homes Becoming More Desirable?An automated home, either fully or in part, provides numerous benefits to its user. This includes enhanced security for the protection of theft, protection from unauthorised access to the user’s home and the evolving need for energy-efficient solutions. For these reasons it’s no surprise that the market is gaining traction, particularly in the residential and commercial sectors in order to protect both personal and business-related assets.There’s been an increase in demand for home monitoring from remote locations. In line with technological advancements, the adoption of smart devices and growing number of smartphone and internet users worldwide are all contributing factors.Smart home statistics show that the global household penetration of products stood at 7.2% in 2019, according to Statista. This figure is reportedly set to increase to 16.7% by 2023, which is more than double and there’s certainly room for further growth.What is the Most Commonly Used Smart Home Product in Britain?According to YouGov, smart meters are the most commonly used smart home product in Britain. However as these are free, it is noted that smart speakers are the most popular smart home device by physical purchase, with 11% of consumers owning one. Among them, 69% chose the Amazon Echo, while a comparatively small 19% opted for Google Home.The Key Role Specially Developed Cabling can Play…This leads us to discuss Smart Home cabling and the options available. Securi-Flex® stock a vast range of cables suitable for smart homes, which includes but not limited to: Audio Speaker Cables, Smart Lighting, Blind Control, Access Control (Purple Pipe), Networking and high-speed data, Home Surveillance, Fire Alarm, Security Alarm, HVAC Control, Belden and KNX Equivalents (also known as EIB cable), which is ideal for smart buildings and building utility systems.Let’s take a closer look at some of these cables! Securi-Flex® stock a Composite Access Control Cable, also known as Purple Pipe. Specifically designed for proprietary access control systems, these cables are broadly used in public buildings where security and safety are important. It’s a cost-effective security solution that’s less labour-intensive and provides easy-identification features for a new level of ease and convenience to any installation.Commonly known as KNX cable, we also stock an EIB Bus equivalent which features two twisted pairs of solid conductors with a foil screen and tinned copper drain wire. This cable has a distinctive sheath which is green in colour and Low Smoke Zero Halogen. The KNX/EIB cable has exceptional capabilities for electrical and shielded communication performance, which enables use for Intelligent Building Control, Lighting, Heating, Ventilation, Air Conditioning, Blinds, Time Management and Locking Systems. This is used to build intelligent building control solutions for domestic and commercial applications resulting in control of the users everyday working or living environment.The Securi-Flex® Home Automation range also includes structured data networking cables, which enable multiple devices to share connection of internet and media over Cat 5E, Cat 6, Cat 6A, Cat 7A and even Cat8. Streaming HD for example requires cabling that can provide fast and accurate data transmission. Using a high-quality, high-performing data cable is important!DALI (Digital Addressable Lighting Interface) is a standard international Communication Protocol, a global standard for dimming and digital lighting control. DALI cables are versatile, easy to install and a cost-effective lighting control solution.LonWorks (Local Operating Network) is regarded as the world’s Leading technology for building services devices. Devices are installed in a variety of Sectors including motorway lighting, lighting control, HVAC Systems, Security Systems & many more. Our ‘SFX/USP1-16’ for example is available in LSZH Grey and Black PE Duct Grade – It has two 16 AWG cores and unscreened composition.Hybrid Data, Communication & Control Cables are also available which work with Speciality Lighting Systems for efficient control of artificial light. Often referred to as 1502R or Lutron equivalent, we can offer our ‘SFX/USP16-OSP22-LSZH’ from stock, which is the ideal solution to these systems to allow custom configuration by the owner to create their own lighting settings. Whereas Lighting Control Bus Cables are intended for communications between the lighting distribution board, lighting control modules and luminaire plug wiring. Colour coded sheath compounds are provided for the ease of identification between lighting control wiring and Dali Bus Installation. These are often referred to as E-BUS, M-BUS, O-BUS and T-BUS.Please contact Securi-Flex® with your Home Automation and Smart Home cabling requirements; We’ll be sure to have a solution for your intended applications!
