GU10 Bulbs and Energy Efficiency

A lot of people are concerned about their energy consumption nowadays. Electricity isn't free, and what's more it causes damage to the environment through the burning of fossil fuels. As a result of this desire to reduce energy consumption, more and more people are turning to the latest in lighting technology. LED (or Light Emitting Diode) bulbs are only just making their way onto the consumer market, and are more energy efficient than standard halogen bulbs, reducing the impact on the environment and on your wallet. Some of the newer models with GU10 mounts only need 2 watts to work!

The change is a gradual one - the whole world isn't just going to start using these bulbs overnight - but the more people that start to make the change the better. Though GU10 LED bulbs can cost more than halogen bulbs, they can help you save money in the long run due to their higher energy efficiency, and their longer lifespan. The bulbs are designed specifically to be similar in shape and size to traditional halogen bulbs, so the transition can be made quickly and easily with as little fuss as possible.

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There are a few differences in the kind of light that LED and halogen bulbs produce, e.g. whereas halogen bulbs create a wide ray of light, LED bulbs create more of a focused beam. This makes GU10 LED bulbs ideal for focused lighting, but you have to take the differences into account when making the change. If you can get used to a more concentrated beam of light, make the change, but you may want to keep the wider beam of the halogen bulbs.

GU10 Bulbs and Energy Efficiency

As GU10 LED bulb use is still relatively a novel concept the output of the bulbs is still being improved but at the moment you do need to be aware that if you are looking for a higher light output then you will be required to pay extra for this. However, the extremely long life of LED bulbs will make up for this as you won't need to replace them as often as standard halogen ones. With LED light bulbs the old saying "you get what you pay for" really does apply.

Like standard halogen bulbs, LED light bulbs are available in a range of different colours so that they are useful for use in special purpose lighting. The colour is created by using filters and this actually improves the energy efficiency of the bulbs in comparison to a standard white light. So if you need different coloured lights for a special occasion then LED bulbs really are the way forward!

It is thought that low energy light bulbs such as LED bulbs actually use less than 20% of the energy of a standard halogen bulb and they even last up to 15 times longer. They are also a lot more durable than conventional bulbs as there are no glass tubes or anything to break and the internal parts are all resistant to vibration and impact.

If you are looking to lower your electricity bills and look after the environment at the same time then making the switch over to LED bulbs is a complete no-brainer!

GU10 Bulbs and Energy Efficiency

For more information please visit GU10 Bulbs

Why is Wind Energy a Good Alternative Energy Source?

Wind energy is the best solution to most of our home energy bill problems. Now that there is an ongoing economic crisis and the price of everything is going up, it is highly recommended that we look for alternative energy sources that we can use. This is to cut down cost and help us save money. One of the best solutions is the wind energy.

In addition to helping us lessen our expenses on home energy, it is also environment friendly. Unlike most energy sources that release chemical substances into the atmosphere, wind generators only uses wind power. It has no other byproducts that can damage our atmosphere causing ozone thinning and many other related problems. The only thing that the wind generator will produce is the cheap energy that you can use in to power the appliances in your house.

Energy

However, having wind generators installed by experts may still cost much. For homeowners, it would not make sense if you have to spend thousands of dollars in something that will only reduce your home energy bill by a hundred dollars per month. You would need to use and wait for several years for your investment to pay back.

Why is Wind Energy a Good Alternative Energy Source?

To make this alternative energy source cheaper, you can install it by yourself. This is the reason why many homeowners now prefer to use this energy source. There is now an available guide to help us through the installation process. This systematic guide also has tips to ensure the proper installation of the wind generators. The guide or manual also contains information on the maintenance of the wind generator so that you do not have to contact a technician in case there something is wrong with your generator.

The DIY kit and the manual are much cheaper than the ready-made wind generator allowing you to save money even during the installation of it. All that you have to do is buy the kit, avail the manual and assemble it. Your wind generator will be up and running in no time saving you money from energy expenses. The guide is very easy to understand and includes some schematic plans to ensure that you are putting the right parts in the right position. If you are still having trouble installing the wind generator, you can look for help online.

Before putting up a wind generator, consider the location of your home. If you live in the city and surrounded by tall buildings, of course, wind generators is not applicable for you. As the name of this energy source implies, there should be wind to make it run and tall buildings can obstruct wind in reaching your house. For this, a suggestion is the solar panel as your alternative energy source.

Why is Wind Energy a Good Alternative Energy Source?

If you are interested in making your own wind generator or solar panel at home, click here to learn more.

How to Run Your Appliances More Efficiently to Save Energy and Money

This is the second in a series of Articles that have become The Energy Saver Challenge.  The first article concentrated on helping people save energy and money on their lighting bill.  The focus for now is on how your appliances can cost you unnecessary money, be using energy for which no benefit is derived and how you can do better for the environment and your wallet no matter what your circumstances. 

If you are in the market for a new fridge or freezer, dishwasher or oven or any other appliance for your home, now is the time to make some quality decisions.  It's not all about looks you know, these days it is just as important to select a model that will perform not only in the cooling/washing/looks department but also in the energy use department. 

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Look for a model that has the top energy rating.   A model with a high energy rating can save you a lot of money over the lifetime of the appliance.  Plus, you can know that you have made a choice that is a better deal for the environment too.  Now let's get into some useful detail.

How to Run Your Appliances More Efficiently to Save Energy and Money

Fridges and Freezers:

Did you know that your fridge and freezer account for a large proportion of the energy you use in your house?  The reason for this is they usually run all day and all night, every day of the year.  Learning how to use your fridge and freezer efficiently can make a big difference to how much energy you use.  This is all good news for the environment and for your electricity bill.  Most people are not in the market for a new fridge and there are some important things you can do to improve the performance of your current fridge and freezer.

The first is to give it a bit of a tune-up in terms of it's seals.

Are they airtight?

  • You can check that by putting a piece of paper between the body of the fridge and the door. Shut the door and then tug gently on the paper.  If it comes out easily then your seal is not tight enough and that is costing you money 24/7!  It may be that the door hinges can be adjusted to improve the seal or perhaps it's time to get the seals replaced.
  •  I read recently on an energy company website that an old inefficient refrigerator can use three times as much energy as a new one!  That means it costs you three times as much to run.  If you can check the seal and make that better or replace it, you will certainly benefit.

Many homes have an extra fridge in the garage, basement or even in the shed.  

The party fridge, the beer fridge, the Christmas overflow fridge - whatever it's name at your place, it is costing you money.  Up to 0 a year!  So ask yourself a couple of questions:

  • Is it necessary for this fridge to be turned on all the time or could you just turn it on when it is actually needed?  This will cut your energy consumption and save you a stack of money.
  •  Do your really need the second fridge at all?  I mean, how bad is the refrigeration situation?  Was it a good idea once upon a time and now circumstances have changed? 
  • Perhaps the solution is to sell it to someone who really needs it.

Now we can look at some behavioural changes that can really cut into your energy consumption where the fridge is concerned.

First there is size.

  • Is your fridge the right size for your needs?  We usually have our fridges for a long time, and often we are using a fridge that is no longer optimum for our needs.  I used to own a really big fridge because there were five of us in the house and we needed the room.  Now there are only three of us and we have a medium size fridge however, most of the time we could probably get away with one that was even a little bit smaller. 

Apparently fridges operate most efficiently when they are quite full.  

  • That's the way they like it best.  So if you are looking in the door of your fridge and there isn't much in there and that is the way it usually looks - I can suggest that you are over capacity in the fridge department and it might be worth considering downsizing!

A couple of other tips to help your fridge keep more money in your wallet and create fewer greenhouse gases for the environment.

  • It's best not to locate your fridge or freezer near your oven, or even if it gets sun on it.  Just makes it work harder and you know what that means! 

  • Fridges need space - make sure there is a gap at the back near the ventilation coils so that it can work efficiently.  Around 80mm is recommended.
  •  And last but not least, give the back of the fridge a bit of a dust now and then, this helps the ventilation system too - and you'll be amazed at what makes it way around the back of the fridge when you are not looking.

