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The Ultimate Guide to Power Extension Cable Updated 2024

The demand for secure and dependable power distribution has never been so high, especially in today’s interconnected world. The goal of the “Ultimate Guide to Power Extension Cables Updated 2024” is to provide individuals and businesses with a comprehensive understanding of power extension cables. This includes an examination of the different types available on the market, what they can be used for specifically, as well as expert tips on how to choose which one is right for your needs. We are looking at safety first but also ensuring that things are compatible and efficient so that people have all the necessary information needed to ensure that their setup is not only practical but also safe in terms of whether or not it meets any regulations, etc., with this article. This guide will answer all your questions about various power extension cords, be you setting up an office at home or managing large commercial spaces where knowledge on these matters may help save lives through precision while still being understandable enough even if those who know nothing about electricity want more details then here they come..

What are Power Extension Cables?

Australian Plug IEC C13 Power Extension Cable 1.5m 0.75mm for PC Computer Monitor Epson Printer
Australian Plug IEC C13 Power Extension Cable 1.5m 0.75mm for PC Computer Monitor Epson Printer

Definition of power extension cables

Power extend cables, known as extension cords, are devices that can be utilized to make electrical power outlets reach further towards electrical appliances or equipment. They have an electric wire inside a protective covering which ends in one or more sockets on one end and a plug on the other. The most important characteristics of power extension cords are:

  • Length: This is how far from the main supply point the device can be installed; such lengths may vary between 1 meter (around three feet) up to 30 meters (about 100 feet).
  • Wire Gauge (AWG): It indicates thickness of wires enclosed by a cable where lower numbers mean thicker ones capable of carrying higher currents without overheating.
  • Rating: Voltage (V) and current (A) capacity, which describes the maximum safe power transfer ability represented in terms of volts times amperes.
  • Connector Type: This refers to plug/socket types used according to country-specific standards like Type A, Type B, or even Type C, etcetera.
  • Insulation and Sheathing Material: These affect longevity as well as safety features exhibited by this component; for instance PVCs are flexible while rubber offers better water resistance than neoprene does but each has got oil protection capabilities alongside abrasion resistance properties too.
  • Safety Features: Surge protectors built into them among other things help keep users safe during use so should GFCI protection against ground faults plus tampering resistant receptacles.

Knowing these aspects can greatly help buyers select suitable power-extending lines for different applications in order to guarantee safety, efficiency, and reliability either at home or in workplace.

Types of power extension cables

There are different kinds of power extension cables that are created for different uses. In general, they can be classified into the following types:

  • Common Extension Cords – These are frequently used in homes and small businesses. They typically have a plug-and-socket design; however, they also come in various lengths and wire sizes to cater for everyday electrical demands.
  • Heavy Duty Extension Cables – Heavy duty cables are manufactured using tough materials like rubber or neoprene so that they can withstand harsh conditions such as construction sites or industrial settings. They often have higher amperage ratings and more safety features like circuit breakers built into them.
  • Retractable Extension Cords – Retractable cords were designed with convenience and space-saving in mind; therefore, they possess a reel which allows users to pull out only as much cord as needed then wind it back up again when finished with it. These types of cords are commonly found in garages where there is limited room available but still require protection from tripping over loose wires.
  • Outdoor Extension Cords – Outdoor cables differ from other types because they come with weather-resistant sheathing materials and may be approved for use under damp conditions too. Some models even include UV protection against sun damage.
  • USB Extension Cables – USB extension cords have become an essential part of many households and offices today due to the digital era we live in now. They allow people to connect devices such as smartphones, cameras or printers at greater distances away from each other than what would normally be allowed by standard USB cable length.
  • Surge Protector Power Strips With Extensions – Surge protectors were invented to safeguard appliances against voltage fluctuations caused by lightning strikes, etc., while extension leads enable users to access power outlets located further away than one’s normal reach could manage alone. Combining these two creates surge-protected extension cords, which extend socket availability whilst protecting gadgets plugged into them, too!

To select the right type of power extension cord, one must take into account specific needs for the application including where it will be used (environment), what loads need to be carried by it (electrical) as well as length and flexibility required. Understanding these specifications guarantees safe use with optimal performance at all times.

