The Copper in Your Central Air Conditioning Systems Outdoor Condenser: Is It Easy Prey for Vandals?

As copper prices have risen over the past few years, copper theft has become a major problem across the nation. Thieves will target anything that has copper, but one of their easiest targets is air conditioner units. An air conditioner condenser sits outside and is easily accessible for thieves to dismantle surprisingly quickly.

The Cost of Copper Theft

Although copper thieves will only net a modest sum for the copper from an air conditioner condenser, homeowners often pay dearly for the thieves’ wrongdoing. Depending on current prices in the area, a thief will generally net about $20 from one residential air conditioner. If copper prices are high, he may get up to $75 from a large commercial one.

Homeowners, on the other hand, are often faced with significantly higher repair bills. Even if the damage is covered by homeowner’s insurance, you’ll likely still have to pay a hefty deductible.

Preventing Copper Theft

Homeowners, however, aren’t defenseless in the fight against copper thieves. Below are some steps homeowners can take to keep their homes safe and deter thieves from stealing the copper in their air conditioner condenser.

•Block the air conditioning unit from view - This is the easiest and most affordable precautionary measure, but it’s also the least effective. Bushes or a little fence can be placed around the air conditioning unit to hide it slightly, but keep in mind that in order for your condenser to run effectively, you need a clear radius immediately surrounding the unit for proper airflow.

•Install lights around the air conditioner - In addition to screening the air conditioner from view, motion lights can be installed around it. Thieves will be less likely to steal copper if they know they’re easily visible.

•Place the air conditioner in a cage - Several companies manufacture lockable air conditioner cages which surround the outdoor unit. Not only do these cages deter thieves, but they also protect units from hail, small branches and other debris.

A Homeowner’s Responsibility

Every homeowner must decide what lengths to go to to deter thieves from stripping the air conditioner condenser of copper. For more information about how you can best protect your unit, or for any other home comfort questions, contact the pros at Action Heating and Air Conditioning. We’re proud to serve homeowners throughout Northeast Florida.

A/C Duct Assessment

Seal in Your Savings with Duct System Repairs
Some information from Florida Power and Light Company

Leaky ducts can cause your electric bill to increase. When your cooling and heating duct system has leaks or holes in it, air is allowed to escape into the attic, which ends up wasting energy and costing you money. In fact, 50 percent of all homes have leaky ducts.

Duct Test

FPL representatives can visit your home and test your duct system. If repairs are needed, you might be entitled to an FPL rebate.

Schedule your home energy survey duct test online today or call 1-800-DIAL-FPL (1-800-342-5375).

Pay just $30 for the first central air conditioning system inspected and $15 for each additional air handler if your home is a single-family detached home.
You'll get a detailed repair report along with a list of Participating Independent Contractors (PICs)* who are qualified to make required repairs.

Rebates for Duct System Repair
FPL also provides incentives to help cover the cost of repairs. Receive up to $154 per central A/C system for single-family detached homes.
Receive $60 for multi-family, single-family attached homes, manufactured, and mobile homes. For these home types, there is no test fee.

What are the Qualifications?
Single-family and multi-family homes that have the duct system accessible qualify.
If a home has had a Duct test performed within the last 12 months, the home does not qualify for a new test.
If a home had an FPL WattSaver incentive redeemed within the last 12 months, the home does not qualify for a new test.
Multi-family homes with chimneys and gas appliances are NOT eligible unless there is a firewall between homes.

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

OIL FURNACE TIPS

Operating an oil furnace does require slightly more maintenance than most other types of furnaces. There are many similarities but also additional extra steps that need to be taken to assure a long lasting and trouble free heating system. Many simple steps can be taken by the homeowner themselves to prevent premature breakdown. Always follow your users manual and do shut off any power supplies before attempting any maintenance other than filter replacement.
Regular maintenance:

All furnaces should have regular maintenance. Furnace filters should be replaced on a regular basis. Follow the guidelines by the filter manufacturer and in households with with a large number of pets, or a sandy outdoor environment, it is sometimes beneficial to replace the filter more frequently than suggested.