Dishwashers:

Mine is my husband and my son and I think they both have a 50 star energy rating!   Seriously though, washing dishes in the sink is a good thing and personally I think it's underrated as a family activity. 

Still if you must use a dishwasher think about it's energy rating when you buy it and see how many of these tips you can adopt in it's use.

  • Only run the dishwasher with a full load - it uses the same amount of energy (and water!) whether it's full or half full so it just makes sense to wait until it's full right? 

  • Then don't let the machine dry the dishes for you - program it to stop before the drying cycle and just open the door - the dishes will dry themselves without any extra energy needed at all.

Your stove or oven:

Once again if you are buying new, go for the highest energy rated appliance you can afford - it will keep saving you money for the whole of its life.

One big tip is to only use your oven when you actually need to.

  • Frying pans, pressure cookers and crock pots and even microwave ovens are more energy efficient if what you are cooking can be created in them. 
  • If you are going to use your oven, check that the door closes fully and that there is a good seal when it is closed.  No point in paying for all that energy to warm it up if it is just going to escape out around the door. 
  • This applies equally to electric or gas ovens. 

Now to the cook top.

  • Did you know that just putting the lid on the pot will substantially lessen the amount of energy required to cook what is in it? 
  • Plus, if you ensure that the right pot goes on the right hotplate or burner (not too big, or small) then you will also save substantially in both energy and time.  Not to mention the money!

So how can you save energy in the laundry? 

That washing machine now gets the energy efficiency treatment.  You know the deal by now with the energy rating if you are in the market for new appliances right?  I know you have a good idea of what to look for now. 

The first tip is to wash in cold water.

  • I've not washed in hot or warm water for decades and I'd love to know how much energy and money that has saved me.  I also recently had to buy a new machine and went for one of those front loading varieties.  I have to say, I like it very much and it uses less water and less energy than an equivalent top loading machine so it appears I have made a good decision with that one. 
  • As with the dishwasher, you will discover that your washing machine will use the same amount of energy whether or not there are a few items or a whole load so it makes sense really to wait until you have a full load of washing if you are trying to save energy and thus have more money in your pocket at the end of the month. 

Now, the bane of my life, clothes dryers.

I was given one as a wedding gift and I had it for about 15 years before it finally coughed it's last load of soft fluffy clothes at me.  However, I had used it less and less as I realised just how much money it cost me each time I used it.  Eventually for the last three or four years it only got used in emergencies of weather or bad management on my part.

  • If it is a sunny day, hang your washing outside.  I have a clothes line but I know others who use clothes airers and they work well too.  The sun dries them perfectly, the breeze softens the fabrics and they smell fantastic when you bring them back inside. 

  • If you do use your dryer, never put dripping clothes in, always spin them first and make sure the lint filter is cleaned really regularly so that the machine can weave its magic for you as efficiently as possible. 

  • Maybe you could trial drying your clothes and just finishing them off in the dryer as an interim measure on a wonderfully sunny day.

There are many other energy using appliances in our home that you may not have thought of.

Things like your iron, your microwave, your television, computer, dvd/video machine, stereo,gaming consoles.....  How on earth did we come to rely on energy so much for our daily lives. 

Most of these appliances now contain digital clocks and also standby lights.  Now this is all very well but how many clocks does one room need?  In my home, in the kitchen I have a clock on the wall, one on the stove and another on the microwave.  In the living room I think at last count there were four clocks in the TV cabinet!  What is this obsession with clocks on appliances? 

Now to get to the point.  I'll give you an everyday example as a means to make it - the microwave oven.  Most if not all homes now possess such an appliance.  They almost all come with a digital display that tells you all sorts of useful information like temperature and duration of cooking time while you are using them and that is great but once their job is done, they just sit there with their little display telling you the time. And using energy. 

  • I use my microwave for less than 30 minutes a day and yet I allow it to use energy (and cost me money) for 24 hours per day.  That just does not make sense. 
  • Turn it off at the switch when you are not using it. 
  • It will not mind, it will not stop working. 
  • Nothing terrible will happen.

The same goes for your stereo. 

  • If you are not listening to it, turn it of. 
  • Not just on the front, that will just let it sit there on standby mode, using power. 
  • Turn it off at the switch.

And when you go to bed at night, all those things in the entertainment cabinet with their little red and green lights just begging you to turn them back on, are costing you money.  Don't listen, reach behind the cabinet and flick that switch!

Now here is the big sell for me about this one.

All those clocks, all those little red and green standby lights (including the ones on your computer!) add around 10% to your energy bill.  That means by creating the habit of turning them off when they are not being used, you could save up to 10% on each and every energy account you receive from this day forward.  Over your lifetime, that can add up to a lot of energy and a nice amount of money left in your bank account for something much more fun than paying the energy bill.

How to Run Your Appliances More Efficiently to Save Energy and Money

Cate Ferguson lives in Australia and has been involved in the Personal Growth and Empowerment field for many years. Cate Ferguson produces a monthly newsletter and is the author of a 5 part ecourse 5 Steps to Discover your life purpose. Visit http://www.CateFerguson.com for more information

Cate is also passionate about living a sustainable lifestyle and has written extensively on how to live a modern, mainstream alternative lifestyle. Visit http://www.AlternativeLifestyleSite.com/blog for more information

5 Ways to Save Energy at Home

The world is facing an energy crisis and we all want to do our part to help conserve what we can. Not only will you help the environment but you will also be able to save money. So here are 5 quick methods you can use to conserve energy at home.

1. Light Bulbs - Switch to CFLs or compact fluorescent light bulbs. The right CFL uses about 75% less energy and lasts up to 10 times longer. Additionally, they save about %2B in electricity costs over the lifetime of the bulb and produces 75% less heat. Although they cost a little more per light bulb, the long term savings are worth the purchase.

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2. Air Conditioner - Set the temp between 78 to 82 degrees depending on your comfort level and you will see a significant savings. Depending on the season, setting the thermostat too low will make the air conditioning unit run continuously or more often and setting the temperature too high will cause the unit to run longer to bring the temperature of the house down.

5 Ways to Save Energy at Home

3. Washing Machines - Washing machines and dryers account for about 10% of overall energy usage. Try to use cold water for wash and rinse. Run large loads instead of several small ones and if you can, try to get front-load washers since they use up to 2/3 less energy.

4. Electric Appliances - Unplug anything electric that is not in use. You'd be surprised how much you can save by simply unplugging your appliances.

5. Computer - It seems a lot of people leave their computers on. Do yourself a favor and turn off the computer and turn off your monitor when you are done using it.

5 Ways to Save Energy at Home

Learn another method of conservation through a DIY Solar Power System. Learn how to build your own solar power or wind power system. Go to [http://www.diysolarpanel.net]

Energy Saving Using Variable Speed Drives - Explanation of How to Save Energy Using Drives

Energy Saving - An introduction

Many systems use constant speed motors and control process flow rates or pressures by mechanically regulation using throttling valves, dampers, fluid couplings or variable inlet vanes etc. These devices generally do not control flow or pressure efficiently because energy is dissipated across the throttling device.

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Running a motor at full speed while throttling the input or output is like driving a car with one foot on the accelerator and the other on the brake; a part of the produced output immediately goes to waste.

Energy Saving Using Variable Speed Drives - Explanation of How to Save Energy Using Drives

A variable speed drive can save over 60% of the energy. This is possible as it controls the energy at source, only using as much as is necessary to run the motor with the required speed and torque - much in the same way as the accelerator in the car controls the engine revs and without the foot on the brake. Types of loads - which are suitable for energy saving?

Drive applications are categorized with respect to power and torque changes in response to the motors speed. It is important to understand the type of load for a particular application because not all are equally good energy saving opportunities for the application of a variable speed drive. In fact, if a variable speed drive is used on some loads there will be little or no energy savings.