Enhancing Safety - LSF vs LSZH
Understanding The Key Differences Between LSF and LSZH Cable Sheaths:In the intricate realm of the electrical industry, safety remains an unwavering priority.Amongst the many components that contribute to safety, cable sheaths play a crucial role in containing potential hazards during fire incidents.Two essential terms commonly used amongst the electrical industry are "LSF" (Low Smoke and Fume) and "LSZH" (Low Smoke Zero Halogen).While they may appear similar, it is crucial to understand the difference and purposes of each cable sheath material.Securi-Flex® knows it's important to understand the differences between the two materials. In this article, we'll examine these differences more closely.LSF Cables:Manufacturers produce LSF cables using a modified PVC compound that produces less HCL gas and smoke than regular PVC cables. LSF cables create between 15-22% of HCL gas and emit black smoke because of the presence of PVC. It is vital not to confuse LSF cables with LSZH cables, as LSF cables do contain halogen materials. They are often chosen as a cost alternative to LSZH, however they should not be confused with LSZH cables. They are not recommended for use in public or commercial buildings, as well as poorly ventilated areas. LSZH Cables:LSZH cables are manufactured using halogen-free compounds. They are effective fire retardants while emitting less than 0.5% hydrogen chloride gas and smoke when burned. During a fire, LSZH cables produce small amounts of light grey smoke and HCL gas. The absence of PVC in LSZH cables ensures no harmful fumes or black smoke are emitted during the event of a fire. Ideal for public buildings such as airports, railway stations (London Underground), computer rooms, and data centres. Low smoke generation ensures evacuation routes and signage remain visible during emergencies. Choosing the Right Cable:The choice between LSF, and LSZH cables depends on the fire risk, flexibility needs, and safety considerations.LSF cables offer a slight improvement over PVC cables but can still emit toxic gases and dense black smoke.However, LSZH cables reduce emissions and experts recommend them for high-risk areas.The CPR categorises cables by fire performance, however it doesn't cover toxic fumes and smoke.Installers must carefully choose cables appropriate for the specific fire risks in a building or application.In Summary:Understanding the differences between LSF and LSZH cables is vital for making informed decisions that prioritise safety in different scenarios.While LSF cables can offer cost advantages, they may not be suitable for critical areas, where LSZH cables are strongly recommended to ensure a safer environment during the event of a fire.Choosing the right cable can significantly contribute to enhancing overall fire safety and exposure.If you have any questions that weren't answered in this article, please do not hesitate to get in touch with our friendly team.We're always happy to help!
Bridging the Gap Between Legacy Systems & Modern Technology
RS232 Systems:In the ever evolving world of technology, the role of RS232 cables might seem like a thing of the past.However, these type of cables play a vital role in bridging the gap between legacy systems and today's cutting-edge technologies.Understanding RS232 Cables:RS232 cables, also known as serial cables, have been used for communication protocols since the early days of computing.They are designed to transfer and receive data between devices, using a series of electrical pulses through a serial port.The RS232 standard defines the voltage levels, signalling, and pin configurations for these cables, making them compatible with various data communication equipment.The Role of RS232 Cables in Legacy Systems:RS232 cables served as a lifeline for legacy systems, enabling communication between devices that lacked modern interfaces such as USB or Ethernet.They found extensive use in connecting computers to peripherals like modems, printers, and serial devices.Many industrial systems and scientific instruments also relied on RS232 connections to transmit data.Integration and Adaptation - RS232 to USB:As technology progressed, new interfaces such as USB and Ethernet began to dominate the scene, rendering RS232 seemingly outdated.However, rather than fading away, RS232 cables adapted to the changing environment. One significant adaptation is the introduction of RS232 to USB converters or adapters.RS232 to USB adapters offer a bridge between legacy devices with RS232 ports and modern computers with USB interfaces.These adapters convert the RS232 signal to USB, allowing older devices to seamlessly communicate with the latest technology.This integration has proven crucial for electronic industries that continue to use legacy systems, as it prevents costs & disruption.Modern Applications of RS232 Cables:RS232 cables have found a place in a range of modern applications, proving their versatility and reliability within advancing technology.Some