Emerson Control Techniques offers a wide range of Variable Frequency Drives (VFDs) and options to meet the diverse power and performance requirements of applications used in Water, Waste Water, Oil & Gas, Food Processing and other industries. To highlight the special performance characteristics and features, ease of use and other benefits Control Techniques drives bring to applications, we have prepared a series of application flyers called Solutions. The (green) Solutions you will find in these pages are specific to Energy Savings applications.
See the official government resources below for more information on State specific incentives for renewable & efficiency as well as energy usage and cost statistics. Energy Savings - Fans & PumpsWhy Energy Savings?Not only does the cost of energy affect profitability but it affects companies’ bottom lines differently. Energy efficient companies have a cost advantage when energy prices increase. Some companies have cut 20% or more of the energy required for a unit of product. This reduction in energy intensity becomes a major cost advantage. In the US industrial sector, 70% of all electricity consumption involves motor driven systems. Over 40% goes to pumps, fans, and compressed air systems. Control Techniques products can help save up to 60% in these applications and up to 30% on many of the remaining applications. An energy kWh meter is built into every Control Techniques drive to help monitor energy usage and document the savings. A number of utilities or states offer rebates to encourage energy efficiency. Check your utility’s web site for details. Those offering rebates will typically offer $40 or more per horsepower – or $4,000 for a 100hp drive. The traditional reasons still exist to use variable speed drives and motion control. These include process and quality improvements, reductions in raw materials usage and scrap produced, and reductions in maintenance of machinery due to soft starting, operational cycles, and fewer mechanical components. These improvements may be less easily quantifiable than energy but will typically provide significant savings. Include these additional benefits, as appropriate, in an evaluation with specifics where possible. You may have already identified applications needing improvement. Control Techniques will work with you to develop solutions that save energy and improve productivity. You can then evaluate how this project’s return on investment compares with other priorities. Most drives opportunities will have a simple payback within 18 months from energy savings alone. Variable frequency drives are an excellent choice for adjustable-speed drive users because they allow you to fine-tune processes while reducing costs for energy and equipment maintenance. Our variable frequency drives (electronic controllers) adjust the speed of electric motors by modulating the power being delivered. Control Techniques variable frequency drives provide continuous control, matching motor speed to the specific demands of the work being performed.
Pumps
Putting pressure on energy savings. A
pump is used for raising, transferring or compressing fluids. Pumps consume
31% of the power used by industry for motor driven equipment; more than any
other application. Pressure and flow of gases and liquids have traditionally
been regulated using bypass, balancing, or throttling valves and mechanical
clutches. These mechanisms
waste energy, require frequent maintenance, and provide inaccurate control. Identify if your pumping system is experiencing any of the key symptoms:
Pumps are the #1 energy savings
opportunity for motor driven equipment.
Studies show average pump system efficiency is below 40%. Over
80% of pump life cycle costs go towards energy and maintenance.
Optimizing pump systems
will greatly reduce both maintenance and energy costs.
Life
Cycle Costs
Pump Solutions Pumps
may be divided into centrifugal and positive displacement categories. 1. Centrifugal
pumps:
Horsepower: Up to 2,000
Savings: Up to 60%
(Depends on duty cycle
& static head.) Over
80% of pumps use centrifugal design because it provides high flow rates,
uniform pressure, and is easily driven by electric motors. They use
centrifugal and axial forces to create pressure that moves the fluid from
inlet to discharge. Centrifugal
pump types include Radial, Mixed, and Axial (propeller).
They serve in applications such as Chemical / Process, Irrigation,
Booster, Cooling Tower, Condensed Water, Hot Water, Chilled Water, Municipal
Water & Wastewater pump applications. Look
for centrifugal pumps with low static head pressure and many operational
hours for the most energy savings! Centrifugal
pumps generally operate as a variable torque load, a load that increases as
the speed increases. They follow
the Affinity Laws which state: 1. Flow is proportional to
speed. 2.
Pressure is proportional to speed squared. 3.
Power is proportional to speed cubed.
Energy usage for centrifugal pumps may be charted as follows for
different control methods. Example savings (VFD versus a Bypass
Valve)*
: 80%
Flow uses 50% of energy, (0.8)3 = 0.50 50%
flow uses 12.5% of energy, (0.5)3 = 0.125
Pump
Power Consumption
Pump
Solutions 2. Positive
displacement pumps:
Horsepower: Up to 1,000
Savings: 10-25% (Depending
on duty cycle.) Positive
displacement pumps force a fixed volume of fluid from inlet to discharge
with each stroke or rotation. They
generally operate as constant torque loads and are used whenever volumetric
accuracy or high static pressures are required.
Energy used is proportional to motor speed or flow.
Designs mechanically limit back flow which helps these pumps achieve
higher efficiencies than centrifugal pumps but are more likely to create a
pressure spike with each release. Positive displacement pump types include: Reciprocating
(fractional hp)
Rotary
(fractional to 1000 hp)
Look
for cam & piston or screw pumps which operate near continuously at
varying flow rates. For
more thorough analysis, The Pumping System Assessment Tool (PSAT) is a free
and useful tool for evaluating potential pumping system improvements. It was
developed with the support of the U.S. Department of Energy.
