POWER FACTOR CORRECTION

 

Power factor corrections

Power factor – the measure of how efficiently power is being used – is a power quality issue that e facility should be familiar with. APS (Alabama Power Solutions) line of power factor correction products feature technology that is compatible with a variety of voltage applications to meet the needs of every industry. These robust solutions, which include fixed and automatic switched capacitors for low and medium-voltage applications, raise facility power factor to meet the requirements of any utility, helping to eliminate costly utility charges. 
What's the best way to correct my power factor and help restore line loss, eliminate lag, prolong the life of all motors and reduce my power bill?
***The simplest way of improving the power factor is to add capacitor banks to the electrical system. PF correction capacitors offset the reactive power used by inductive loads, thereby improving the power factor. That maximizes the current carrying capacity, improves the supply voltage, reduces transmission power losses, and lowers electricity bills.
We look forward to custom-building you world-class products that save you energy, money, and most importantly time. 

Need help determining the best PFC solution for you? Call us today at 206-615-4440 APS (Alabama Power Solutions) 

More information below...

What is unity power factor?

When power factor is at unity, the voltage and current waves are aligned or in phase with one another. This is expressed as a PF of 1.0.

What causes low power factor?

Power factor is driven by the number of inductive loads on a system. Many industrial and commercial electrical system loads are inductive, meaning they require reactive power (kVAR) to sustain a magnetic field needed in order for the equipment to operate, in addition to the kW which they use to perform work.  The larger the portion of a facility’s load that is inductive, the higher its kVAR draw from the utility and the lower its power factory will be. The loading of this type of equipment also plays an important role in a facility’s power factor.

How does low power factor affect motors?

Inductive loads always require the same amount of kVAR regardless of kW output, which results in motors operating at less than full load having extremely poor power factor. This often occurs in cycle processes where motors are sized for the heaviest loads, such as those using circular saws, ball mills, conveyors, compressors, grinders and punch presses. Low power factor at high loads can also be an issue. A facility operating at a high load has a higher current draw, which causes voltage to dip. Motors operate best at higher voltage levels, as low voltage can cause them to be sluggish or overheat.

How does low power factor affect consumers?

When the power factor is below 1.0 or unity, the utility must generate more than the minimum kVA required to provide kW, which increases utility costs. Most often, a utility company then passes these added costs on to the customer. However, by boosting the power factor to meet the utility’s minimum PF requirements, consumers can eliminate these costly charges.

Can APS (Alabama Power Solutions) review my utility bill?

Absolutely! Consumers may send utility bills to their local sales representative or use this email for a free evaluation and to help calculate potential savings.

 

How do utilities charge for power factor?

Utility companies assess power factor charges in a variety of ways. Sometimes tariffs are clearly identified on a utility bill, while in other instances they may be rolled into other costs. Three of the most common ways a utility will charge for power factor are through kW demand adjustments, kVA demand billing, and kVAR demand charges.

If the charge is not easily identifiable when reviewing your bill, you may obtain tariff details from the utility to better understand these extra charges. 

How can power factor correction units help lower utility charges?

Consumers can slash costly penalties by adding power factor correction capacitors to their facility distribution systems, as these units effectively lower kVAR demand. By adding capacitors as a local reactive current source to the system, they reduce the current drawn from the utility and improve voltage, resulting in more efficient motor performance and longer motor life.

What’s the difference between the two types of power factor correction capacitors – fixed and automatic?

Fixed capacitors supply a constant amount of correction (kVAR) to an electrical system, while automatic capacitors – also called switched capacitors ─ vary the amount supplied. Fixed capacitors are generally installed at individual motor loads, while automatic capacitors are installed at the main utility power entrance.

WHY IS POWER FACTOR SO IMPORTANT?

Written by: Andi

The specifications of any electrical appliance working on AC supply, such as a refrigerator, a toaster, a fan, etc., list a minimum of three important parameters – Voltage, Wattage and PF. The voltage rating indicates the nominal operating voltage of the appliance, the wattage rating indicates the power the appliance will use when switched on. The third parameter, PF, stands for the Power Factor – usually a value between 0.6 and 1.0.

All electrical appliances consume power for operating or working such as for lighting, heating, motion, etc. The appliance transforms a major part of the consumed power into its intended activity and the rest is wasted as heat. The ratio of the power converted to useful work to the total power consumed is the efficiency of the appliance.

Of the power converted to useful work, only a part is used as true or real power and the balance as reactive power. Engineers express real power in W (Watts) and reactive power as VAR (Volt-Amperes-Reactive). The appliance converts the real power into actual work, while it needs the reactive power to sustain a magnetic field and this does not directly contribute to the actual work done by the appliance. Therefore, the real power is also called the working power, while the reactive power is called non-working power. The sum total of the working and non-working power of an appliance is called its apparent power, expressed as VA (Volt-Amperes) and is the product of the nominal operating voltage and the current consumed by the appliance when operating.

This phenomenon of reactive power is true mostly for inductive appliances such as motors, compressors or ballasts. Power Factor is the ratio of the real or working power to the apparent power – an indication of how effectively the appliance will be using electricity. The problem is, although you will be paying the electricity utility for the entire apparent power consumed, the appliance will be converting only the real power into useful work for you. Therefore, a higher PF rating for your appliance works to your advantage – choose one with PF as close to 1.0 as possible.