modern applications of RS232 cables include:Networking Equipment Configuration - Many networking devices, such as routers and switches, feature RS232 ports for configuration and management purposes. Network administrators use RS232 cables to send data for setting up and troubleshooting these devices. Industrial Automation - Industries with established processes often operate on legacy systems that rely on RS232 communication. RS232 cables are used to interface with programmable logic controllers (PLCs), human-machine interfaces (HMIs), and other industrial equipment. Serial Communication for Specialised Devices - Some devices and instruments require serial communication due to their specific data transfer needs. RS232 cables remain a preferred choice for such applications, where a simple, robust connection is essential. RS232 Connectors in Modern Devices:Despite more advanced communication interfaces, RS232 ports can still be found in some modern devices.While they may not be as common as USB or Ethernet ports, certain industries and devices prefer RS232 connectors for their distinct advantages, such as immunity to electromagnetic interference and reliability over long distances.Conclusion:RS232 cables have shown adaptability, to remain relevant in today's technology landscape.From playing a critical role in legacy systems, to seamlessly integrating with modern devices through RS232 to USB adapters, these cables continue to be a reliable bridge between the past and the future of data communication.Their application in networking equipment configuration, industrial automation, and specialised devices outlines their continued importance in various sectors.As technology continues to evolve, RS232 cables will likely persist as an enduring and essential component of data communication solutions for years to come.Securi-Flex® stock a range of Belden Equivalents which are suitable for RS232 Applications.If you have any questions that weren’t answered in this article, please do not hesitate to get in touch with our friendly team.We’re always happy to help!
Choosing the Right Connectors for Data Cables
The importance of the Right Connectors for Data Cables: A Wise Business DecisionData cables are the backbone of modern communication and information transfer.From homes to offices, data cables play an integral part of our daily lives, ensuring seamless connectivity and swift data transmission.However, amongst the complex web of data cables, connectors play a pivotal role.Choosing the right connectors for your type of data cable connections is important to ensure efficient and reliable communication. A range of the most common connectors for data cables include:RJ45 Connection (for Ethernet Cabling) LC, SC & ST Connectors (For Fibre Optic Cables) USB Connectors Mitigating human error through informed decision-making and careful consideration is vital when selecting suitable connectors. Understanding the SignificanceData cables serve as the conduits through which information flows, connecting devices, networks, and systems.Data cables ensure reliable flow of data, including emails and financial transactions, without any interruptions or loss.Yet, the true hero behind this seamless transmission is the connector.RJ45 Connectors, designed for Ethernet Cabling, serve as the gateway that joins data cables together. They ensure a secure and stable link, enabling data to move from source to destination.Similarly, LC Connectors offer high precision connections, allowing for reliable data transmission over longer distances.SC & ST Connectors are used in demanding environments, these connectors are known for their durability in Fibre Optic setups.USB Connectors facilitate versatile data transfer across various devices and therefore are a popular choice in modern data connectivity.The quality of this connection impacts the overall performance of the data cables.Making the right connector choice an important aspect of the full setup. Reliability and DurabilityData cable connections can be vulnerable to external factors like environmental conditions, physical strain, and electromagnetic interference (EMI).Choosing connectors that are built to withstand these challenges is vital to maintain reliable connections. An ill-fitting or subpar connector can lead to signal loss, slow data transfer rates, and even complete connection failure.The RJ45 connection, a standard for Ethernet cabling, is renowned for its robust design. Its locking mechanism ensures a secure fit, reducing the chances of accidental disconnections. This durability translates to a longer lifespan for the data cable connection, minimising maintenance and replacement costs.LC connectors, SC connectors, and ST connectors for fibre optic cables also boast resilient designs that preserve connectivity in challenging settings. Maximising Data Transfer SpeedsWhether it's streaming high-definition videos or transferring large files, the speed of transferring data is a critical factor.The choice of