How power extension cables work

Power extension cords are designed to carry electrical current from a power source to equipment or appliances located some distance away. Typically made of copper or aluminum, the wire (conductor) is the most important part of an extension cord as it allows electricity to flow with minimum resistance. Its size and gauge determine how much electric charge measured in amperes can be safely transmitted by the cable. This wire is insulated with PVC or rubber-like material that shields users against contact with live parts and guards them from external factors.

The cable’s ability not to overheat while supplying power depends on its gauge – fatter wires have lower AWG numbers hence higher current carrying capacity. For example, a 14-gauge extension cord may be rated for up to 15 amperes which is enough current for common household devices; whereas a 12-gauge one could transport up to 20 amps needed by heavy duty tools.

Extension cords are equipped with plugs and sockets so that they can be connected between electrical outlets and appliances. These terminations comply with regional standards like NEMA (USA/Canada) or IEC (International Electrotechnical Commission) thus making them universally acceptable for use across different countries worldwide. Grounding contacts plus built-in circuit breakers among other safety features are put in place to reduce chances of electrical faults thereby enhancing protection against electric shock or fire hazards.

Power extension cables allow electricity supply systems to reach farther than their original points towards places where energy is required most, hence very useful in homes/offices/factories, etc., depending on specific needs. The right choice should be made during selection based on technical specifications together with surrounding conditions so as not only to ensure efficient performance but also to meet safety requirements while powering devices.

How do you choose a suitable power extension cable?

How do you choose a suitable power extension cable?

Factors to consider when selecting a power extension cable

When one is selecting a power extension cable that will be right for his or her needs as well as meeting safety standards, there are various things that need to be taken into account. They include the following:

  • Current capacity (Amperage): The amperage rating of any given wire should correspond with or exceed the total current drawn by all devices it is meant to supply electricity. This will prevent overheating that might result in a fire outbreak. For instance, if you have appliances consuming 15 amps altogether, then your cable should not be less than 15A rated.
  • Length: Long wires experience voltage drops, which may cause inadequate delivery of power to machines, especially those fitted with motors or any other delicate electronic gadgetry. To avoid this problem, one must pick the shortest length possible for his or her situation.
  • Wire gauge (AWG): The American Wire Gauge number shows how big internal conductors are; lower numbers mean larger conductors capable of carrying more current safely. For example, a 12-gauge wire can handle higher currents than 14-gauge equivalents.
  • Safety features: Extension cords having built-in protection against electrocution, overloading and short-circuiting are much safer than those without them. Grounding, surge suppressing functions and circuit breakers fall under this category too.
  • Connectors: Ensure you have plugs & receptacles that match each other and all necessary devices being used are properly grounded where applicable so as not to create unnecessary hazards during usage. This also includes checking whether polarity marks on connectors agree with those found at sockets/terminals
  • Environmental conditions: If cables are used in outdoor environments, they should be designed for such usage i.e., moisture resistance, UV protection, etc., similarly when dealing with hazardous locations where chemicals may come into contact with live wires, such situations demand special types of cabling having resistance against substances likely corrode or react badly upon contact
  • Compliance & Certifications: Always make sure that whichever wire you decide to buy has undergone testing by recognized authorities so as to ascertain its conformity with various safety measures. Examples include but not limited to UL, CE, RoHS marks which serve as indicators showing whether particular standards have been met or not.

By considering these points seriously one can easily select an appropriate power extension cord for their distribution needs without compromising on electrical safety precautions.

Choosing the appropriate length for your needs

It is important to choose the right size for an extension cord to make sure that electricity is delivered efficiently and safety is maintained. The length of a cable directly affects voltage drop which refers to the reduction in electrical potential along it. This can result into failure of power reaching a device and consequently performance problems or damage. To achieve maximum performance, use only as much length as required.

For example, if both 10-foot (3-meter) and 50-foot (15-meter) cables were used to supply power to one device, the former would experience a significantly lower voltage drop than the latter. To illustrate this point further, in a 14-gauge cable carrying a current of about 10 amperes, there will be an estimated voltage drop of 2.08 volts per hundred feet. Thus, for a ten-foot cable, this drops by about 0.208 volts, which is generally considered negligible but increases up to 1.04 volts in the case of fifty feet long cables, which may be disastrous for delicate tools.