Variable speed drives and the loads they are applied to can generally be divided into 3 groups:

- Constant power
- Constant torque
- Variable torque

Constant Power Loads

In constant power applications, the power requirement remains constant at all speeds, and the torque requirement varies inversely with speed. One example of this type of load would be a lathe. At low speeds, the machinist takes heavy cuts, using high levels of torque. At high speeds, the operator makes finishing passes that require much less torque. Other examples are drilling and milling machines.

Typically, these applications offer no energy savings at reduced speeds.

Constant Torque Loads

In constant torque loads, the power is directly proportional to the operating speed. Since torque is not a function of speed, it remains constant while the power and speed vary proportionately. Typical examples of constant torque applications include conveyors, extruders, mixers and positive displacement pumps. Usually these applications result in moderate energy savings at lower speeds.

In variable torque load applications, both torque and power change with speed. Torque varies with speed squared, and power varies with speed cubed. This means that at half speed, the power required is approximately one eighth of rated maximum. Common examples of variable torque loads are centrifugal fans, blowers and variable discharge pressure pumps.

The use of a variable speed drive with a variable torque load often returns significant energy savings. In these applications the drive can be used to maintain various process flows or pressures while minimizing power consumption. In addition, a drive also offers the benefits of increased process control, which often improves product quality and reduces scrap.

Effective speed ranges are from 50% to 100% of maximum speed and can result in substantial energy savings.

How do variable speed drives achieve energy saving with variable torque loads?

Variable speed drives regulate the speed of motors and in turn the speed of the fan or pump by controlling the energy that goes into the motor rather than restricting the flow of a process running constantly at full speed.

A variable speed drive can save over 60% of the energy as it controls the energy at source, only using as much as is necessary to run the motor with the minimum speed and torque.

Large amounts of energy can be saved on fan and pump systems, because of the affinity laws for pressure and flow rates.

The Affinity laws state -Flow is directly proportional to speed Torque is directly proportional to speed squared Power required is proportional to speed cubed Therefore, this means that if 100% flow requires full power 75% flow requires 0.753= 42% of full power 50% flow requires 0.53= 12.5% of the power

Mechanical control methods such as inlet guide vanes, throttling valves, discharge dampers do not take advantage of the affinity laws.

With mechanical flow control methods the motor always runs at full speed and the flow is mechanically restricted.

A variable speed drive saves energy by reducing the actual speed of the motor when full flow is not required.

Example A fan is running at fixed speed (50Hz) and the output from the fan is restricted by a discharge damper to restrict airflow to the correct level for the process. The input power is typically 95% of full load power.

A variable speed drive is fitted to the system and the discharge damper removed so there is no restriction to airflow. The speed of the motor is reduced to 40Hz which gives the same airflow as before when the motor was run at full speed and a discharge damper used. Now the input power is typically 50% of full load power.

Therefore by using a variable speed drive, the power being consumed is reduced by typically 45%.

Centrifugal Fans Massive potential energy savings using a variable speed drive compared to the two most common methods of flow control for fans: - Inlet guide vanes require about 60% power to give a flow rate of 50% - A discharge damper requires a huge 90% power to give 50% flow

Centrifugal Pumps - Operating at 75% flow requires less than 50% power, whilst the throttling valve requires around 90% power.

Centrifugal fan - Typical input powers

The following table shows the typical input power to a motor when run at full speed with flow rate is restricted by an outlet damper compared to the typical input power when the same motor is run at reduced speed from a variable speed drive, achieving the same air flow rate as with the outlet damper. It can be seen that if an outlet damper reducing the air flow rate to 80% uses 95% input power, a variable speed drive achieving the same air flow rate uses 50% input power.

Other advantages of variable speed drives

o A variable speed drive can also make it possible to stop a motor completely when it is not required as re-starting with a variable speed drive causes far less stress than starting direct on line - soft start is an inherent feature of the drive.
o Regulating the motor speed has the added benefit of easily accommodating capacity rises without extra investment, as speed increases of 5-20% is no problem with an AC variable speed drive as long as there is enough spare capacity in the system.
o Reduced maintenance compared to DC systems (brushes and commutators)
o Reduced motor/application noise levels.
o If the variable speed drive has an internal PID loop, it will be possible to automatically control flow or pressure based on feedback from a sensor within the system. This can make further energy savings as the motor can slow right down if very little flow or pressure is required.

Another method of saving energy

Most companies forget about the motors when considering energy saving. As well as saving money by installing a variable speed drive, installing high efficiency motors can also save energy and money. Please see the enclosed document for further details on high efficiency motors. Motor Control Warehouse can supply EFF1 accredited motors. Please take a look at our website for further details.

Example of energy saving using a variable speed drive

A 30kW pump operating for 16 hours during weekdays and 12 hours during week ends, total of hours per week = 92 hours.

Energy Cost at constant speed Energy consumption per week - 30kW x 92hours = 2760kWh Assume electricity rate is 10p per kWh Energy cost per year - 2760kWh x £0.10 x 52 weeks = £14352

Energy Cost at variable speed Assume average speed is 75% which corresponds to 42% power consumption Energy consumption per week - 0.42 x 30kW x 92 hours = 1159.2kWh Energy cost per year - 1159.2kWh x £0.10 x 52 = £6027.84 Value of energy saved per annum by using a variable speed drive £14352 - £6027.84 = £8324.16

NOTE: This calculation is just an example using a figure of 10p/kWh but gives a good guide as to what can be saved by using variable speed drives. For a more accurate value of possible energy savings, a full survey including tests would be required

Energy Saving Using Variable Speed Drives - Explanation of How to Save Energy Using Drives

Largest supplier of AC/DC Inverters, Motors, Servo Variable Speed Drives, EMC Filters, and more! We have 75 years of experience and provide next day shipping on all orders.

How Power Savers Work - Basic Buying Tips

Can you really save 40% on your electricity bills by plugging a small box into your AC socket?

In the past six month a number of products have been advertised on TV and online which seem too good to be true. I'd like to explain the reality of these exciting claims and give you a layman's understanding of how Power Savers work.

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A Power Saver is a device which you plug in to your power socket. Apparently just by keeping the device connected it will immediately reduce your power consumption. Typical claims are savings between 25% and 40%.

How Power Savers Work - Basic Buying Tips

The technology behind Power Saver units comes from German research coupled with Asian manufacturing and it is based on sound scientific principles.

Electricity is not stable. When electricity flows the voltage can rise and fall all the time. The rises in voltage are known as 'spikes' and they cannot be used by your appliances at all. All these spikes do is waste your electricity. These power spikes also convert electrical energy into heat energy which leaks power from your circuit. Not only that but the heat will also do long-term danage to your wiring and to your appliances.

There are a few Power Saver models on the market but they all work along the same principle. They store the electricity inside of it using a system of capacitors and they release it in a smoother way to normal without the spikes. The systems also automatically remove carbon from the circuit which also encourages a smoother electrical flow. This means that you will have less power spikes. More of the electricity flowing around your circuit can be used to power your appliances than before.

There are many factors which do affect the efficiency of your Power Saver. The device works immediately after plugging it in although it can take as long as 8 days before it has adjusted itself for peak performance. The rate of savings will depend on what kind of appliances you have connected. All appliances are different but expect savings of up to 25% on lights, 30% on air-conditioning units and up to 35% on other appliances.

The highest savings will be in areas where voltage supply is less stable. Locations close to shops, restaurants and light industries tend to gain additional savings from Power Saver devices.

So how can you be sure that your Power Saver is working correctly?

Most often Power Savers come fitted with a light to indicate that it is working. If you have access to an electricity meter then you should see it immediately slowing down. Assuming that the light is on and that you leave the device unattended you can expect savings immediately. Be aware that often electricity companies will not take meter readings each month. Often bills are calculated on monthly averages which self-correct over time so please be aware of that in using your bill as a guide.