connectors can significantly impact these speeds.A high-quality connector, specifically designed for data cables, ensures minimal signal degradation, leading to faster and more efficient data transmission.Connectors optimised for communication, such as RJ45 for Ethernet and LC connectors for fibre optics, provide reliable gigabit data transfer speeds.This is crucial in locations with high-speed networks. Examples include offices with numerous devices connected to a central server or data centres that transmit large amounts of data. Maintaining Signal IntegrityThe referential integrity of the data source being transmitted is of utmost importance.Connectors that provide strong contact points and shielding mechanisms help maintain signal integrity, reducing the risk of data corruption and errors.Inadequate connectors can introduce noise and interference, leading to compromised data quality and accuracy.RJ45, LC, SC, and ST Connectors are designed with signal integrity in mind. Their shielding helps protect against EMI, ensuring that the data set remains intact and uncorrupted during transmission. Compatibility of ConnectorsThe technology landscape is constantly evolving, with a myriad of devices and systems requiring seamless connectivity.Choosing connectors that offer compatibility is essential to ensure a hassle-free data cable connection experience.RJ45 connectors are a standard interface and widely supported across various devices and networks, making it a versatile choice. Similarly, LC, SC, and ST connectors are industry standards in fibre optic networks, ensuring seamless data transfer across diverse systems. Streamlining Data Centre ConnectivityIn data centres, where efficient communication is critical, the right connectors play a pivotal role in streamlining operations.Whether it's high-speed Ethernet connections, rapid fibre optic data transfer, or USB connectivity, well-chosen connectors ensure that data centres function smoothly, reducing downtime and enhancing overall performance. A Wise Business DecisionThe strategic significance of choosing the right connectors extends beyond technical considerations.It is a business decision that can impact productivity, efficiency, and cost-effectiveness.Choosing high-quality connectors demonstrates a commitment to reliable communication and data transfer.This, in turn, can enhance customer satisfaction, improve internal processes, and foster a competitive edge. ConclusionIn the intricate web of data cables, connectors enable efficient and reliable communication across a wide range of technologies.Different connectors like RJ45, LC, SC, ST, and USB affect data transfer speed, signal quality, and system performance.Choosing the right connector for data cables is both a technical choice and a strategic decision. This decision has the potential to enhance connectivity.Investing in the right connectors for networks and data centres keeps data flowing quickly, securely, and without interruption. If you have any questions that weren’t answered in this article, please do not hesitate to get in touch with our friendly team.We’re always happy to help!
Choosing The Right Data Cables
A Guide for Your Specific Data Cable NeedsIn today's electrical world, data cables play a crucial role in enabling seamless communication and efficient data transfer.Understanding the important factors for selecting the correct data cable is crucial when creating a home network, office, or data centre.It is important to consider these factors in order to ensure the efficiency and reliability of the network. Without a proper understanding of these factors, the network may experience issues such as slow speeds, frequent disconnections, and data loss.Therefore, it is essential to research and choose the appropriate type of data cable that meets the specific requirements of the network. This guide will walk you through key considerations such as;Data transfer speed requirements. Length of cable limitations. Environmental factors. Compatibility with networking equipment. Additional cable categories, to help you make an informed decision for your specific applications. Data Transfer Speed RequirementsThe first step in choosing data cables is assessing your data transfer speed requirements.Different data cable types offer varying speeds, and understanding these options is crucial:Cat5e CableCat5e is ideal for basic network setups with data transfer rates up to 1 Gbps (Gigabit per second). Widely used for home networks, small offices, and general data applications. Delivers a Maximum Performance of 100Mhz. Cat6 CableProvides higher bandwidth with data transfer rates up to 10 Gbps. Cat6 is suitable for demanding applications and future-proofing your network. Commonly used in business environments and small to medium-sized data centres. Delivers a Maximum Performance of 250Mhz. Cat6a CableSupports data transfer speeds up to 10 Gbps over longer distances. Suitable for larger network infrastructures and data centres. Cat6a is