Older blower motors may require a yearly oiling. Newer sealed units do not. If you have a belt driven system, check the belt for wear or cracking and replace if needed. Check and clean your thermostat for accumulated dust and debris. If you have a mercury based thermostat be sure it is not out of level.

Keep you return air and registers clean and unobstructed to allow for proper air flow. Your furnace needs proper air flow to function and a build up of heat inside the system can damage it.

Specific maintenance for oil furnaces:

Keeping an oil furnace clean is a major part of the maintenance required. Oil furnaces do produce a greasy soot and this can lead to build up quickly. Clean the blower before the first start up of the heating season and again mid-way through the season. Also clean any soot from the stack control.

Oil filters should be cleaned or replaced at the beginning of the season and again about halfway through. Follow your owners manual for instructions. Most oil furnaces have a filter assembly similar to automotive oil filters and are not extremely difficult to replace.

If your furnace has an oil strainer this should also be cleaned when you replace your oil filter. Again you should follow instructions from your owners manual for your particular furnace. If your strainer shows any signs of damage it should be replaced. Debris in the oil can damage your oil pump and cause premature system failure.

Always check for any oil leaks in your tank or supply lines. Leaks will require professional repair but the earlier they are caught the better off you will be. You should also check the color of the smoke coming from your chimney. Black smoke is an indication of improper burning and will require professional adjustment.

Your oil furnace should serve you well, the most important thing is to keep it clean and free of soot build up. Cleaning and filter replacement on a regular basis will help keep your oil furnace trouble free.

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

KANO KROIL

RESEARCH REPORT
Molecular Structure Key to Loosening Frozen Metal Parts

Kano Laboratories isolated the interdisciplinary physical, electrical, and chemical properties, which cause the common industrial problem of frozen metal parts.

Corrosion, compression, chemical reactions, thermal variations, and electrical interrelationships are the primary factors which contribute in varying degrees to frozen metal parts. For example, in some instances loosening a frozen metal part requires that the molecular bond of oxidation be broken in an often-inaccessible location that literally exists in infinitely small spaces. Based on a unique proprietary formula and manufacturing process, Kano created a molecule which had an inherent means of expedient self propulsion which would penetrate into spaces which are immeasurably small. In the lab, it was nicknamed Creeping Oil, i.e. Kreeping Oil, i.e. Kroil. To these penetrating properties were added the ability to disrupt the existing corrosive bond while remaining chemically neutral to the base metal. Since not all frozen parts are caused by corrosion, additional research has provided for the inclusion of other molecular properties assuring that the final molecular architecture would also be capable of loosening frozen metal parts when other factors such as compression were more responsible for the problem. The result of the research is Kroil, the world's largest selling penetrating oil.

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

WINTER FUEL OUTLOOK

WASHINGTON — According to the U.S. Energy Information Administration (EIA) Short-Term Energy and Winter Fuels Outlook, the EIA expects higher prices this winter for homes that heat with natural gas, propane, and electricity. Home heating oil prices are expected to be lower than last winter.

Forecast temperatures are close to last winter with the Northeast about 3 percent colder and the West 3 percent warmer.

Projected changes in residential expenditures from last winter are:

• 13 percent higher for homes that heat primarily with natural gas;

• 9 percent higher for propane;

• 2 percent higher for electricity; and

• 2 percent lower for heating oil.

Although natural gas expenditures are significantly higher than last winter, they are still lower than the average of the previous five winters (October 2007 – March 2012).

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

CONSUMER COMFORT DEPENDS ON HUMIDITY CONTROL

Comfort, Health Big Factors in Controlling Moisture



Here is an article I thought our readers would be interested in. This article comes from "the Air Conditioning|Heating|Refrigeration News":