Finally, it is highly recommended to order your Power Savers from companies offering 100% guarantees for longer than 30 days. Remember that 30 days may not be sufficient time to truly know if the device is working as effectively as you expect. Try to work with companies that extend their guarantee dates to at least 60 day which gives you a much longer period to assess the benefits.

How Power Savers Work - Basic Buying Tips

Martin Pavion is the owner of http://www.plugandsave.com You can learn more about Power Saver on his website

Residential Wind Turbines - Save Money, Save Energy, Save the Environment

Money, energy saving, and the environment are three issues that concern many people in the world, and they are all tied together. Rising oil and coal prices lead to higher electricity prices, which lead to the general will to save energy which will also save the environment. Unfortunately, it is not easy to accomplish all these tasks together without doing anything. But when doing something, like installing wind turbines, devices that produce energy from the wind, it all becomes easy.

The rising electricity bill is a big concern these days with expensive oil. Fortunately, wind turbines do not require any oil or other fuel to operate, and they generate free electricity. Since the energy from wind turbines powers your home appliances, you need less electricity from the electric company. As a result, you electricity bill shrinks. If you have enough wind turbines to produce more electricity than you consume, you can sell it to the electric company and get paid for it. Your wallet will be happy.

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Energy saving and green thinking is a major point of many companies today. Most appliances have an efficiency rating, so you can choose the one that gives the most work for the electricity invested. However, this is still not enough to be independent from electric companies. Wind turbines generate electricity for you, so you save much more energy from oil and coal.

Residential Wind Turbines - Save Money, Save Energy, Save the Environment

Environmentalists like to complain about the pollution from electric companies, and they are right. Electricity generation is a very polluting process. However, the use of wind turbines is completely pollution free. Not a single molecule of carbon dioxide or any other polluting substance will be released in the process. You save money, you save energy, and you save the environment.

Residential Wind Turbines - Save Money, Save Energy, Save the Environment

To start using wind turbines and saving, download Earth4Energy, the detailed guide that will show you how to properly install your very own home wind turbine system.

About the author:

Nadav Snir is a chemistry and physics student who studies energy and ways of conservation. To find out more about energy saving, wind turbines, and Earth4Energy, visit his site: http://Great-Info-Products.com/WaterForGas/earth4energy.html

Generate Electricity Using a Permanent Magnet Generator

Energy generated with magnets has always been debatable. Over the past few years, it has been a top priority to find renewable energy and so far one of the best options has been magnet generated energy. Energy in this form is highly Earth friendly, plus will definitely save you a great deal money spent on electricity. If you want to generate energy with magnets, your home will need a permanent magnet generator, which is a special energy system. With a small investment to build a generator, you'll have the ability to generate all the magnet energy you want, all free to use.

You can power your household once the magnets inside the generator have created the energy. Similar to the poles repelling and opposites attracting, the magnets use great force to create energy. Maintenance of the permanent magnetic generator is quite possibly the cost you'll endure over the years of using one.

\"Energy Efficiency\"

Homeowners who are using generators to create magnetic energy have reported that maintenance costs are quite low. Reports are showing, compared to solar systems or other energy efficient devices, the maintenance costs for a generator is next to nothing. These generators have no harmful effects on the environment, which is a major plus for people that are concerned about energy efficiency.

Generate Electricity Using a Permanent Magnet Generator

There are never any worries about toxic fumes being released into our atmosphere while these generators are being used to create magnetic energy. A lot of people ask how much energy can magnets make? A permanent magnet generator is capable of generating up to 7,000 watts. This certainly gives you the potential to eliminate your electric bill once and for all. If you're ready to begin harnessing the power of magnets, then you need a permanent magnet generator to get the job done. Start generating energy by using magnets and you will get off the grid completely!

Generate Electricity Using a Permanent Magnet Generator

Explore more about the new energy focus, the Permanent Magnetic Generator. Acquire wealth of information on how magnetic generators work, benefits and many other informative tips on saving electricity. Also, look into how Zero Point Energy can do for you and your family at the comfort of home; Master the true knowledge of generating free energy.

Who Cares, 3528 LED Or 5050 LED Diode?

3528 LED or 5050 LED are the most 2 common use LED in flex strip lighting. They can also used in either mono-light or RGB flex strip lighting. So what is 3528 LED as compare to 5050 LED? The supplier will reply with a simple sentence, 5050 is the diode which much brighter than 3528-LED.

Let us talk slightly more over here.

\"Energy Efficiency\"

LED comparison

Who Cares, 3528 LED Or 5050 LED Diode?

Please see the image for better understanding. You can find out that 3528-LED is smaller size as compare to 5050-LED, every 5050 LED diode actually compose of 3set of 3528-LED diode.

A 3528-LED diode will illuminate brightness equal to 6lm, and a 5050-LED diode will deliver the brightness for 18lm. Same as power, a 3528-LED diode will consume 0.06w; on the other hand a 5050-LED will use 0.18w of energy.

Since both diodes are considered as a low power diode, we don't see much difference between heat dissipation. Or to put it another way, heat dissipation may not be a big concern for their application.

Application for 3528 LED and 5050 LED

We note that both diodes are mainly used in flex strip lighting, apart from flex strip lighting; we also notice that some of the manufacturers tend to use multiple 3528 or 5050 LED diode integrated in a household LED light bulb, is that any difference? In term from user stand point, it doesn't make much difference because it emit similar amount of light brightness. However for most cases, people are still preferred to have high power LED diode.

In general, 3528 and 5050-LED are two general type of LED diode in the market that used for flex strip lighting. Select 5050-LED diode if illumination or brightness is the major concern.

Who Cares, 3528 LED Or 5050 LED Diode?

I am deeply involve in LED Lighting and products, feel free to visit my LED Lighting website. http://www.iloveledlighting.com

4 Key Parts Needed For Solar Power Electricity

Solar power electricity installations are gaining moment all over the world. Stock of fossil fuels is fast depleting and alternate natural energy solutions, like solar power electricity is becoming popular.

Natural energy solutions are environment friendly with little or no air pollution and no emissions or greenhouse effects. Solar power electricity production is also free of noise pollution.

\"Energy Efficiency\"

How is solar power electricity produced?

4 Key Parts Needed For Solar Power Electricity

It is produced by converting light from the sun into electrical energy using a silicon wafer / semiconductor called a photovoltaic cell. This technology is simple and easy to maintain.

What are the main parts of a typical residential solar power electricity system?

A typical residential system would have 4 key Parts:

1) Solar panel array

2) Charging controller

3) Batteries

4) Inverter

Solar panel array: Solar panel array is made up of several solar panels. A series of photovoltaic cells working in unison in a module form the solar panel. The solar panel array needs to be exposed to sunlight, and the array is normally installed on rooftops where sunlight exposure is more. The solar array converts light energy into solar power electricity. Electrical energy in the form of 12 volts (DC) is produced by the solar panel array.

Charging controller: The charging controller is the device that controls the amount of charging for the batteries. Batteries should not be overcharged, neither should they be undercharged. This device, which sits between the solar panel array and the battery bank, controls the charging.

Batteries: These are deep cycle batteries used for storage of solar power electricity produced by the solar array panel. The 12 volts (DC) produced by the solar panel array is stored in the batteries. The charging controller regulates charging, thus extending the life of these batteries.

Inverter: The output from batteries is 12 volts (DC) and can run only devices that work on 12 volts (DC). Most home appliances work on 110 / 220 volts (AC). Hence 12 volts (DC) needs to be converted into 100 / 200 volts (AC). The inverter does the job of converting 12 volts (DC) into 110 / 200 volts (AC).

Along with these four main components several other hardware accessories, wires and connectors would be required to have the complete solar power electricity system functional.

4 Key Parts Needed For Solar Power Electricity

Krishnan Varadarajan is an Infrastructure Consultant with focus on alternate energy solutions.You can now install Solar Power Electricity on your own for less than $ 200. To get your DIY guide now visit http://www.know-to.com/energy/solar.html

Energy Efficiency And HVAC Technology

The following overview offers a quick reference to key considerations with some of the most effective technologies. As with lighting, trial installations are a good idea; so is working with manufacturers and distributors.