well-suited for high-performance applications and environments with higher bandwidth requirements. Delivers a Maximum Performance of 500Mhz. Cat7 & Cat7a CablesThese cables offer even higher data transfer speeds, reaching up to 10 Gbps and 40 Gbps, respectively. Designed for specialised applications that demand ultra-fast data transmission. Cat7 & Cat7a is Suitable for use in data centres, high-performance computing, and industrial settings. Delivers a Maximum Performance of 1000Mhz. Cat 8 CableOffers lightning-fast data transfer speeds up to 25 Gbps or even 40 Gbps. Specifically designed for high-performance data centres and enterprise applications. Cat 8 cables are becoming increasingly popular for data-intensive tasks and large-scale networking requirements. Delivers a Maximum Performance of 2000Mhz. Understanding your data speed needs and the capabilities will help you choose the most suitable option for your specific applications. Length of Data Cable LimitationsData cables have length limitations, beyond which signal degradation can occur.It is essential to consider the distance between devices and the networking equipment when choosing the right cable.Cat 5e, Cat 6, and Cat 6a cables can reliably transmit data up to 100 metres. These cable categories are well-suited for most applications within a building or office environment.Cat 7 and Cat 7a cables, designed for specialised applications, can also transmit data up to 100 metres.Cat 8 cables however, have a higher data transfer speed and are therefore designed for shorter distances, typically up to 30 metres in length.For longer distances, you may want to consider using appropriate signal boosters or fibre optic cables, which offer longer transmission distances whilst maintaining performance.Fibre optic cables, in particular, can transmit data over much greater distances, making them suitable for longer networking and connections between different buildings. Environmental ConsiderationsEnvironmental factors can significantly impact the performance and durability of data cables.You will need to consider the following environmental aspects when choosing suitable data cables:Indoor vs. Outdoor UseChoose cables rated for either indoor or outdoor use, depending on your installation requirements. External cables, typically manufactured using polyethylene are designed to withstand exposure to harsh weather conditions, UV radiation, and other environmental factors. There are a range of internal sheathed data cables such as PVC & LSZH which can be used within different installation environments. Temperature and HumidityVerify that the chosen cables can operate within the temperature and humidity range of your installation environment. Extreme temperature variations or high humidity levels can affect cable performance and longevity. Chemical and Oil ResistanceFor industrial or specialised applications, consider cables with enhanced resistance to chemicals and oils. These cables are designed to withstand exposure to harsh chemicals or oil spills, ensuring continuous data transmission in demanding environments. Compatibility with Networking Equipment:Ensure that the selected data cables are compatible with your networking equipment, including switches, routers, and network adapters. Most modern networking equipment supports a wide range of cable categories, but it is essential to verify compatibility for optimal performance. Using cables that match the capabilities of your networking equipment ensures smooth and reliable data transmission. Shielding and Crosstalk:Shielding is an essential consideration, especially in environments where electromagnetic interference (EMI) or radio frequency interference (RFI) is present.Shielded cables, also know as FTP (Foil Twisted Pair) and SFTP (Shielded Foil Twisted Pair), are designed to reduce external interference, minimising crosstalk and signal loss.These cables are commonly used in industrial settings, data centres, and areas with high levels of electrical noise.Unshielded cables, also known as UTP (Unshielded Twisted Pair), are suitable for most residential and office environments, where the likelihood of interference is lower.If you plan on running data cables near power lines, machinery, or other sources of interference, you will need to consider using shielded cables to ensure reliable data transmission. Cost and Budget ConsiderationsWhile it's essential to choose data cables that meet your performance requirements, cost considerations also play a role in the decision-making process.Cat 5e cables are generally the most budget-friendly option, making them a popular choice for basic home networks and small offices. Cat 6, Cat 6a, and Cat 7 tends to increase the cost due to higher performance capabilities and construction quality. Cat 8 Ethernet cables are currently the most expensive option due to their cutting-edge technology and lightning-fast data transfer speeds. Before making a decision, carefully evaluate your data speed and performance