When it comes to IAQ, humidity plays an influential role in the health, safety, and comfort of occupants in buildings and homes. Settling this uncertainty falls solely on the shoulders of HVACR contractors, who admittedly devote a lot of their time to solving and controlling such climate conundrums.
Finding the Comfort Zone
When it comes to IAQ, humidity plays an influential role in the health, safety, and comfort of occupants in buildings and homes.“There’s a certain humidity range we humans like to live within,” said Rick Tullis, president, Capstone Mechanical, LP, Waco, Texas. “If we start getting outside those parameters, bad things start to happen with the illnesses that come upon us, impacting everything from our skin and sinuses, making us more susceptible to different viruses and bacteria. We like a certain range, ideally, and other organisms do, too.
“Some of the molds and other creatures like it when it’s really moist, and they start to do bad things to our homes, our structures, our buildings, and beyond,” he said. “With all that being said, we have to work to keep things within the right range.”
When humidity is kept to a certain level — ASHRAE recommends between 30-60 percent relative humidity for homes — air moisture-related issues are kept at bay.
“If you don’t have moisture, you don’t have mold, period,” said Larry Pearson, owner, Panoramic Building Performance Solutions, Bradenton, Fla. “When people say they have a mold problem, I tell them they have a moisture problem. A mold problem is always a moisture problem. End of story. You’ve got to control humidity if you want to control mold. If you create an environment inside of a building with acceptable humidity levels, you won’t have a mold problem unless there’s a plumbing leak or something like that.”
The moisture that is humidity presents some challenges in all applications. Tullis said his company recently had a job at a library in a special room for old, archived materials. He said, because of the condition of the materials, there was a very thin temperature and humidity range to be adhered to. He said this required some precise equipment and controls.
On the other hand, Tullis has found himself dealing with a broad range of issues involving humidity throughout his career. “We’ve had some experiences in a diaper plant,” Tullis said. “What goes into diapers? It’s little pellets that love to absorb moisture. This diaper plant had been designed by people from up north who weren’t used to the temperature and humidity challenges we have here in Texas. As a result, they had a building that had a very high relative humidity, which was causing the pellets to absorb moisture and expand in the manufacturing delivery pipes. Those pipes clogged because the pellets were absorbing the moisture and expanding. We encounter all kinds of fun scenarios like that.”
Lew Harriman, director of research, Mason-Grant Consulting, Portsmouth, N.H., said a firm grasp on humidity will provide comfort and save energy.
“Those are the two big reasons,” he said. “Lurking behind that are things like mold prevention. You really have to screw up in a major way to have mold problems in a building. More than one thing has to go wrong to have a mold problem. … If you don’t control humidity, people will use the thermostat to try to achieve comfort by forcing down the temperature set point, then lots of bad things happen. Energy gets all crazy because you’re using energy to do a job that’s difficult to do, and it also creates cold surfaces, which is when you get into the risk of mold. So if you don’t control humidity independently of the temperature set point, you will be using the temperature set point to control it. That’s where the energy and comfort problems come in, and that’s true in both light commercial and residential settings.”
Tullis agreed, stating that if the humidity varies wildly, comfort levels could be all over the board, regardless of the temperature.
On spring and fall days in Texas, where it could be 75˚F in the morning — which isn’t quite hot enough to turn on the air conditioning in Texas but the humidity is raging around 90 percent — it creates a problem for commercial buildings like schools that have to bring in a certain amount of fresh air to comply with ventilation standards.
“It definitely gets tougher when you get into many of the commercial settings because you’re dealing with so much more outside air,” Tullis said. “If you’re getting involved in auditoriums or office buildings, you have to bring in so much more outside air to meet the ventilation code that it really creates some interesting challenges on maintaining the right humidity range. Whereas in residential, you’re dealing with a fairly small people load, so there’s not as big of a need for outside air. There is some need, but it’s not nearly as much.”
In homes, controlling humidity plays a very big, albeit somewhat indirect, role in assessing IAQ, Harriman said.
“If the humidity is high, IAQ contaminants that exist in furniture and furnishings are more likely to get into the air,” he said. “The desorption rate of IAQ contaminants from those things rise as the humidity rises. Secondly, the perception of IAQ is very much related to whether it’s cool and dry, or cool and damp, or hot and damp. If you don’t control humidity, the perception, the annoyance factor of any level of IAQ contaminants goes up.”
Pearson, who joked the gates only opened to Florida once air conditioning was invented due to the subtropical climate and high humidity there, said a little bit of humidity won’t kill a building, as long as the equipment is running a few hours later to dry things out.
But it all comes down to making sure the job is done right, he added. “At the end of the day, if you keep it clean and keep it dry, you’re good to go,” Pearson said. “That’s a lot easier said than done, though. It costs a lot of money to properly design, install, and maintain HVAC systems. The other thing, too, is in Florida there are thousands and thousands of buildings that weren’t properly built. From day one, they weren’t designed or built properly to handle the conditions in Florida.”
Whether in a commercial building or inside a home, Harriman encouraged installing equipment designed to dry the ventilation air. “You have to dry the ventilation air to a 50° dew point, maybe 55°. But if you don’t dry the ventilation air all the time to that dew point, it’s going to be very tough to control the humidity in a way that doesn’t cause problems with comfort and energy, and that’s a really sad fact, but you have to do it,” he said. “People don’t want to do it because it costs money and is an extra piece of equipment, but if you do this, all your problems go away. And if you don’t do this, your problems will persist.
“There’s many ways to mitigate the problem. You can do it with controls, with the fancy furnaces and a/c systems, but you’ll always have difficulties until you dry the ventilation air, because that’s where the humidity comes from.”
Publication date: 8/12/2013