Getting the most from HVAC controls

\"Energy Efficiency\"

Because a building's performance can be dramatically improved by installing and fully using HVAC controls, it is essential to understand and correctly use those controls. The place to start is with a close look at what is really transpiring in your building, 24 hours a day, seven days a week.

Energy Efficiency And HVAC Technology

What is happening with each piece of equipment? On holidays? Weekends? As the seasons change, do your operations change? It is important to understand where and how energy is being consumed in order to identify where waste is occurring and where improvements can be implemented. Then it is imperative to ask, "What exactly do I want these controls to do?"

Energy management systems (EMS) are designed to run individual pieces of equipment more efficiently and to permit integration of equipment, enhancing performance of the system. In a typical EMS, sensors monitor parameters such as air and water temperatures, pressures, humidity levels, flow rates, and power consumption. From those performance points, electrical and mechanical equipment run times and setpoints are controlled.

Seven-day scheduling provides hour-to-hour and day-to-day control of HVAC and lighting systems and can account for holidays and seasonal changes. As the name implies, night temperature setback allows for less cooling in summer and less heating in winter during unoccupied hours.

Optimal start/stop enables the entire system to look ahead several hours and, relative to current conditions, make decisions about how to proceed; this allows the system to ramp up slowly, avoiding morning demand spikes or unnecessary run times.

Peak electrical demand can be controlled by sequencing fans and pumps to start up one by one rather than all at once and by shutting off pieces of HVAC equipment for short periods (up to 30 minutes), which should only minimally affect space temperature. Economizers reduce cooling costs by taking advantage of cool outdoor air. Supply-air temperature-reset can prevent excessive reheat and help reduce chiller load.

An EMS can provide an abundance of information about building performance, but someone has to figure out what they want the EMS to do and then give it directions. Calibrating controls, testing and balancing are key to any well-maintained HVAC system, but are especially critical to optimize control efforts.

Variable speed drives and energy-efficient motors

Variable speed drives (VSDs) are nearly always recommended as a reliable and cost-effective upgrade.

VSDs are profitable where equipment is oversized or frequently operates at part-load conditions. Savings of up to 70 percent can be achieved by installing VSDs on fan motors operating at part-load conditions. They may be applied to compressor or pump motors and are generally used in variable air volume (VAV) systems. They are also cost effective in water-side applications. Backward-inclined and airfoiled fans are the best VSD candidates.

Air-handler configurations controlled by variable inlet vanes or outlet dampers squander energy at part-load conditions. Using throttle valves to reduce flow for smaller pumping loads is also inefficient. The efficiency of motors begins to drop off steeply when they run at less than 75 percent of full load; they can consume over twice as much power as the load requires. VSDs operate electronically and continually adjust motor speed to match load.

The power to run the VSD is proportional to the cube of the speed (or flow), which is why this technology is so efficient. If the speed is reduced by just 10 percent, a 27 percent drop in power consumption should result. A VSD pilot study performed by EPA found that VSD retrofits realized an annual average energy savings of 52 percent, an average demand savings of 27 percent and a 2.5-year simple payback.

Perform harmonic, power factor, electric load, and torsional analyses before selecting a VSD. Though harmonic and power factor problems are not common in VSD applications, VSDs should generally be equipped with integral harmonic filters (or a three-phase AC line reactor) and internal power factor correction capacitors (or a single capacitor on the VSDs' main power line). In general, this equipment is not standard and must be specified.

Improved design and better materials enhance the performance of energy-efficient motors, which use 3 to 8 percent less energy than standard motors; units with efficiencies of 95 percent are available.

To achieve maximum savings, the motor must also be properly matched with its load, increasing run time at peak efficiency. Motors operate best when running at 75 to 100 percent of their fully rated load; motors routinely operating below 60 percent of rated capacity are prime candidates for retrofit. For motors whose loads fluctuate, VSDs should also be considered.

Smaller, more efficient motors are integral to a system downsizing stratagem; downsizing a 75 horsepower standard motor to a 40 horsepower energy-efficient model will result in energy savings of 15 percent.

Some energy-efficient motors have less "slip" than standard-efficiency motors, causing energy-efficient motors to run at slightly higher speeds; consider a larger pulley to compensate for the higher speed and to maximize energy savings. Installing a new pulley or adjusting the existing one can also be an alternative to a VSD when the cost for the VSD is prohibitive or the load has been reduced.

Improving fan system performance

A common way to improve the efficiency of the air distribution system is to convert constant air volume (CAV) systems to VAV. One authority on energy issues, E-Source, reports that "typical (VAV) air flow requirements are only about 60 percent of full CAV flow."

VAVs respond to load requirements by varying the volume of the air through a combination of pressure controls and dampers rather than by varying the air's temperature. According to the air pressure, fan power and volume of conditioned air are reduced, thus increasing energy efficiency. Of course, it is crucial to maintain indoor air quality (IAQ) when altering air handling systems.

To maximize savings, VAV components such as VSDs, variable-pitch fan blades, diffusers, mixers, and VAV boxes must be operating properly; careful zoning is also required to achieve VAV optimization.

E-Source recommends considering the following VAV retrofit procedures:

• complete load reduction measures and calculate the maximum and minimum air flow requirements,
• measure existing fan performance; examine duct system for possible improvements,
• stage fans that are in parallel configurations,
• commission the system thoroughly,
• optimize static pressure setpoint and implement reset control, and
• possibly remove return air fans.

Energy-efficient and properly sized motors are also recommended along with careful control strategies. Installing a self-contained, thermally powered device to each diffuser can add greater control to VAV systems by controlling individual spaces, rather than entire zones, and eliminate the need for VAV boxes. Such a device also offers VAV-style capabilities to CAV systems.

VAV retrofit costs and paybacks can vary widely. Installation problems related to fan control, reduced supply air distribution, location of pressure sensors and their reliability, in addition to deficient design, can diminish a VAV retrofit's performance. Because VAV boxes are relatively expensive and one is required for each zone, it is generally not cost effective to partition the space into many zones. Careful zone designation -- according to occupancy, internal loads and solar gain -- will maximize efficiency, increase comfort and reduce reheat.

When reheat cannot be eliminated, consider these steps to minimize it: ensuring thermostat calibration; increasing supply air temperatures during the cooling season; and monitoring reheat year round and possibly employing reheat only during winter months. Where reheat is used primarily to control humidity, a desiccant wheel or a heat pipe might be considered.

Downsizing existing VAV fan systems is a relatively low-cost way to save energy when loads have been reduced or when the air distribution system was oversized to begin with. The following are means to downsize fans or airflow requirements:

• Reduce static pressure setpoint to meet actual temperature and airflow requirements.
• Rightsize motors and upgrade to energy-efficient models; install larger pulleys.
• Replace the existing fan pulley with a larger one; that will reduce the fan's power requirements by reducing its speed.
• Make sure the fan's speed corresponds to the load. Reducing a fan's speed by 20 percent reduces its energy consumption by approximately 50 percent.

There are several ways to determine if VAV fan systems are oversized. If a motor's measured amperage is 25 percent less than its nameplate rating, it is oversized. If a fan's inlet vanes or outlet dampers are closed more than 20 percent, it is oversized. If the static pressure reading is less than the static pressure setpoint when inlets or dampers are open and VAV boxes open 100 percent, as on a hot summer day, the system is oversized. Again, be sure to consider IAQ requirements when downsizing air handling systems.

Chillers and thermal storage

No one wants to replace a perfectly good chiller just because of the CFC phaseout. But once load-reducing efficiency upgrades have been completed, it may actually be profitable to replace an oversized chiller. That's especially true given rising prices and tightening supplies of CFC refrigerants.

Oversized units 10 years or older are good candidates for replacement. A high-efficiency chiller reduces energy costs throughout its lifetime; initial costs are reduced because the replacement chiller is smaller than the old one. Depending on the old unit's efficiency and load, a high-efficiency chiller's energy consumption can be.15 to.30 kW/ton less, decreasing energy consumption by as much as 85 percent if combined with downsizing.