needs to strike a balance between performance and budget. Application-Specific ConsiderationsDifferent applications have unique data cable requirements based on their specific demands and constraints.Here are some application-specific considerations to keep in mind:Data CentresData centres demand high-performance data cables capable of handling massive amounts of data and ensuring minimal data loss. Cat 6a, Cat 7, and Cat 8 cables are popular choices in data centre environments, where efficiency and reliability are critical. Industrial EnvironmentsIndustrial settings often present challenging conditions, such as high temperatures, vibrations, and exposure to chemicals. Shielded cables with enhanced durability are well-suited for industrial applications, ensuring reliable data transmission in adverse environments. Home NetworksFor typical home networks and casual internet usage, Cat 5e cables are generally sufficient. If you have multiple devices connected to your network or engage in data-intensive activities such as gaming or media streaming, upgrading to Cat 6 or higher can provide a noticeable improvement in performance. Office EnvironmentsIn office settings, Cat 5e and Cat 6 cables are commonly used due to their cost-effectiveness and ability to support typical office applications. ConclusionChoosing the right data cables is critical to achieving efficient and reliable data transmission in any network setup.By carefully considering factors such as data transfer speed requirements, cable length limitations, environmental factors, compatibility with networking equipment, shielding and crosstalk considerations, cost and budget constraints, and application-specific needs, you can make an informed choice that meets your unique data connectivity requirements.Whether you are building a home network, expanding an office infrastructure, or designing a data centre, the right data cables will ensure seamless communication and enhanced productivity.By staying informed about the latest advancements in cable technology and understanding the unique demands of your applications, you can future-proof your network and ensure it remains reliable and efficient for years to come.Remember to consult with experienced network professionals or cable experts to get personalised advice based on your specific needs and circumstances.In conclusion, investing in high-quality data cables that match your network requirements is an essential step towards building a robust and reliable data communication infrastructure.By following the guidelines in this comprehensive guide, you can make an informed decision that optimises data transfer speeds, supports future growth, and enhances overall network performance.If you have any questions that weren’t answered in this article, please do not hesitate to get in touch with our friendly team.We’re always happy to help!
Ensuring Safe and Compliant Electrical Installations
CPR and BS6701:2016+A1:2017Construction Products Regulations (CPR):The Construction Industry has witnessed significant advancements in electrical systems and technology. This in turn has led to safer and more efficient electrical installations.Various standards and regulations govern these advancements in the United Kingdom and across the European Union.Two crucial standards that play a pivotal role in ensuring electrical safety and compliance are:Construction Products Regulation (CPR) British Standard BS6701:2016+A1:2017 What is CPR?CPR, or the Construction Products Regulation, is a European Union (EU) Regulation that came into effect in 2011.The primary purpose of CPR is to harmonise the performance requirements for Construction Products, including cables, within the EU Member States.CPR Categorises Construction Products into different classes based on their performance characteristics. This Classification helps ensure that products meet specific safety and performance standards. Application to Cable Types:One of the most critical applications of CPR is in the Classification and regulation of cables used in buildings and infrastructure.CPR sets clear requirements for fire safety and reaction to the fire performance of cables. Key Elements of CPR for Cables:Cable Classification - CPR classifies cables based on fire performance. These classes range from Aca (the highest level of fire safety) to Fca (the lowest). The Classification depends on criteria such as heat release, flame spread, and smoke production CE Marking - Cables that comply with CPR must carry the CE Marking. This indicates that the product meets required standards and is safe for use in Construction Declaration of Performance (DoP) - Manufacturers have an obligation to furnish a Declaration of Performance (DoP) for their cables. A DoP details essential information such as Product Classification, intended use, and fire performance characteristics What is BS6701:2016+A1:2017?British Standard BS6701:2016+A1:2017 is the UK standard that provides recommendations and requirements for