One Stop Heat Exchanger Information

With today’s rising energy demands, volatile financial & housing markets and a constant potential of increased living costs looming over our shoulders, catching a financial break anywhere we can as a consumer should be of keen interest to everybody. 90%+ Annual Fuel Utilization Efficiency (AFUE) furnaces may easily provide the solution and can easily off set a household bill or two with all of the energy being saved by this furnace in contrast to the conventional 60-80% AFUE furnace that is more than likely currently in your home even as you read this article. 90%+ AFUE furnaces have a 2 heat exchanger design to avoid wasting heat, in the past the product was problematic when it was first developed in the 90′s, but has since been improved to near perfection today by most manufacturers to be a very reliable product and if sized properly and installed properly will save an incredible amount of money on the utility bill that you can capitalize on year in and year out.

The two heat exchanger design is the key feature that allows a 90%+ AFUE furnace to operate so efficiently. A primary heat exchanger handles the ignition of the furnace and the natural gas fire (propane, kerosene, heating oil or what ever the furnace burns) of the furnace burners. As the burners are engaged inside of the heat exchanger, the heat exchanger gets hot so that when the furnace blower turns on, forced air travels over the hot heat exchanger to allow for heat transfer to occur, sending warm air through your air ducts and to ultimately heat the air in your home. With a conventional 60-80% AFUE furnace that is all that is present for a heat exchanger, but through brilliant engineering furnace manufacturers realized that flue gases always creates hot moisture that is typically wasted out of the flue pipe and so they decided to capture this free energy by designing a better product. So engineers went to work to produce the two heat exchanger furnace and incorporated a secondary heat exchanger that looks like a coil to capture the hot flue gas moisture to re use this heat in a more efficient appliance, rather than wasting this heat out of the flue pipe.

Remarkably after 70 years of relatively little change in the heating market in terms of how a furnace basically operated, a vastly more efficient appliance emerged on the market. Two stage technology emerged as well, where engineers realized that a furnace did not necessarily have to high fire gas at all times to effectively heat your home, due to varying weather outside of your home. The two stage gas valve emerged to where a low fire predominately occurs on temperate (less cold) winter days saving an additional 25-35% on gas consumption and then when the weather gets real cold outside the furnace can engage a high fire to ensure that the appliance can keep up with heating your home only when high fire is truly needed, to ensure that the homeowner gets the best of both worlds; saving money and staying comfortable.

A conventional furnace is missing these features, because the conventional furnace can only fire in one stage and just wastes flue gas moisture out of the flue pipe. The venting of a 90%+ AFUE furnace is typically done with PVC piping material and most often is vented to the exterior side of a home. The 90%+ AFUE furnace burns and exhausts vastly more cleaner gases than a conventional furnace effectively lowering emissions as well, so you can feel good about doing your part in the environment when you have a 90%+ AFUE furnace installed in your home.

Some contractors are afraid to install a 90%+ AFUE furnace in your home due to lack of training and an inability to successfully repair furnaces in the first place. One legitimate complaint and or criticism that was true in the past, that these contractors would make, is that parts were more expensive on a 90%+ AFUE furnace and why on earth would you want an expensive repair bill they would ask. That all came to an end when Rheem manufacturing designed their new line of 95% AFUE 2 stage furnaces. All parts selected to make the Rheem 95% AFUE 2 stage furnace work are of quality durable design, but cost effective to repair after the furnace warranty expires.

This would not be the case with the expensive Carrier induced draft motors and chip boards or the expensive chip boards used by Trane and American Standard or all parts by Lennox being of higher expense in their product lines of 90%+ AFUE furnaces. Furthermore, Rheem realized that the primary heat exchanger was the most expensive part of the furnace, so they decided to make a primary heat exchanger tougher than any other manufacturers primary heat exchanger.

The Rheem primary heat exchanger is constructed of stainless steel and is of a tubular design with virtually no seam points present on the part, kind of like a car tail pipe, which rarely breaks. Eliminating seam points on the heat exchanger increases the life span of the part. On the contrary, the Lennox, Carrier, Trane and American Standard heat exchangers are a cheaper clam shell design that is no where near as strong as the tubular designed heat exchanger. The clam shell designed heat exchanger is designed to last a certain amount of years, but once enough time goes by these heat exchangers typically fail due to 4 sides of crimped seams separating the heat exchanger, leading to part failure.

Not only is the Rheem 90%+ AFUE line of furnaces tougher and built with cost effective parts in mind, but they even went as far as ensuring that all Rheem furnaces operate at a vastly lower decibal range making the Rheem furnace the quietest class of furnaces in the residential market today. Carrier, Trane, American Standard and Lennox furnaces will work and if sized and installed properly will last for many years, however when they break, you will surly pay a pretty penny to get them fixed.