In reality, low PF is also a headache for the utility supplying you with power. This is best explained with an example. Let us assume you have an operation that requires 100KW to run properly. If you install a machine that has a PF of 0.8, it will chalk up 125VA on the Apparent Power meter, but will convert only 80% of its incoming power into useful work. Since the electricity utility will have to supply both active and reactive power to its consumers, the wasted power ends up heating the conductors of the distribution system, resulting in a voltage drop at the consumers end.

The simplest way of improving the power factor is to add capacitor banks to the electrical system. PF correction capacitors offset the reactive power used by inductive loads, thereby improving the power factor. That maximizes the current carrying capacity, improves the supply voltage, reduces transmission power losses and lowers electricity bills.

 

WHY IS POWER FACTOR SO IMPORTANT?

Written by: APS

The specifications of any electrical appliance working on AC supply, such as a refrigerator, a toaster, a fan, etc., list a minimum of three important parameters – Voltage, Wattage and PF. The voltage rating indicates the nominal operating voltage of the appliance, the wattage rating indicates the power the appliance will use when switched on. The third parameter, PF, stands for the Power Factor – usually a value between 0.6 and 1.0.

All electrical appliances consume power for operating or working such as for lighting, heating, motion, etc. The appliance transforms a major part of the consumed power into its intended activity and the rest is wasted as heat. The ratio of the power converted to useful work to the total power consumed is the efficiency of the appliance.

Of the power converted to useful work, only a part is used as true or real power and the balance as reactive power. Engineers express real power in W (Watts) and reactive power as VAR (Volt-Amperes-Reactive). The appliance converts the real power into actual work, while it needs the reactive power to sustain a magnetic field and this does not directly contribute to the actual work done by the appliance. Therefore, the real power is also called the working power, while the reactive power is called non-working power. The sum total of the working and non-working power of an appliance is called its apparent power, expressed as VA (Volt-Amperes) and is the product of the nominal operating voltage and the current consumed by the appliance when operating.

This phenomenon of reactive power is true mostly for inductive appliances such as motors, compressors or ballasts. Power Factor is the ratio of the real or working power to the apparent power – an indication of how effectively the appliance will be using electricity. The problem is, although you will be paying the electricity utility for the entire apparent power consumed, the appliance will be converting only the real power into useful work for you. Therefore, a higher PF rating for your appliance works to your advantage – choose one with PF as close to 1.0 as possible.

In reality, low PF is also a headache for the utility supplying you with power. This is best explained with an example. Let us assume you have an operation that requires 100KW to run properly. If you install a machine that has a PF of 0.8, it will chalk up 125VA on the Apparent Power meter, but will convert only 80% of its incoming power into useful work. Since the electricity utility will have to supply both active and reactive power to its consumers, the wasted power ends up heating the conductors of the distribution system, resulting in a voltage drop at the consumer end.

***The simplest way of improving the power factor is to add capacitor banks to the electrical system. PF correction capacitors offset the reactive power used by inductive loads, thereby improving the power factor. That maximizes the current carrying capacity, improves the supply voltage, reduces transmission power losses, and lowers electricity bills.

 More...

Power Factor Correction Benefits

A Voltage Correction System with Power Factor Correction built in will provide an incredible amount of benefits to your facility beyond satisfying the Utility Provider requirements. While correcting the power factor with an AVC you can also stabilize your power internally to your facility and create many additional benefits along the way.

Power Factor Problems

Several negative issues can derive from a low power factor including penalties assessed from your utility provider, higher demand use charges, and decreased capacity in your electrical and breaker distribution system. When you install equipment that will correct power and hold voltage, you can also accommodate power factor issues.

 

What causes low power factor?

Inductive motor loads in a facility have largest effect on Power Factor. Many manufacturing and process facilities across industries have a Power Factor issue. Many utility providers are paying attention, issuing guidance, and in many cases issuing fines for it. Many Utilities are enforcing Power Factor level to maintain above .85. This is nearly impossible for many industry equipment.

These loads have a negative effect and create power factor issues:

  • Induction Motors
  • Pumps
  • Conveyors Arc Elders
  • Flourescent Ballasts

The results are:

  • Higher Facility Operations cost
  • Higher utility peak demand
  • Lower capacity in your facility's electrical distribution

Low power factor means lower operating efficiency which results in a need for larger conductors (wires) and increased equipment capacity, as well as causing voltage drops as power losses increase. These equate to higher capital investment, higher expenses, and diminished distribution system performance. Correcting power factor can bring significant savings in energy bills if the utility imposes a low power factor penalty in their rate structure, as most utilities do for industrial customers.

When you install equipment that will correct power and hold voltage, you will be providing your facility with additional operational and cost benefits. Wear and tear on other equipment in the facility by having stable voltage and power factors. Lower maintenance costs by limiting voltage and amperage anomalias inside the facility.

 

Have an APS (Alabama Power Solutions) site survey done to survey your facility and install a power metering device. 

We are available to review electrical one-lines, Power Reports, Demand Usage, and any other data on your facility's power.

Call your APS (Alabama Power Solutions) Technical Representative today to discuss options to increase efficiency in your facility and correct our facility power issues! 205-615-4440