telecommunications cabling infrastructure within buildings:Planning Design Installation Testing Maintenance While it primarily focuses on telecommunications cabling, it also addresses key aspects of electrical safety in relation to cabling installations. Key Elements of BS6701:2016+A1:2017 Structured Cabling:The standard highlights the significance of structured cabling systems by stressing the need for organised, documented, and maintainable cabling installations.Safety: BS6701:2016+A1:2017 includes safety requirements for cabling installations to reduce the risk of electrical hazards.This includes proper grounding, bonding, and protection against overcurrent.Compliance: Compliance with this standard is critical for telecommunications cabling installations, as it ensures network performance, reliability, and safety. The Intersection of CPR and BS6701:2016+A1:2017While CPR and BS6701:2016+A1:2017 primarily address different aspects of construction products and installations.Cables used for data and telecommunications transmission are subject to:CPR Classification for fire safety BS6701:2016+A1:2017 for structured cabling requirements In the construction industry, electrical and cabling installations play a vital role in ensuring safety, efficiency, and performance. CPR and BS6701:2016+A1:2017 are integral standards that guide the design, installation, and maintenance of cables and cabling infrastructure.Compliance with these standards is a legal requirement, and a crucial step in ensuring the safety and reliability of electrical and telecommunications systems.As technology continues to advance, staying up-to-date with these standards becomes increasingly important in the construction industry. In Summary:Securi-Flex® proudly announces our comprehensive knowledge of CPR (Construction Products Regulation).We have invested significant time and resources into understanding and adhering to these crucial regulations. This helps to ensure the highest level of safety and compliance in all our products and services.We are dedicated to keeping up with CPR regulations to ensure that our products meet the highest safety standards. This allows you to have full confidence in the reliability and quality of Securi-Flex® solutions.Securi-Flex® is your trusted source for a diverse range of Dca CPR rated cables which are in stock as standard.Securi-Flex® curates its' extensive inventory meticulously to meet the highest safety and quality standards. This ensures that your projects comply with the necessary regulations and standards.If you require CPR rated cables for the following applications, Securi-Flex® provides a wide selection of options to suit your specific needs:Residential Commercial Industrial If you have any questions regarding CPR, please don’t hesitate to contact the Securi-Flex® team, we’re always happy to help!
Cat 6A Cable
Cat 6A cable delivers high performance of 500Mhz, and must meet stricter specifications for reducing system crosstalk than Cat5e cables. This type of data cable allows for transmission of up to 10Gbps. Cat 6A Cable Application Cat 6A cable is most commonly used for VoIP, CCTV and data network appl
Network Data Cable
Offered as a budget friendly alternative, and designed to support network data cabling installation over shorter distances, the CCA network data cabling range has Copper Clad Aluminium solid conductors, HDPE insulation and overall PVC, LSZH or PE Jacket. Not recommended for POE. Budget frien
Cat 6 Cable
The Cat 6 cable delivers a maximum performance of 250Mhz, which is more than twice that of the Cat 5e cable specifications of 100 Mhz, making it ideal for networking installations. These data cables are also backwards compatible. The printing detail on the sheath includes reverse metre marking, all
Cat 8.1 Cable
A newer option in data cabling standards, Cat 8 ethernet cable is one of the highest performing data cables on the market. Cat 8 cable offers performance of up to 2000 MHz. Cat 8 Ethernet Cable Application Designed for use in computing, communications and POE applications. Cat 8 cable is best sui
Profinet
PROFINET, or industrial ethernet, is a crucial component in industrial automation systems, ensuring reliable communication within industrial networks. PROFINET cable withstands harsh industrial environments, offering robustness and durability. Our PROFINET cable facilitates high-speed data
Cat 5E Cable
Cat 5e cable refers to the Category 5 Enhanced cabling standard for networks and performs up to 100MHZ. These backwards-compatible data cables are used in Gigabit ethernet and other networking applications. Each cable consists of 8 colour coded polyethylene insulated conductors. These are twisted
Cat 7A Cable
Cat 7A ethernet cable provides high immunity to interference, and offers performance up to 1000 MHz. Because of this, these data cables are becoming the industry standard for wiring within smart homes and are gaining popularity with customers that want to get the optimal performance out of their own