An alternative to replacement is to retrofit chillers to accommodate a new refrigerant and to match reduced loads. That may involve orifice plate replacement, impeller replacement and possibly compressor replacement, depending on the chiller's specifics.

Retrofitting may entail gasket and seal replacement and motor rewinding. Depending on the refrigerant and the way the retrofit is performed, the chiller may lose either efficiency or capacity. To determine whether replacement or retrofit is a better option, consider both initial and life-cycle costs.

Retubing the condenser and evaporator yields sizable energy savings but whether it makes sense, given its high cost, depends on the condition of the chiller. Water-cooled condensers are generally more efficient than air-cooled units. Because condenser water flows through an open loop, it is susceptible to fouling. Scale build-up will inhibit heat transfer efficiency; maintenance is therefore required to keep the surfaces clean.

Absorption chillers are an alternative to centrifugal models. Absorption chillers cost up to 0 per ton more than vapor compression chillers like centrifugal units, but can be profitable in areas of high electrical demand charges or where steam or gas is available, depending on the local utility rate structures. Using a combination of the two chiller types can reduce electrical demand charges.

Thermal energy storage (TES) uses conventional chiller equipment to produce conditioned water or ice (or occasionally another phase-change material) in off-peak periods. Water is withdrawn from storage during the day or at peak hours and circulated through the cooling system.

TES systems can be incorporated into new and existing systems and can provide partial load leveling or full load shifting. TES helps decrease operating and maintenance costs; in some cases, a smaller chiller can be specified. Some systems provide lower supply air and water temperatures, so air and water flow requirements can be cut.

Water-side improvements

Fill material, size and fan configurations affect cooling tower efficiency. Cellular fill (aka film packing) increases efficiency over other fill types. Oversizing the tower to allow for closer approach to ambient wetbulb temperature can improve its efficiency. Generously sizing the tower and increasing its share of the chiller load can make economic sense because a cooling tower's initial cost and energy use per ton are less than a chiller's.

At part-load conditions, applying a VSD to the fan (or pump) will improve the tower's efficiency. Systems with VSDs and several fans are more efficient when all tower cells are operating at reduced speed as opposed to one or two cells at full speed.

Because cooling towers contain large heat exchange surfaces, fouling -- scale or slime build-up -- can be a problem. The efficiency of improperly treated systems can be improved with effective water treatment. High-efficiency towers are available; induced-draft types are more popular and efficient than forced-draft towers. Performance can also be improved by increasing cooling surface area.

In traditional pumping systems, flow is generally constant volume; a throttle valve reduces flow at part-load conditions, inhibiting efficiency.

Installing VSDs on secondary pumps in variable flow systems, rightsizing pumps and motors to meet load requirements, and upgrading single loop systems to primary/secondary loop configurations can increase the performance and reliability of pumping systems. In upgrading chilled water pumps, it is important to meet maximum and minimum flow rates through the chiller.

Other cooling options

Desiccants are dehumidification materials which can be integrated into HVAC systems to reduce cooling loads and increase chiller efficiency while improving indoor air quality and comfort. Formerly found only in niche and industrial applications, desiccant cooling is extending throughout commercial markets.

Desiccants make sense when the cost to regenerate them is low compared to the cost to dehumidify below dewpoint and can reduce HVAC energy and peak demand by more than 50 percent in some cases.

Evaporative coolers provide one of the most economical and efficient means of cooling, using up to 75 percent less energy than vapor-compression systems. Though initial cost is typically higher, paybacks for evaporative coolers range between six months and five years. Though evaporative coolers are particularly prevalent in the arid West and Southwest, they can service most U.S. climates. E-Source states that, in combination with evaporative cooling, desiccant cooling can eliminate refrigerative air conditioning in many climates.

Hybrid systems that integrate evaporative cooling with conventional HVAC technologies offer additional opportunities. To improve performance consider lower air velocity; better fill materials; higher fan, pump and motor efficiencies, including VSDs; better belts or direct drive; improved housing; improved controls; and duct sealing. Proper maintenance is key to energy-efficiency.

Packaged air-conditioning units are typically found in buildings or building zones where the cooling load is less than 75 tons. Running these units at part load can severely reduce efficiency. They are generally not as efficient as chiller systems but can be upgraded and rightsized when replaced. Existing systems can be improved by using higher efficiency compressors, larger condensers and evaporators, and VSDs, though life expectancies of 10 to 12 years for these technologies may mean that retrofits are not cost-effective.

Heat pumps are among the most energy-efficient heating and cooling technologies available today. Low operating costs, increased reliability and long life expectancies improve their viability. They function best in moderate climates and proper sizing is critical.

Multi-unit configurations can service larger loads and provide zoning; large, modernized central units offering capacities of up to 1000 horsepower or 750 kilowatts are gaining popularity. Air-to-air type heat pumps are the most common because of low up-front costs; ground supply heat pumps are the most efficient but tend to have higher initial costs.

Boiler upgrades

Especially in colder climates, improved boiler performance -- with improved fuel and airflow controls over a range of load conditions and increased heat transfer surface areas -- can contribute substantially to energy savings. Smaller units arranged in modular systems increase efficiency up to 85 percent while small units replacing those with open-loop condensing systems shoot combustion efficiency up to 95 percent.

Boiler retrofits, combined with improved maintenance measures, can also increase efficiency -- up to 90 percent. New burners, baffle inserts, combustion controls, warm-weather controls, economizers, blowdown heat recovery and condensate return conversions provide increased efficiency opportunities. A smaller "summer" boiler might be a good option when a boiler is required year round though at reduced capacities in warmer conditions. The much smaller summer boiler is sized for reduced loads; the main boiler is shut down.

HVAC upgrades can provide tremendous economic benefits, improve occupant comfort and system reliability, and reduce operating costs. But to maximize benefits and minimize capital investment, load-reducing measures, such as lighting upgrades, should precede HVAC system upgrades.

Energy Efficiency And HVAC Technology

Julian Arhire is a Manager with DtiCorp.com - DtiCorp.com carries more than 35,000 HVAC products, including industrial, commercial and residential parts and equipment from Honeywell, Johnson Contols, Robertshaw, Jandy, Grundfos, Armstrong and more.

Heat Pump Reviews - One Surefire Way to Pick the Right Heat Pump

Are you tired of buying the wrong heat pumps time and again?

The problem is you are probably misinformed about what pumps to buy. I know what you are going through. I have experienced this same dilemma in the past as well.

\"Energy Efficiency\"

Imagine your heat pump breaking just one week after you started using it - in the middle of the winter season. That was what happened to me on miserable December.

Heat Pump Reviews - One Surefire Way to Pick the Right Heat Pump

So now you see that I understand what you are going through. This is why I am writing this short article, to share with you one surefire way to pick the right pump in the future.

Are you curious to know this tried and tested strategy which I have recently learned is all about?

The secret is this: Checking Consumer Reports For Heat Pumps

It is not uncommon for customers who have purchased pumps in the past - especially those who were unsatisfied with the product - to file negative consumer reports with detailed information.

These reports are accessible to the public and to you. You may have been fooled by nice advertisements and convincing salespeople in the past - but no more!

From now on you will always be well informed due to the consumer reports you will be reading.

Plus, there are other ways to do background checks on the many brands and kinds of pumps in the market today:

1. Reading or watching heat pump reviews on websites online or in newspapers and magazines are some of the best ways to learn more about what you are planning to buy.

2. Checking online forums or consulting with your family and friends is also an effective way of gathering information. It is very beneficial learning from the mistakes of others.

Warning: Do ensure that your sources of information are unbiased ones. Purely informational websites are the best sources for information on pumps and other products.

