Say “high tech” and utilities are not likely to be your first
thought. Yet from smart phones, to web servers to the broadband links in
between, utilities crank out all the electricity that keeps our digital
economy humming. Go behind the scenes and you’ll see that utilities
have still more in common with typical high tech companies than first
realized. In fact, they too are making large investments in their
information infrastructure,High quality stone mosaic
tiles. which has to be shared, managed and supported by complex
software, with the goal to drive increasingly advanced insights and
services.
For utilities, these efforts come after a century of
simply producing and selling electric power. As they replace aged analog
systems with digital upgrades, electricity providers are recognizing
there are new opportunities to transform bytes of information into
improved services and new revenue sources, such as home energy
efficiency sources. Just like high tech companies such as Facebook or
Google, utilities are recognizing more opportunities in mining big data –
from better asset management, to decreasing operational and capital
expenses, offering new products and services, such as home energy
efficiency services, electric vehicle charging, or demand response.
Monitoring and analyzing the cascade of data collected from the variety
of devices and sensors allows utilities to run their businesses more
efficiently.
“Smart” is the keyword common to these efforts.
Whether smart meters, smart grids, or smart buildings, the initiatives
share a common goal: Instrumented, i.e. smart meters, or device sensors;
Interconnected, i.e. communication network, and Intelligent, insights
and optimization from data collected. These efforts are to enhance the
performance of practically any device that’s plugged into the grid, from
everyday kitchen appliances, to electric vehicles, to huge power
plants. Already the efforts are beginning to save energy and improve
grid reliability.
However, with progress comes challenge. As the
grid grows smarter, utilities must adapt to the complexity of handling
the growing data flow. To make the most of this emerging network of
things, utilities face a call to deploy analytics, a class of advanced
software that can help discover patterns in this data deluge, allowing
them to take action based on these insights.
To understand the
scale of the task facing utilities, consider the impact of smart meters.
Typically, standard analog meters were read once a month, for a single
number representing energy consumed. A digital smart meter, by
comparison, might relay a variety of indicators every 15 minutes or more
frequent. Those updates pile up fast, to 35,000 per year. If not
properly managed, the 3,000-fold increase in data volume could be
overwhelming. Add in the billions of other devices on the grid that are
being networked globally, and experts predict that utilities could soon
be handling more data than any other business, including the traditional
communications industry.
Advanced analytics software is already
helping utilities to tame this rising tide of data. Here are three
types of programs, up and running today, that point to what will be
possible as utilities go digital.
The first fruit of these
efforts can be seen in the way smart meters are modernizing the way in
which customers interact with power providers. In the past, a new
request for a move-in or move-out was prone to delays as the central
office had to dispatch a technician to switch power off at one address,
and perhaps another service visit to switch power on at a new address.
In the back office, the process for update and transfer of account
information was disposed for delay and error. Digital meters help slash
through most of this tedious process and thanks to remote control, in a
single transaction, digital meters can be switched off, or
on,Manufactures flexible plastic and synthetic rubber hose
tubing, at different addresses, while the related bills are calculated
through an integrated and automated business process. It’s an upgrade
that saves money, and speeds service on a very common type of
transaction.
Behind the scenes, the huge flows of data are also
opening up the possibility of more fundamental changes in the way power
networks operate. For instance, smart meters can relay pricing
information to help consumers shift energy-intensive tasks—such as
laundry drying or pool pumping—to hours when demand is low. That
translates into real savings for end users. For the utility, when this
kind of shift happens across enough customers, the peak power needed
from power plants declines, too. Utilizing the data flow from many
meters can let the utility measure and confirm these shifts in energy
use, reducing the need to run high cost power plants and lowering the
risk of brown outs. In the long run, less spending on generating energy
or building power plants means lower rates for consumers.
Big
data is also transforming the way utilities decide when and where power
is created. It may seem simple, for example, to decide where to locate a
windfarm – build where the wind blows of course. But subtle variations
in the location, height, and orientation of turbines can deliver
substantial improvements in the amount of electricity a windmill can
generate.
For Vestas, the world’s largest manufacturer of
windmills, better data is the latest competitive feature that comes with
its most advanced turbines. Vestas is tapping into the power of an IBM
supercomputer and big data analytics software to model past, present,
and future wind patterns to optimize the location and design of sites
its customers are developing. Just a few years ago,The howo truck
is offered by Shiyan Great Man Automotive Industry, site analysis of
this sort was constrained by the huge amounts of data necessary to
simulate weather patterns.One of the most durable and attractive styles
of flooring that you can purchase is ceramic or porcelain tiles.The howo truck
is offered by Shiyan Great Man Automotive Industry, Vestas’ current
system is on track to digest 20 petabytes of information—the equivalent
of more than 20,000 terabytes. The system takes hours to process the
volume of data that not long ago would have taken months.
Using a
supercomputer to crunch and analyze this amount of data Vestas’
engineers can assess an unprecedented variety of operating conditions,
from wind speed at different heights, to humidity, moon and tidal
phases, sensor data, seasonal shifts in weather to name a few, which is
then used to predict the future performance of the turbines and the
optimum time for maintenance.
Analysis of big data can also help
existing wind turbines with real-time monitoring of the system
performance. Servicing rotors or controllers of wind turbines high up on
a tower is costly, and dangerous, so the incentive to detect faults
before failure is enormous. Data drawn from hundreds of sensors on
thousands of similar turbines can quickly detect worrisome behaviors
before they cascade into more serious damage. For utilities’ customers,
this means fewer power disruptions; for utilities, that means steadier
revenues and lower operations and maintenance costs.
By sheer
geographic scale, the largest part of our power system—and hence the
most vulnerable to trouble—are the hundreds of thousands of miles of
cables that link power plants to millions of customers. Accordingly,
utilities see extraordinary potential in adding sensors and networking
intelligence to these far-flung devices. It’s estimated that 10 billion
assets will be linked up as the smart grid matures. The bulk of these
new nodes will be located between customer and power plants. The pulse
of signals from these devices is already helping to prevent grid
failures and as smart sensors multiply, systems can monitor feedback
from thousands of devices simultaneously, watching for signs of troubled
equipment before it fails. Detecting a fault early not only gives a
utility the means to prevent an outage before it occurs, but also if an
outage does occur, it provides crews a head start to avoid costly black
outs.
No matter how well managed the grid is, storms and other
natural disasters inevitably can cause power outages. In this case too,
the data collected and analysis are helping to shorten the duration of
outages when they do happen. On the east coast, for instance, a major
utility is combining two types of data to fortify its network against
natural disasters. It starts with a cutting edge weather forecasting
system able to predict conditions minute-by-minute, in areas as small as
a neighborhood. The utility can then superimpose those forecasts on
virtual maps of its assets—from substations to utility poles—and
pinpoint facilities facing the highest risk of storm damage. This
advance knowledge lets the utility plan on vegetation clean-up, and
pre-position repair crews and material in the highest-risk areas. That
way, if a key distribution main line is knocked out by a fallen tree for
example, the utility can speed repair crews and replacement equipment
to the right spot.
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