Friday, September 26, 2008

Heat Pump Prices

Heat pumps are energy efficient devices used for both heating and cooling a home or small area. They are great in that they use very little electricity and produce minimal emissions in comparison to traditional furnaces and home heating devices. People often wonder about heat pump prices when they are considering having one installed in their home.

The initial investment into a heat pump can be quite costly. The prices are typically higher than the air-source pumps. An average size heat pump will cost approximately twenty-five hundred dollars per ton of capacity. An average house would need a heat pump of approximately three tons. This means that you would expect to pay approximately seventy-five hundred dollars to have a heat pump installed in your home. People are often put off by the initial price but in the long run they can expect to save a great deal of money using this machine.

There are two different types of heat pumps that you can install in your home. There are the ground source heat pumps, which are more energy-efficient than air heat pumps. The ground source heat pumps do not demand extra electrical heaters and they output less carbon dioxide. All heat pumps have been reported to have excellent performance in extreme temperatures and even work wonderfully during extreme cold temperatures.

The installation process of a heat pump can take about two to three days. You can expect to add this to the price of the unit because you have to pay for the labour that it takes to install the machine. When looking to have your heat pump installed you should look for a company that has extensive experience in this area so that they do not have to take extra time to figure out what they are doing. This will keep the total price of your unit that much lower.

For more information on heating and air conditioning and other related topics, visit Homeclimate at http://www.homeclimate.biz

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Sunday, September 7, 2008

Pump Information and Detail

This is a good article which provide good explanation on pump used in the processing industry.

Pumping of liquids is universal in chemical and petrochemical processes. The many different materials being processed require close attention to selection of materials of construction for various pump parts, shaft sealing, and the hydraulics of the individual problems. A wide variety of pump types have been developed to satisfy special conditions found in chemical plant systems; however, since all of these cannot be discussed here, the omission of some does not mean that they may not be suitable for a service. In general, the final pump selection and performance details are recommended by the manufacturers to meet the conditions specified by the process design engineer. It is important that the designer of the process system be completely familiar with the action of each pump offered for a service in order that such items as control instruments and valves may be properly evaluated in the full knowledge of the system.

A pump is a physical contrivance that is used to deliver fluids from one location to another through conduits. Over the years, numerous pump designs have evolved to meet differing requirements.

The basic requirements to define the application are suction and delivery pressures, pressure loss in transmission, and the flow rate. Special requirements may exist in food, pharmaceutical, nuclear, and other industries that impose material selection requirements of the pump. The primary means of transfer of energy to the fluid that causes flow are gravity, displacement, centrifugal force, electromagnetic force, transfer of momentum, mechanical impulse, and a combination of these energy-transfer mechanisms. Gravity and centrifugal force are the most common energy-transfer mechanisms in use.

Pump designs have largely been standardized. based on application experience, numerous standards have come into existence. As special projects and new application situations for pumps develop, these standards will be updated and revised. Common pump standards are:

1. American Petroleum Institute (API) Standard 610, Centrifugal Pumps for Refinery Service.
2. American Waterworks Association (AWWA) E101, Deep Well Vertical Turbine Pumps.
3. Underwriters Laboratories (UL) UL 51, UL343, UL1081, UL448, UL1247.
4. National Fire Protection Agency (NFPA) NFPA-20 Centrifugal Fire Pumps.
5. American Society of Mechanical Engineers (ASME).
6. American National Standards Institute.
7. Hydraulic Institute Standards (Application).

These standards specify design, construction, and testing details such as material selection, shop inspection and tests, drawings and other uses required, clearances, construction procedures, and so on.

The most common types of pumps used in a chemical plant are centrifugal and positive displacement. Occasionally regenerative turbine pumps, axial-flow pumps, and ejectors are used.
Modern practice is to use centrifugal rather than positive displacement pumps where possible because they are usually less costly, require less maintenance, and less space. Conventional centrifugal pumps operate at speeds between 1200 and 8000 rpm. Very high speed centrifugal pumps, which can operate up to 23,000 rpm and higher, are used for low-capacity, highhead applications. Most centrifugal pumps will operate with an approximately constant head over a wide range of capacity.

Positive displacement pumps are either reciprocating or rotary. Reciprocating pumps include piston, plunger, and diaphragm types. Rotary pumps are: single lobe, multiple lobe, rotary vane, progressing cavity, and gear types. Positive displacement pumps operate with approximately constant capacities over wide variations in head, hence they usually are installed for services which require high heads at moderate capacities. A special application of small reciprocating pumps in gas processing plants is for injection of fluids (e.g. methanol and corrosion inhibitors) into process streams, where their constant-capacity characteristics are desirable.

Axial-flow pumps are used for services requiring very high capacities at low heads.

Regenerative-turbine pumps are used for services requiring small capacities at high heads. Ejectors are used to avoid the capital cost of installing a pump, when a suitable motive fluid (frequently steam) is available, and are usually low-efficiency devices. These kinds of pumps are used infrequently in the gas processing industry.

To properly accomplish a good and thorough ratinghizing of a centrifugal pump, the plant system designer should at a minimum do the following.