Heat Pump Reviews - One Surefire Way to Pick the Right Heat Pump

The Three Little Pigs Story - Wise Building Materials and Energy Efficiency Considered

Not long ago, a friend of mine use the three-little pigs story in a blog post. Since, we all know the story, I will not repeat it, but do recall that the wolf blew over the first two little pigs homes and ate the pigs. The third pig made his home of bricks, thus the wolf could not blow it over. Later in the story the wolf tried to come down the chimney and he falls into boiling water instead of getting dinner.

In this story the Pig boils water to kill the Wolf in the choke point of the chimney, that takes energy, quite a bit of it. It takes a whole lot of energy to boil water. Now then, is this the true and efficient energy model of a prudent pig or is he an energy hog? You see, had the third pig used a solar collector to heat the water, bringing the water to boiling may have only taken a little extra energy rather than all the energy to bring the water from room temp to boiling.

\"Energy Efficiency\"

The pig waited until there was a crisis then used the most inefficient form of energy to boil the water in the chimney, he used wood, Natural gas is more efficient and you do not have to cut down the forest to do it either. I think we can show this as a bad example of energy use. There are easier ways to kill a wolf, and shouldn't that wolf have become dinner, why waste a perfectly good wolf.

The Three Little Pigs Story - Wise Building Materials and Energy Efficiency Considered

Further the two pigs who did parish along with their houses offer another opportunity - recycle-able materials - Why waste those materials, as they might provide decent insulation material?

Those who proclaim to be environmentalists are often hypocrites, because they would have attacked the third pig for using brick, as brick takes energy to make, transport, requires mining of materials and lots of water to be used (most brick making), it is a messy process. The finished brick home is deadly in an earthquake which could have crushed the pig and his piglets at a future date, through the law of unintended consequences of a black swan event in an area not known for seismic disruptions.

So, the environmentalists and their movement would have sued and prevented the EIR for the pig to build the brick house in the first place, if the pig built it anyway then the government would have torn it down for the wolf. Thus, the pig would have been eaten along with his brothers. Consider this.

The Three Little Pigs Story - Wise Building Materials and Energy Efficiency Considered

"Lance Winslow" - Online Blog Content Service. If you have innovative thoughts and unique perspectives, come think with Lance; www.WorldThinkTank.net/.

How a Magnetic Energy Motor Generates Never Ending Energy to Power Your Home - Energy Efficiency

If you are considering using alternative energy sources to power your home, then you might be interested in magnetic energy motors. A magnetic energy motor is similar to wind turbines and solar panel systems because they generate free energy. However, once you learn how it works you will see the differences.

These motors will generate electricity for your home using magnetic fields. The amount of energy a magnetic energy motor generates depends on the strength of the magnets being used. The stronger the magnets used for the motor, the more energy will be created by the motor.

\"Energy Efficiency\"

Moreover, this motor will use the energy it has produced to power itself. This means you won't have to worry about whether or not you have enough wind or sunlight to support your home energy system.

How a Magnetic Energy Motor Generates Never Ending Energy to Power Your Home - Energy Efficiency

These motors operate on the principle that opposite magnets attract, meanwhile, if they are similar they will repel. Magnetic energy will be created when the magnetic forces push against each other in the motor. The more these magnetic forces push, the more energy will be created until the magnets are removed.

Someone would have to strip the motor of it's magnets in order for it to stop producing energy. These motors use perpetual motion to produce never ending energy, and as long as the magnets inside the motor repel and attract naturally it will continue to do so.

There is no harmful emissions when you use a magnetic energy motor, making it very environmentally friendly. Also, when you use magnetic fields for producing energy for your home you don't have to worry about any excess heat being generated.

At the end of the day, when more people understand how a magnetic energy motor works solar and wind home energy devices will have a big competition.

How a Magnetic Energy Motor Generates Never Ending Energy to Power Your Home - Energy Efficiency

If you decide to implement one of these motors on a full-scale, it will independently power your household, meaning, you won't have to pay anything to the power company. Click Here and take a look at how you can begin producing free energy using one of these motors, also known as a Permanent Magnet Generator.

Benefits of Oil Filled Radiator Heaters Over Electric Or Propane Heaters

An oil-filled radiator heater can become quite an asset to your home as cold weather sets in. Somehow, you always forget about the drafty areas of your home when it is 70 degrees and sunny outside. But let those subzero temperatures start along with a kicking wind and suddenly you remember.

What is an Oil Filled Radiator Heater?

\"Energy Efficiency\"

Unlike portable electric heaters that radiate heat then use a fan to blow the heat in a directed area, an oil-filled heater has oil that is stored inside of a sealed compartment of coils and fins. The heat works by convection and the warm air generated floats up without any type of fan. Advanced models have a timer function that lets you set the unit 30 minutes before you get out of bed so it does not operate all night.

Benefits of Oil Filled Radiator Heaters Over Electric Or Propane Heaters

How does it Heat an Area?

As the heat rises from the unit, it comes back down, warming the immediate area surrounding the radiator. Although you will not be able to heat your room as well as a forced air furnace, a 12 x 18 foot room can warm up an additional 10 degrees by using this heater.

Where Does this heater do the most Good?

Most people have drafty spots in their homes that just never seem to warm up. They may be located by a window or door that is not properly sealed and your thermostat works very hard to reach these areas. When those spots are warmed, your furnace runs less. It usually takes this heater up to one hour to reach its best heat but once it gets there, your area is nice and toasty. It also takes the same amount of time to cool down.

What are the Benefits of Oil over Electric or Propane Heaters?

An oil-filled radiator heater is portable and energy efficient, much more than an electric unit that blasts the room with a surge of electricity or a propane heater that loses much of its fuel in waste. The nice part about an oil-filled radiator heater is that you never have to refill, is energy efficient and costs much less to operate than other traditional methods.

If you are looking for a small, dependable heat source to help keep your home less drafty this winter, an oil-filled radiator heater can be found anywhere where baseboard heaters, ceramic heaters or propane heaters are sold. A free advantage of an oil unit is that it will not dry out the air and your skin as others that blow dry air.

Benefits of Oil Filled Radiator Heaters Over Electric Or Propane Heaters

The cost for a 17 pound, 1200 to 1500 watt can be found for under 0 and runs on 110 volts. Many reviews mention that once you have tried out using oil filled heaters, you'll never used another type of portable heaters. Pick one up at your local building supply store or on the Internet and enjoy a better type of warmth this winter.

Reducing Heat Losses Through Energy Efficient Window Coverings

If your windows are ancient and aren't doing a passable job of keeping the warm air inside your house in cold weather (or keeping it out in warm weather), it might be time to consider having new, energy saving windows put in. But new windows, especially good quality energy saving ones, can be very expensive. As a result, their payback period can be quite long. For the amount of cash you would pay to redo the windows in a single big room, you can get almost the same energy efficiency with some basic weather stripping and by using energy efficient window coverings to eliminate heat transfer between your home and the out of doors.

Let's first look at how windows help keep the cold out in winter, and the hot air out in summer. Windows block heat transfer in three ways: convection, conduction, and radiation.

\"Energy Efficiency\"

Windows eliminate or reduce the convection airflow between the inside and outside, blocking heat from passing through the window along with the airflow. A leaky window, or one with cracked glass or broken putty, allows air through these gaps, so heat gets out in winter, and heat leaks in during the summer.

Reducing Heat Losses Through Energy Efficient Window Coverings

Even a very thin sheet of glass has some insulating properties, but if the glass is double-glazed and the space between the panes is an inert gas such as argon, the panes provide extra insulating value, which reduces heat transfer through conduction. Conduction is what causes the metal handles of a pot to heat up when you boil water in the pot; so you can guess that a metal window frame, if not properly built, can conduct a lot of heat. While you can't easily add extra glass sheets to a window, there are other techniques to create additional still air spaces between the window glass and the room, which will add insulation and reduce conduction losses.

Radiation, the third type of heat transfer, usually occurs when light in the infrared spectrum passes through windows, heating the air inside, or when heat inside the room radiates out through the glass. Home energy auditors sometimes take infrared photographs of a home to show where heat losses are most significant, and windows are typically one of the largest sources of heat escaping from houses in winter.