The choice between convenience and technical limitations must be made while selecting the best length of power cords needed for different applications. In situations where a continuous supply of energy is necessary, such as hospitals or data centers, always ensure that you buy extension cords having the least amount of resistance, i.e., the shortest possible lengths, so as to minimize voltage drops, which can cause intermittent faults on sensitive electronic devices like servers etcetera.If there are circumstances under which longer cables cannot be avoided, then go for bigger wire gauges (lower AWG number) because they have fewer Ohmic losses, which counteracts effects caused by VD even over great distances.

Determining the correct gauge for your devices

While determining the gauge for your devices, you should consider their power requirements as well as the length of cable needed. The diameter of a wire is inversely proportional to its cable gauge, which is represented by an AWG (American Wire Gauge) number; smaller AWG numbers indicate thicker wires. A wider wire carries more current with less resistance hence reducing voltage drop over long distances.

To illustrate, if a device draws 15 amperes of current, then it would require a 14 AWG wire for lengths up to 50 feet without compromising safety. However, after this point, an electrically efficient and secure connection may demand a 12 AWG wire. Under different conditions, the National Electrical Code (NEC) gives maximum ampacities for insulated conductors of various gauges in terms of their ability to carry current; this information can be found on Table 310.16 NEC.

In practice, one might refer to such tables so that they select cables whose gauges can cope with power loads from devices without heating up too much. Despite the fact that a 10 AWG wire is capable of carrying about 30 amperes normally; there could be a need for larger sizes like 8 AWGs when dealing with longer runs or higher power applications where adequate delivery needs to be guaranteed lest risk be managed against power shortage through such strategic choices which are crucial towards optimizing performance while observing safety rules.

Top Features to Look for in Power Extension Cables

Top Features to Look for in Power Extension Cables

Understanding different connector types

To guarantee compatibility and effectiveness in power extension applications, it is important to know about the different types of connectors. Connectors serve as a bridge between the cable and the device or power source. The kind of connector chosen can greatly affect safety and functionality within an electrical system. There are several main connector types:

  • IEC Connectors: IEC connectors, or International Electrotechnical Commission connectors, are commonly used with computers and monitor power cords. Among them, the most well-known ones include IEC-320 C13 and C14 which have a locking mechanism that prevents accidental disconnection.
  • NEMA Connectors: NEMA refers to National Electrical Manufacturers Association; they standardize connectors for use mainly in North America. These connectors are identified by an alphanumeric code such as NEMA 5-15 – this being the standard three-prong plug used for most household electronics.
  • USB Connectors: Universal Serial Bus (USB) connectors have become very popular since portable devices came into existence. They range from USB-A, USB-B which are common standards to USB-C which supports faster data transfer rates as well as power delivery hence its suitability for various devices.
  • DC Power Connectors: DC or direct current connectors are frequently employed on battery powered equipment and low voltage applications. Barrel connectors, with their simple cylindrical design, rank among the most widely used DC plugs globally.

The right choice of connector type depends on knowing what power a device needs and where the cable will be used, i.e., environmental factors like weather conditions, etc., and also considering applicable standardizations concerning geographical location involved in the selection process. When choosing a connector, one should look at the voltage/current ratings vis-a-vis those required by the device being powered through it while ensuring a higher protection level based on IP rating, especially for areas prone to moisture/dust/particulate presence.

Safety features to prioritize in power extension cables

To guarantee the safety of individuals and protect their devices from destruction, it is important to choose power extension cables according to safety features. Some of the major safety concerns are as follows:

  1. Surge Protection: Surge protectors shield electric appliances from voltage spikes. Cables that have built-in surge protection guards can save vulnerable equipment from abrupt power surges.
  2. Insulation and Jacket Material: Durability of wires largely depends on insulation and jacket material quality vis-à-vis their resistance against environmental conditions such as heat, moisture or even abrasion. Different types like PVCs, rubbers or polyethylenes offer different degrees of protection as well as flexibility.
  3. Gauge and Wire Thickness: The thickness of electrical wires within a cable is denoted using the American wire gauge (AWG) system; lower numbers represent thicker wires that can handle higher current loads without overheating, thus preventing fire accidents emanating from this issue. Always ensure that your wiring gauge matches up with what you want to use it for lest things turn out adversely.
  4. Grounding: Ground wires in an extension cord are very crucial when it comes to preventing electric shocks especially where there might be high chances of getting faults due to poor earthing systems employed so far.
  5. Overload Protection: There may be circuit breakers included in some extension cords themselves which automatically cut off electricity supply if current exceeds safe limits thereby providing additional safeguard against overloads.
  6. Tamper Resistance: In areas accessible by kids, tamper-resistant outlets deter insertion of foreign objects into sockets thereby reducing risks related with electrical injuries caused through this means alone.
  7. Environmental ratings: Those cables intended for outdoor usage need proper ingress protection ratings indicating their ability to resist dust or water entry under different circumstances; failure to take into consideration these aspects could lead into various hazardous situations occurring while working outside