1. Understand the fundamentals of performance of the pump itself.
2. Understand the mechanical details required for a pump to function properly in a system.
3. Calculate the friction and any other pressure losses for each "side" of the pump, suction, and discharge.
4. Determine the suction side and discharge side heads for the mechanical system connecting to the pump.
5. Determine the important available net positive suction head (NPSH,) for the pump suction side mechanical system, and compare this to the manufacturer's required net positive suction head (NPSH,) by the pump itself. This requires that the designer makes a tentative actual pump selection of one or more manufacturers in order to use actual numbers.
6. Make allowable corrections to the pump's required NPSH (using charts where applicable) and compare with the available NPSH. The available must always be several feet (mm) greater than the corrected required.
7. Make fluid viscosity corrections to the required performance if the fluid is more viscous than water.
8. Examine specific speed index, particularly if it can be anticipated that future changes in the system may be required.
9. If fluid being pumped is at elevated temperature (usually above 90o F (32.2o C )), check temperature rise in the pump and the minimum flow required through the pump.
10. Make pump brake horsepower corrections for fluids with a specific gravity different from water. Select actual driver (electric motor, usually) horsepower in order that horsepower losses between the driver and the pump shaft will still provide sufficient power to meet the pump's input shaft requirements.
11. If the pump has some unique specialty service or requirements, recognize these in the final sizing and selection. Consult a reliable manufacturer that produces pumps for the type of service and applications and have them verify the analysis of your system's application.

Get other all about pump types, selection, problem in pumps, pump design etc. in :

pump | deep well pump | jet pump

The author name is Bustanul Arifin. A chemical engineer who graduate from reputable university in the world. Now I am working as consultant in ethanol plant design, and petrochemical construction contractor. This article was written based on my experience and many text books. Please feel free to visit my website :

pump | deep well pump | jet pump

Textbook reference :

1. Branan, C. R., "The Process Engineer's Pocket Handbook", Vol. 2, Gulf Publishing Co., 1983.
2. Brown, G.G., "Unit Operations", John Wiley and Sons, Inc. , 1950.
3. Evans, E L., "Equipment Design Handbook For- Rejneries and Chemical Plants", Vol. 1, 2nd Ed., Gulf Publishing Co., 1979.
4. GPSA Engineering Data Book, "Gas Processors Suppliers Association", Vol. 1, 10th Ed.. 1987.
5. Kern, R., "How to Design Piping for Pump-Conditions," Chemical Engineering, 1975.
6. Kirk, R.E. and Othmer, D.F., "Ensyclopedia of Chemical Technology", Interscience Ensyclopedia, Inc. , 1951.
7. Ludwig, E. E., "Applied Process Design for Chemical and Petrochemical Plants" Vol. 1, Gulf Publishing Co., 1977.
8. Perry, R. H., and Chilton, C. H., "Chemical Engineers' Handbook" New York: McGraw-Hill, Inc, 1973.
9. Standards for Steam Jet Ejectors, 3rd Ed., Heat Exchange Institute, New York, N.Y.
10. WALAS, Stanley M., "Chemical Process Equipment - Selection and Design",
(Butterworth-Heinemann Series in Chemical Engineering). Boston, MA: Butterworth-Heinemann, a division of Reed Publishing (USA) Inc., 1998.

What is the Heat Pump Efficiency of Your Heat Pump?

Are you looking into purchasing a heat pump to either heat or cool your home? If so, what is the main function this unit will be used for? Heat pump efficiency ratings are different for each season. The ratings do not always correlate, so if your pump has a high SEER rating, it does not mean that it will have a high HSPF rating.

Therefore, it is important to prioritize your exact needs for this device. If you live in a warm region that will require more use of the cooling unit then the heat pump efficiency should be higher for the SEER rating. If you live in a cooler region, that will require more heating then look for a unit with a higher HSPF rating.

Every heating and cooling unit must have an energy efficiency rating. It lets people know how that particular model compares to other models and compares the different low and high efficiency ratings.

Now you are probably wondering what these two ratings actual mean. The SEER rating is the Seasonal Energy Efficiency Rating and the HSPF rating is the Heating Seasonal Performance Rating. Each unit is thoroughly tested to determine the exact rating.

Heat pumps are used for both heating and cooling. These devices move heat between the outside and the inside of the home. They do not actually create any hot or cold air.

We can explain this better by stating that during the winter a heat pump will move heat from outdoors into the house. In the summer, they move heat from indoors to the outside. Usually these devices run on electricity, but some run off gas instead.

Heat pump efficiency also factors into the energy savings these units can provide. In some cases, you can save up to fifty percent on your heating costs.

If your heat pump efficiency is high then you could save even more money on your energy costs. A high efficiency heat pump will require less electricity to heat or cool your home, thus they are much more efficient.

However, these units are quite costly. Thus, you have to be sure that this is what you want as far as heating and cooling your home is concerned. Read as many consumer reviews as possible to get a good idea of what units are available on the market and which ones people are satisfied with and which ones are not receiving good reviews.

We provide information for the consumer on heat pump efficiency along with information on different brands including Trane heat pumps as well as many other types of heat pumps.
By M. Applebaum