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

WHY SEER RATINGS ARE IMPORTANT

You may have heard about SEER ratings. Today, we’ll go over what these ratings mean and why they matter. SEER is all about efficiency, so anyone installing a new A/C system or replacing an old one should know what their new unit’s SEER rating is. It affects your energy costs in the long term, as well as the performance of your cooling system. In a hot, humid climate like ours, this is especially relevant. Air conditioners here have to work hard to keep homeowners comfortable, so energy efficiency is pretty important.

SEER stands for Seasonal Energy Efficiency Ratio. The U.S. Department of Energy established this designation to educate consumers about the energy efficiency of air conditioning units. SEER is the ratio between the cooling of the unit over one season and the total energy it consumes during that same period. So, the figure measures the overall efficiency of the unit over an entire cooling season.

The higher the SEER rating, the higher the efficiency of the unit. For you, a higher SEER means lower energy costs each month. So, although these high SEER systems cost more up front to buy, they usually pay for themselves in energy savings within a few years.

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

Sept. 9, 2013: Development of Natural Refrigerant Heat Pump Receives DOE Grant

Some interesting information from the Air Conditioning|Heating|Refrigeration News:

NASHVILLE, Tenn. — Part of a U.S. Department of Energy (DOE) project to reduce energy bills and greenhouse gas emissions, S-RAM Dynamics has been awarded a grant to help commercialize a new natural refrigerant heat pump.
According to the company, the heat pump will also reduce energy consumption for commercial and industrial customers by more than 50 percent when compared to other common air conditioning and heating systems. The system is being developed in coordination with Purdue University and performance testing will be done at DOE’s Oak Ridge National Laboratory.
“This is a big award for us. Energy efficiency and greenhouse gas emissions are major concerns, and the DOE recognized the potential impact of the new heat pump using our company’s proprietary compressor and expander technology,” said Lee Jestings, S-RAM president.
Assistant Secretary for Energy David Danielson announced the selection of the S-RAM technology as part of the “Next Generation Energy Efficient Buildings Technologies” program. According to Danielson, “Energy efficient technologies — from improved heating and cooling systems to better windows and lighting — provide one of the clearest and most cost-effective opportunities to save consumers money while curbing greenhouse gas emissions.”
“We are excited to be part of testing S-RAM’s technology and to assist them with commercializing this heat pump,” said Dr. Eckhard Groll, the Reilly Professor of Mechanical Engineering at Purdue University. “This technology can eliminate the use of high global warming refrigerants and improve energy efficiency while providing comfortable and productive indoor environments for occupants.”
S-RAM Dynamics holds 47 patents for its variable power conversion technology. For more information, visit www.s-ram.com.
Publication date: 9/9/2013

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

ALLERGIES

Indoor air quality (IAQ) is a term which refers to the air quality within and around buildings and structures, especially as it relates to the health and comfort of building occupants. IAQ can be affected by gases (including carbon monoxide, radon, volatile organic compounds), particulates, microbial contaminants (mold, bacteria) or any mass or energy stressor that can induce adverse health conditions. Source control, filtration and the use of ventilation to dilute contaminants are the primary methods for improving indoor air quality in most buildings. Residential units can further improve indoor air quality by routine cleaning of carpets and area rugs. EPA has guidelines for frequency of cleaning based on traffic, number of household members, pets, children and smokers. Carpets and rugs act like an air filter and must be cleaned.