Distinguishing between indoor and outdoor power extension cables

When it comes to distinguishing between indoor and outdoor power extension cables, there are several important considerations and specifications that need to be taken into account for their safe and efficient operation in their respective environments.

Typically, indoor power extension cords are designed for use in less severe conditions and, therefore, have lighter-weight insulation, which is also more flexible. They cannot be used outside because they lack the ability to withstand harsh weather, such as moisture or direct sunlight, among others. On the other hand, outdoor power extensions feature a rugged design with heavy-duty materials used throughout their construction, including coatings resistant against UV light, water, and even oil or chemicals that may be applied depending on specific needs, sometimes referred to as waterproof type cables.

Furthermore, these types of wires usually come with higher Ingress Protection (IP) ratings than those meant for indoor application thus indicating their ability to keep off things like dust particles entering into them as well as preventing any liquid from getting inside too easily. The two digits that make up an IP rating represent protection levels against solid objects (first digit) and liquids (second digit). For instance, an IP65-rated cable is dust-tight while being able to withstand water jetting at it from all angles, thus suitable for various demanding applications outdoors where such levels of protection may be required.

In addition to having tougher plugs or connectors fitted onto them so that they can remain operational under different weather conditions, outdoor cords may also possess higher American Wire Gauge (AWG) numbers, meaning thicker wire sizes used therein are capable of carrying electricity over extended distances without experiencing much voltage drop along its length. This becomes very critical, especially when dealing with longer runs or stretches of cable extensions required outside, where this could happen frequently due to either bad connection joints made during the installation process or simply poor quality control measures adopted by manufacturers themselves during production stages.

It is, therefore, necessary that one knows how best he/she should choose between these two types based on what exactly he/she intends to use them for since failure will not only compromise safety but also damage the devices connected with them.

Benefits of Using Power Extension Cables

Benefits of Using Power Extension Cables

Enhanced convenience with multiple outlets

Power extension cords are very useful since they offer several sockets where many devices can be connected from one power source. This feature becomes invaluable in places that have few or inconveniently placed electrical outlets. For instance, a conference room may need to connect laptops, projectors, and sound systems at the same time without using multiple cables, which could pose a danger by lying all over the floor.

Most of these extensions come with surge protectors designed to prevent voltage spikes that may damage connected appliances. The capacity of energy absorption of protective components between the wires used to make them is measured in joules; hence the higher the rating in joules, the stronger it is against power surges. In addition, some power extension cords with multiple outlets have individual switches for each socket such that electric flow can be controlled better and devices not in use can be turned off without necessarily unplugging them, thereby saving energy and enhancing safety at the same time.

For environments requiring more than one IT data center or any other high-powered device, there are various types of extension cables available, including those having extra outlets, increased amperage capacity as well as integrated circuit breakers. These special-purpose wires are made in such a way that they meet stringent requirements for powering high-power gadgets while still protecting against overload so as to ensure the stable distribution of electricity necessary for the uninterrupted operation of critical equipment.

Increased flexibility in positioning electronic devices

Power extension cords are designed to elongate the reach of electrical appliances in a room or office. This feature comes in handy, especially when the fixed electrical facilities are not located as per the space arrangement requirements of the equipment being used. For example, in a contemporary workplace setup, it may be necessary to position desks and workstations closer together for team interaction and efficiency but this might not coincide with where built-in power outlets are placed. In such situations, power extension cords can be used to move computers, printers, or desk lamps, among other devices, to these preferred areas without having to do much electrical rewiring.