For more information on the PSAT and on properly matching pumps to
system requirements, see Improving Pumping System Performance: A Sourcebook
for Industry, which is available at www.eere.energy.gov/industry
/bestpractices.
Pump
Solutions Control
Techniques AC drives adjust pump speed to directly control flow and
pressure. The included PID controller or optional single or multi-pump
software solutions make advanced control easy to achieve. System
reliability and efficiency is greatly improved with elimination of bypass or
throttling valves and reduced pump RPM. Soft starting and operation at the
pump’s best efficiency point prevents water hammer, pipe stress, and
reduces cavitations while improving valve and pump seal life.
The flying start feature allows the drive to start an already
spinning motor. If it is moving
backwards due to pump back pressure, it will be smoothly brought to zero
speed before acceleration to the desired speed in the forward direction.
This greatly reduces stress on the pump impeller.
Control Techniques AC drives dramatically reduce pump life cycle
costs by lowering both maintenance and energy costs. Switching
control from bypass valves to an AC drive on centrifugal pumps with low head
pressures will typically save over 50% of the energy used.
Dynamic V/Hz further improves efficiency by reducing motor voltage
during low demand. While
the greatest reduction in energy costs is realized with centrifugal pumps,
most pumps will realize savings when less than full output is required.
AC drives improve power factor (>0.95) and reduce motor starting
current by factor of 8:1 to
further reduce power demand from your utility. An integrated EMC filter
reduces electrical line noise as standard.
Control Techniques helps you document energy savings by including a
kWh energy and running cost meters in the drive. The Skip Frequencies feature allows the user to easily avoid resonate
equipment frequencies which may cause high levels of vibration. Standard communication options enable remote monitoring and proactive
preventive maintenance triggered by pump load changes (such as clogged pump
or approaching bearing failure), run time, or other criteria. Contact Microcon Technologies for assistance identifying energy
savings opportunities in your facility.
Fans & Blowers
#1 Variable Frequency Drive Application Fans & Blowers:
Horsepower: Up to 2,000
Savings: 30-60% (Depends
on duty cycle.) Fans
are the single most popular application for variable frequency drives
because they are easy to retrofit and the energy savings typically pay for
the drive within 4-12 months. Fans and blowers consume 14% of the power used by industry for motor
driven equipment, ranking third behind pumps and compressors.
Fans and most blowers operate as a variable torque load, a load that
increases as the speed increases. They
follow the Affinity Laws which state: 1. Flow is proportional to
speed (n). 2.
Pressure is proportional to speed squared (n2). 3.
Power is proportional to speed cubed (n3). 4.
Noise is proportional to speed to the fifth power (n5). Reducing speed dramatically reduces power consumption and noise.
Control Techniques AC drives adjust fan speed to directly control flow and
pressure. Pressure
and flow have traditionally been regulated using mechanical dampers and
inlet vanes to restrict the flow of air.
These mechanisms waste energy, require frequent maintenance, and
provide inaccurate control. Energy usage may be charted as follows for
different control methods. The
distance between the curves is the energy saved at a given speed.
Look for fans and blowers which do not need to run at full speed
to meet process requirements. HVAC
is a good example because these systems are sized for hottest and coldest
days of the year. AC drives save
energy and dollars every other day.
Fan & Blower Solutions Since
these applications were early adapters of new technology, you may find fans
and blowers powered by some very old drives.
These early generation AC drives have long since paid for themselves
but are relatively inefficient compared to today’s generation of IGBT
drives which boast 97%+ efficiency. They
were large because they dissipated significant heat with typical
efficiencies of 75-90% depending on the technology used.
This large improvement in efficiency justifies a drive upgrade.
The upgrade is easy since the control is already in place and the new
drive is smaller than the existing drive. Look
for older AC drives for opportunities to improve efficiencies, reliability,
and functionality; not to mention a new 2 or 5 year warranty. Control
Techniques AC drives feature all the latest energy saving features and
integrated control to keep performance up and costs down as you find new
ways to save energy in your facility. The
included PLC functionality and
PID controller allow you to eliminate external controls if needed.
Skip
Frequencies feature allows user to easily avoid resonate equipment
frequencies which cause high vibration levels. Supply
Loss Ride Through will keep the drive up and running through most power
outages. It uses the inertia of
the load to provide drive power until the load stops turning fast enough to
generate the power necessary. When
input power returns, the drive ramps back up to set-point speed. The flying start feature handles motors already rotating due to back
pressure on the blades. They
will be smoothly accelerated to desired speed in the forward direction.
This greatly reduces stress on the fan blades, bearings, and belting
or coupling. Dynamic V/Hz further improves efficiency by reducing motor voltage
during low demand. AC
drives improve power factor (>0.95) and eliminate belt slippage by
reducing motor starting current to further reduce power demand from your
utility. Control
Techniques even helps you document energy savings by including a kWh energy
and running cost meters in the drive.
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Microcon Technologies Inc.
1105 Crestlawn Drive, Unit # D8 & D9
Mississauga, Ontario L4W 1A7 Canada
Tel: (905) 602-4770
Fax: (905) 602-4779
e-mail: [email protected]
Website: www.microcontechnologies.com