If you think that you are having issues with your indoor air quality, give us a call and let us help. We have UV-Lites, Speciality Filters, along with other products that can help with your indoor air quality.

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.

THERMAL EXPANSION VALVE

A thermal expansion valve (often abbreviated as TEV, TXV, or TX valve) is a component in refrigeration and air conditioning systems that controls the amount of refrigerant flow into the evaporator thereby controlling the superheating at the outlet of the evaporator. Thermal expansion valves are often referred to generically as "metering devices".
Flow control, or metering, of the refrigerant is accomplished by use of a temperature sensing bulb, filled with a similar gas as in the system, that causes the valve to open against the spring pressure in the valve body as the temperature on the bulb increases. As the suction line temperature decreases, so does the pressure in the bulb and therefore on the spring causing the valve to close. An air conditioning system with a TX valve is often more efficient than other designs that do not use one.
A thermal expansion valve is a key element to a heat pump; the cycle that makes air conditioning, or air cooling, possible. A basic refrigeration cycle consists of four major elements, a compressor, a condenser, a metering device and an evaporator. As a refrigerant passes through a circuit containing these four elements, air conditioning occurs. The cycle starts when refrigerant enters the compressor in a low pressure, low temperature, gaseous form. The refrigerant is compressed by the compressor to a high pressure-and-temperature gaseous state. The high pressure-and-temperature gas then enters the condenser. The condenser precipitates the high pressure-and-temperature gas to a high temperature liquid by transferring heat to a lower temperature medium, usually ambient air. The high temperature liquid then enters the expansion valve where the TX valve allows a portion of the refrigerant to enter the evaporator. In order for the higher temperature fluid to cool, the flow must be limited into the evaporator to keep the pressure low and allow expansion back into the gas phase. The TXV has sensing bulbs connected to the suction line of the refrigerant piping. The sensing bulbs give temperature readings to the TXV to adjust flow of refrigerant.

FUNCTION IN A REFRIGERATION CYCLE

Expansion valves are flow-restricting devices that cause a pressure drop of the working fluid. The valve needle remains open during steady state operation. The size of the opening or the position of the needle is related to the pressure and temperature of the evaporator. There are three main parts of the expansion valve that regulate the position of the needle. A sensor bulb, at the end of the evaporator, monitors the temperature change of the evaporator. This change in temperature creates a change in pressure on the diaphragm. For example, if the temperature in the evaporator increases, the pressure in the diaphragm increases causing the needle to lower. Lowering the needle allows more of the working fluid into the evaporator to absorb heat. The pressure at the inlet of the evaporator affects the position of the needle and prevents the working fluid from flowing back into the compressor. Since the pressure before the valve is higher than the pressure after the valve, the working fluid naturally flows into the evaporator. The pressure at the inlet of the evaporator acts on the diaphragm. There is also a spring providing a constant pressure closing the valve needle. The spring constantly restricts the amount of working fluid entering the evaporator. The pressure spring can be adjusted to increase or decrease pressure based on temperature needs. The pressure created by the spring acts on the opening of the valve. When the pressure of the sensor bulb acting on the diaphragm is greater than the combined pressure of the evaporator and spring, the valve opens to increase the flow of the working fluid. An increase of flow lowers the temperature of the evaporator and allows for more heat absorption.

TYPES OF THERMAL EXPANSION VALVED

There are two main types of expansion valves: internally or externally equalized. The difference between externally and internally equalized valves is how the evaporator pressure affects the position of the needle. In internally equalized valves, the evaporator pressure against the diaphragm is the pressure of the outlet of the expansion valve, whereas in externally equalized valves, the evaporator pressure against the diaphragm is the pressure of the outlet of the evaporator.

Our goal is to help educate our customers about energy and home comfort issues (specific to HVAC systems). For more information about Indoor Air Quality and other HVAC topics, click here to visit our website.