Secondly, technical specifications like cable length, thickness (gauge), and the kind of insulation material used also contribute largely to determining whether an extension cord is suitable for a particular application or not. Longer cables cover more distance between the power source and appliance while thicker wires allow electric current to flow over extended lengths without significant voltage drop. Henceforth, it is important to choose an appropriate specification of an extension cord that will ensure that electronic devices operate safely and efficiently.

Moreover, besides meeting immediate power supply demands, these cords make workstations healthier places by enabling users to position gadgets in ways that cut down on mess around them, thereby reducing chances of tripping over objects as well as enhancing accessibility overall. Therefore, the use of well-selected strategic points within such physical working spaces not only facilitates the distribution of electricity required at different sections but also contributes towards making such environments more lively and adjustable.

Protection against Electrical Surges

Electricity wave are an essential part of the use of extended cables, as they protect electric appliances from power surges that are caused by lightning strikes or any other interruption in power supply. Studies have shown that when surge protective devices (SPDs) are integrated into extension cords they can greatly reduce the chances of damaging electronics by absorbing or redirecting excess voltage away from them. For example, according to an article published in IEEE Transactions on Industry Applications, which described several controlled experiments with electrical surges, computer systems were saved from destruction only due to having been connected through SPD–equipped extension cords. Such findings imply that all extension cables used with electronic devices prone to power variations should be fitted with surge protection facilities if their operational life and dependability are to be ensured.

Common Mistakes to Avoid When Using Power Extension Cables

Common Mistakes to Avoid When Using Power Extension Cables

Overloading power extension cables

One of the most common mistakes people make is overloading power extension cables. This can be very dangerous. It could cause a fire and ruin all the things plugged into it. This happens when you connect devices that draw more electrical power than what the cable can handle. To prevent this, here are some tips:

1. Know The Maximum Watts Allowed By The Cord: Every extension cord has a maximum amount of power it can carry safely, which is indicated in watts on its packaging or label; ensure not to exceed this value with all the devices connected.

2. Consider All Device Needs: take note of how much electricity each appliance uses and add them up so you know what demand will be put onto your cables.

3. Don’t Connect Too Many Together: Avoid daisy chaining many cords together as this could lead to overloading and inefficient distribution of electricity thus reducing safety too.

4. Utilize For Its Designated Functionality: Make sure that where it is used suits its nature such as outdoor specific types or those meant for heavy duty tasks.

5. Regularly Check For Any Damages: Inspect periodically for any signs like fraying or cracking along their lengths; even if total wattages connected fall within limits, capacities may still get exceeded due to compromised integrity caused by these faults

Using damaged cables or connectors

If you use damaged cables or connectors, they can lead to different problems that can affect device safety and operation. Therefore, it is important to be aware of these risks, which need to be understood and dealt with by:

  • Dangers associated with electric shock: Exposed wire tips without insulation around them may easily give users a potentially fatal jolt. When an outer shield protecting against this kind of thing is pierced thus revealing inner metallic parts used for conducting electricity.
  • Short circuits: A cable which has been damaged allows contacts meant never to touch each other come into contact thereby causing short circuiting. This may result into failure of devices and even fire outbreak in extreme cases.
  • Performance deterioration: Defects found within wires or connectors could greatly lower their efficiency levels as well as cause signal attenuation. Such imperfections can make data cables transfer slowly or lose connectivity altogether while power cords might fail to supply enough energy needed by equipment.
  • Fire risk incrementation: The possibility for overheating increases when wires get spoilt especially if they have been stripped off internally leading to short circuits. In addition, such items not only destroy the gadgets connected but also become potential sources of fires.
  • Damaging devices: Electronic machines could be permanently harmed through the utilization of faulty wires, among other things. Moreover, sensitive components are likely to suffer from voltage fluctuations due to bad connections thus caused by irregularities in electrical systems.

To mitigate these risks, it is recommended to:

Check the cables and connectors frequently for any signs of damage.
Do not use cables or connectors that have visible damage until they can be replaced or repaired by someone who is qualified to do so.
Always make sure you are using the right kind of cable or connector for your particular application, and that it is suitable in terms of compatibility and electrical capacity.

Taking these precautions can reduce the likelihood of device damage and personal injury and ensure the longevity and reliability of electrical devices and systems.