When you call out an HVAC company or contractor to perform an in home estimate to install your 90%+ AFUE furnace, make sure that they are evaluating your whole house. Proper furnace sizing will involve an estimator to evaluate wall insulation type, attic insulation type, home exposure, window type, slab type, outdoor landscape, fire places present, duct sizing, how many people occupies the space as well as a few other factors too.

Be leery of the estimator that is in and out of your home in 30 minutes or less, because getting it right during the estimate phase will have a huge effect on achieving maximum efficiency of the furnace and your over all indoor comfort for many years to come. Most of the estimates that reputable heating and air conditioning companies perform may require between 1-2 hours to gather all necessary data, answer customer questions and to write an up front price to do the work.

There are many like minded good companies and contractors out there that conduct themselves that way as well. Your best bet would be to just call out an ACCA member company to perform the estimate, because an ACCA member company will operate professionally, follow higher HVAC standards and receives accredited support in training, up to date trade information and will be up to date with new techniques and standards in the HVAC field. Visit www.acca.org and use the contractor zip code locator to find an ACCA member company near you.

Cleaning your heat exchanger tubes is a job anyone can do if they know how. If you are a do it yourself then you should have no trouble with this task.

There are several methods to clean exchanger tubes. Here are a few of them; one is to use chemicals for the cleaning. Another is to use high-pressure water system. One last method is to employ mechanical cleaning using brushes, scrapers and abrasive balls. These are the best ways to clean the tubes.

Regular cleaning of the exchanger tubes should prolong the life of the entire unit. It will help it work at its maximum efficiency as well.

Many people use a heat exchanger system to heat their swimming pools these days. Having the ability to clean your own exchanger tubes would be a good way to save money and keep your system in top working order.

It would be beneficial to clean the exchanger tubes every few months. At least inspect them to see if they need to be cleaned. If they do not need to be cleaned, and then make sure that, they are thoroughly cleaned twice a year.

In order to clean the exchanger tubes properly, they must be removed from the system. Remove any loose material that is near the ends of the tubes and inside them as well. Use a brush and push it down the tube to get the cleaning started. The brush should have good strong nylon bristles. This helps to loosen and remove any loose materials inside.

During this brushing process, you may find that there is some material stuck to the sidewall of the exchanger tube. A plastic or metal scraper will help to remove anything that is stuck to the wall. Be careful not to damage the tube. Do not use a scraper that is harder than the material of the wall of the tube.

Try not to scratch the wall of the exchanger tubes as it could cause the tube to not function as well as it should because particles could stick to the scratches in the tube. Therefore, a plastic scraper would be best.

As a last step in cleaning the exchanger tubes, you could use a water jet to force out any loose particles that were missed with the previous methods. If you have any calcium deposits on the tubes then you will need chemicals to remove them.

Now you have the basics for cleaning your exchanger tubes. Gather as much information as possible before tackling this do it yourself job.

A heat exchanger is a device that is used to transfer heat from one fluid to another fluid and at the same time preventing the two fluids from coming in contact with one another. There are three main types of heat exchanger. They are as follows:

• air-cooled
• shell and tube
• plate heat exchangers

Dividing the two fluids is usually a metal wall, which acts as a conductor. On one side of the wall is a hot solution, which, while flowing transfers its heat to the cooler solution that is flowing on the other side of the wall.

If the surface area of the heat exchanger is larger then it will create a faster heat transfer. Thermal energy will only flow from a hotter area to a cooler area in order to reach a point of equilibrium.

A heat exchanger can be known by other names as well. For example, in a car, the radiator that acts as an exchanger. The radiator cools the hot fluid by using the airflow over the surface of the radiator.

Other examples of some uses for these devices are swimming pool heating, air conditioners, refrigerators and hot water radiators.

Whether a heat exchanger is used in an industrial or a commercial setting, they are considered very important energy saving devices.

A heat exchanger is usually constructed of cast iron, aluminum, and steel, titanium, bronze or copper. Manufacturers find that one of the biggest problems with these devices is corrosion. This is due to the constant flowing of liquid in these devices.

Manufacturers are always looking for ways to prevent this from happening. The manufacturers are using tubing that is resistant to basic corrosion. They have been creating heat exchangers that feature fins to provide better thermal conductivity. They have found that this has been helping prevent some corrosion.

You will find a heat exchanger in many different types of industry. This would include pulp and paper, pharmaceutical, steel industries, marine, automotive and water treatment plants.