When a power outage at a remote equipment rack site takes down your network, suddenly the importance of an effective power redundancy solution becomes all too clear. Network outages are always costly; whether you’re talking about lost productivity, lost business opportunities or just the hassle of being without valuable network communication capabilities when you need them the most, a network outage always makes the cost of a power redundancy solution or power fallback strategy seem well worth whatever funds it might cost to put one together.
Archive for the ‘transfer switch’ Category
Power Fallback Always Seems Like a Good Idea After a Power Outage Interferes with Network CommunicationWednesday, December 28th, 2011
When a vital network element loses power and shuts down, the resulting outage can disrupt access to important network services or at worse, bring your entire network to its knees. This is a pretty familiar problem to most network administrators, and in most cases, the most obvious way to prevent this type of situation is to make certain that all of your vital network devices have access to a back-up power source. Although a power redundancy solution is easy to implement when the network device in question includes dual power inlets and built in power fallback capabilities, it can be a different matter if that vital network element only includes one power inlet.
In today’s technology driven world, computer networks essentially serve as the nervous system of large businesses and organizations. Users depend on the network to be available when they need it, and a widespread network crash can often bring an entire organization to its knees while users wait for valuable services and capabilities to be restored. With this in mind, the importance of a reliable power fallback or power redundancy solution is easy to understand; when network administrators eliminate network service interruptions caused by power outages, they have essentially eliminated one of the most common factors that can disrupt network communication and hamper the work flow of the business or organization that relies on a particular network.
When power to a critical network device suddenly fails or becomes unstable, the resulting network outage can often create a wave of pain that’s quickly felt throughout your entire organization. Network communication is a vital part of any modern business, and most businesses can’t afford to have a relatively minor inconvenience, such as a power failure, interfere with the ability of their employees and customers to access important network resources and communication capabilities. This is exactly why so many businesses are updating their network infrastructure to include power fallback and power redundancy capabilities.
Without proper planning, the task of adding power redundancy and power fallback capabilities to an existing network equipment site can be both complicated and costly. In order to add a power redundancy solution to an existing network installation, network administrators and engineers will often resort to replacing older, single-power-inlet devices with brand new dual inlet devices. This can often run into tens of thousands of dollars in equipment costs, plus additional time spent reconfiguring other network devices for compatibility with new dual inlet devices. But adding power redundancy to an existing network application doesn’t have to be expensive and inconvenient; not if you use a transfer switch to provide power redundancy to existing single inlet devices.
Power redundancy is becoming an increasingly important element in many network applications. The reason for this is simple; an intelligently deployed power redundancy solution with automatic power fallback capabilities helps to minimize network downtime and ensure that critical network elements are always available when needed. An effective power redundancy solution helps to reduce the risk of network outages by providing a means to automatically switch over to a back-up power supply in the event that the primary power supply fails, or becomes unstable.
Power outages can be a major headache for network administrators; especially when those outages occur at remote network equipment racks, where an interruption in power might not be noticed until it causes a problem and a user complains. Obviously, the ideal solution for dealing with power outages at network equipment racks, is to implement a power redundancy strategy that enables vital network devices to begin drawing power from a secondary power source in the event that the primary power source in not available.
These days, it’s pretty difficult to think of a type of business that doesn’t rely on network technology or internet access to one degree or another. Given the importance of network communication in the modern office, it’s easy to see why it has become absolutely vital that the corporate network is always up and running and available to users, 24 hours a day, seven days a week, 365 days a year. In order to ensure the reliability and availability of the corporate network, many network administrators rely on power redundancy and automatic power fallback capabilities to prevent power outages and power supply instability from disrupting network communication.
In critical network applications, older single power inlet devices are basically a disaster waiting to happen. All it takes is a power outage to take down single-inlet routers, servers and firewalls and cause widespread interruptions of network service and loss of access to critical devices and functions when they’re needed the most. In an ideal world, the obvious solution would be to replace those existing single power inlet devices with brand new dual-inlet network elements, but in the real world, sometimes we just don’t have the budget to drop tens of thousands of dollars on new equipment when those older single inlet devices are working fine (for the most part.) In cases like this, a simple transfer switch can provide an economical means to add power redundancy and power fallback capabilities, without the need to replace existing single inlet devices.