Tips for Maintenance and Care of Power Extension Cables

Tips for Maintenance and Care of Power Extension Cables

Proper storage to prevent tangling or damage

If you don’t keep extension cords in order, They will get tangled or damaged very quickly. In order to prevent this from happening, it is necessary to coil the cables into a loose loop following their natural coiling so that they do not twist them too tight and, therefore, break any wires inside. One can also use velcro straps or cable organizers for securing these loops together which would keep them from unraveling and becoming a mess of knots. To preserve insulation materials of electrical wires and cables, one must store them away from direct sunlight; heat sources like radiators or heaters, as well as sharp objects such as nails or scissors, should be kept far off, too. It’s important to know that all these items can easily degrade the insulation material, thus making it less effective against electric shocks. Such methods save power cords from physical harm thus maintaining their performance throughout time.

Regular inspection for wear and tear

To prolong usage and keep power extension cords safe, it is very important to have them checked for wear and tear regularly. For this reason one must carefully go through the whole length of the cable looking out for any signs of fraying, cuts, abrasions or exposed wires, which may mean that there has been physical damage that weakened its strength. Another thing that should not be left unchecked during the inspection is if there are parts that appear twisted or bent too tightly, as such areas could contain hidden internal wire damage. In addition, connectors, as well as plugs, need to be examined keenly, for instance, when they show signs like a change in coloration or melting due to overheating, so as to prevent probable risks. An enhanced frequency of checking ought to be embraced where cables are moved frequently within different sites exposed to adverse weather conditions. By doing timely detection and correction, device breakdowns can be avoided; fires caused minimized and people shielded from electricity, thus keeping them at their best levels of safety while functioning properly

Safe handling practices to prolong the lifespan of your cables

Safe handling practices are important to make power extension cords last long and work better. First, you should always hold the plug when connecting or disconnecting cables instead of pulling it. This will prevent unnecessary pressure on the connector and cable junction. Second, do not route them across high-traffic zones where they can be stepped on or rolled over by chairs and equipment damaging them internally or externally with time. In addition, never overload power extensions exceeding their rated capacity because they may heat up excessively thus become potential fire hazards. Use cable clips together with raceways for managing cables; these tools help in organization as well protection against possible damage to the wires. Lastly, space-saving methods like employing right-angle plugs or connectors with low profile can reduce strain at the entry point of a cord while also utilizing less space itself . Following all these precautions shall not only increase the useful life of your power supply leads but also keep people safe at work by creating an efficient environment for everyone involved in it

Reference sources

  1. 9 Best Power Extension Cords for 2024 – In 2024, Storables did an article about the best power extension cords that can be found out there. The author of this article discussed different products and shared what makes them special with their readers. Source
  2. 2024’s Best Cables, Power, and Grounding – The 2024 buyer’s guide from Part-Time Audiophile gives its readers a list of the top-rated cables, power management tools, and grounding options this year. This guide is helpful to people looking for information on things like power extension cords. Source
  3. 8 Best Extension Cord for 2024 – The following is yet another piece from Storables. They have compiled a list of the top extension cords for 2024. They also provide an in-depth buyer’s guide that explains various types of extension cords, cord lengths, indoor and outdoor use as well as gauge.Source
  4. The Best Outdoor Extension Cords of 2024 – This post has been reviewed and rated by USA Today as it tests, researches and compares the top outdoor extension cords you can buy in 2024. Source
  5. Top 4 Best Extension Cords in 2024 – YouTube – A YouTube video guide that talks about the best four extension cords for 2024; it is an important visual aid for those who do not like reading articles. Source
  6. The Best Generator Extension Cords of 2024 – The 2024 generator extension cords are the main subject of examination by Woodsmith. It gives some must-have features when selecting a suitable cord.Source
  7. The Ultimate Guide to 2 Gang Black Extension Leads – A Medium article that provides an in-depth look into 2 Gang Black Extension Leads, which are power extension cables.Source
  8. The Best RV Extension Cords of 2024 – In its review of the top RV extension cords for 2024, Old Cars Weekly ensures that an RV has dependable power supply for its journey. Source
  9. The 6 Best Extension Cords of 2024 – In a 2024 list of the best extension cords, according to Popular Mechanics, the article names six options including which is the best overall and most affordable heavy-duty.Source
  10. The Complete Guide to Apple Power Extension Cables – A detailed guide on Medium about Apple Power Extension Cables; A valuable source for apple users in need of power extension cables.Source

Recommend reading: Power Extension Cable for sale

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