How does this knowledge about heat transfer through convection, conduction, and radiation help you cut energy losses through your windows?

The first problem to address is convection. If your windows have cracked panes, get them repaired. If you still have the old wood-framed windows with putty holding the glass in, inspect the pane for any peeling or missing putty. It's fairly easy to pull old putty out with a putty knife and put a fresh layer of putty on in its place. If the wood of the window itself is broken, or if the glass is hard to get out for replacing, you may not be able to put off getting new windows, but if you can cut the small air leaks, you'll have gone a long way towards minimizing energy losses and should feel some relief in your utility bills.

You may be surprised to learn how much heat can travel out of a home in cold weather through the wood trim around a window. Just wait for a really cold day, put all the exhaust fans on in your house( kitchen range vent, bathroom exhaust fans, etc.), and run your hand along the edges of window and exterior door trim on the inside of rooms. Anywhere you feel cold air coming in, you have a draft that should be sealed. It won't hurt to run a thin bead of clear or white caulking around window and door frames to cut this convection heat transfer.

The last thing to try to reduce convection heat transfers is to use tape-on or Zip-Loc type energy saving window kits to seal any windows that are particularly drafty, or windows that really need replacing but that can't be replaced because of your budget (or because you are renting the place). These kits are a great way to rapidly reduce your heating losses in winter: the kits normally come with several sheets of three by five foot transparent plastic, and a roll of double sided tape. (If you have a large number of windows to cover you can purchase a 48" roll of the plastic and buy the tape separately.) You measure and cut plastic rectangles slightly wider than the window, run the tape around the window frame, peel off the protective tape from the double sided tape, then set the cut plastic over the window, sealing along the tape line. Blow dry the plastic for five minutes, and it shrinks to form a tight, flat extra pane of 'glass' that is hardly unnoticeable. This plastic can hold its taut shape for months, although you may find it needs an occasional short blow dryer blast to pull up the odd wrinkle in the plastic.

The next heat loss you'll want to address is conduction - heat being conducted through the solid materials of the window. In terms of energy efficient window coverings, your goal here isn't actually to avoid this conduction - you can't usually change the materials the window was made of - but to add barrier layers between the window and the room to slow the conduction down. The plastic window insulation kits stop convection heat loss by eliminating drafts into the room, but they also eliminate conduction, by providing a layer of trapped air between the window and the room. A curtain can perform the same task: when closed, the curtain traps a small amount of air between the curtain and the window, so that on a cold day the air behind the curtain naturally gets cold but the room itself stays cozy.

When you install curtains on windows to reduce conduction heat loss, it's important to think about convection currents inside the living area. Hot air rises, and cold air falls, so if you install curtains you should make sure the air currents are stopped, preferably at both the top and bottom of the curtain. Otherwise, in winter, the cold window will cool the air between the window and the window covering, and that colder air will fall to the floor, pulling warm air from above the window covering down in front of the window in a continuous cycle. In summer, the flow runs the other way, with the air between the curtain and the window warming from sunlight, rising out the top opening, and drawing cool room air up towards the glass where it gets heated.

You should block these air flows by having the curtains flush against the wall at the top and bottom, or by having the bottom touch the floor and by closing in the curtain rod area at the top.

If you have cloth blinds that cover the window, you can use Velcro tabs along the sides of the blinds that you then press into Velcro tape along the window frame; this completely seals the air space between the window and the blind, providing an above average insulation layer. Cloth blinds as well as curtains can use a similar technique but with magnetic tape in the fabric, and metal on the framing, so that the cloth sticks to the walls on either side of and below the opening.

Another way you can try to add an insulation barrier to conduction through the window is to buy cellular blinds, which are made in a cellular or honeycomb cross section, or other blinds that incorporate a hollow space within the blind. Cellular blinds when fully pulled up use almost no space and the cells fold shut; when extended, they can add insulating value to a window from R-2 (for single-cell thickness) to R-5 (for double-cell).

Window blinds can help address the final type of heat transfer, radiation, by preventing heat from radiating through the glass (into the room from sunshine in summer, and towards the outside from the indoor radiant heat in cold weather). The most effective blinds use light, reflective colors on the outside, so that sunlight in summer is more or less completely reflected away from the room. Good window blinds can reflect sufficient solar energy away from a room to reduce heat gain by as much as 45%, but they do very little to the R-value of the window, so have little effect in winter.

Roller shades, which have a wind-up axle and can be pulled up or down (we used to call these blinds when I was young) are a great radiation reflector, and also provide superior insulating value to reduce convection air flows around the window that lead to conduction losses through the glass or window frame. Roller shades, because they are placed so close to the glass, do well at reducing convection currents, especially if their side edges and bottom are attached to the window frame (side tracks are used to accomplish this). Loose-sided shades can reduce heat transfer by up to 28%, while attached-edge shades reduce it up to 45%. Shades that can be reversed, with one side dark and the other light, are even better, because you can use the light side to reflect the heat where you want it (keep it out in hot weather, inside during winter).

Awnings and overhangs are a good way to cut direct light from entering a home and heating it up in summer. Because the solar angle is lower in the winter, such window coverings only block the sunlight you don't want, allowing the lower-angled winter sun in to help heat your home.

Storm windows - which were added to many older homes - can be up to 50% more energy efficient than single-pane windows, provided the storms are properly sealed against air leakage. So if you have old wooden-framed storms sitting around in your basement or garage, you should put them on each fall and take them down once winter has passed. If you have aluminum framed storms you can typically leave them up year round; just don't forget to slide the glass sash shut when autumn comes.

Windows form such a small percentage of the surface area of a house, yet they are one of the biggest potential sources of energy waste in a house being heated or air conditioned. So you should strive to do anything you can to restrict heat transfer through convection, conduction, and radiation. Just remember to set aside a portion of the money you save on reduced utility bills, so you can replace any old, energy wasting windows with brand new, energy efficient ones when the time comes.

Reducing Heat Losses Through Energy Efficient Window Coverings

Robin Green runs Green-Energy-Efficient-Homes.com, a website that helps people save energy in their homes. For more on energy saving window treatments, see Energy saving window coverings on Green Energy Efficient Homes.

Pros and Cons of Wind Turbines

Is it really worth it to build wind turbines? What are the pros and cons? We'll discuss these questions in this article.

In short: resounding yes. Many are against wind turbines and wind farm building and I have to admit they have a few good reasons other than the childish "I don't like the look of wind mills in the countryside". Well, I don't like that the Arctic is getting smaller and smaller every day, and the fact that maybe my children won't be able to experience the world as it is today. Letting go of the untouched view is a small sacrifice in exchange for nothing less than the whole future of the Earth.

\"Energy Efficiency\"

Other than the "threat" to the panorama there are a few reasons why one wouldn't choose wind turbines over regular electricity generation. Here are a few examples.

Pros and Cons of Wind Turbines

- Wind turbines do not produce constantly. Their performance varies based on the actual power of the wind. This can be from zero to storm force!

- Efficiency is not the best available: a modern turbine running at its desired speed can deliver electricity to 500 households. Count quickly how many would be needed for a city with a population of 20 million?

- It is not true that wind turbines are 100% environment friendly, because when factories build them, they do emit some pollution into the air. But that is a onetime pollution against the constant negative effects of regular electricity production with for example burning of coal.

- They are noisy mechanisms. One turbine can produce the same level of noise as a car travelling at 60mph on the highway! You certainly don't want that under your window constantly. But almost all of these are against the larger, industrial versions, not the ones built for home usage.

Now let's hear a few pros!

- The wind is free, and it can be captured with good efficiency nowadays compared to the results some decades ago.

- They do not take large portion of lands like solar farms do! The land around these small towers can be cultivated or used in a different way without any problems!

- A large group of people thinks they add to the view of the landscape!

- If you live on the top of the hill or miles away from any civilization you can still generate your own power with smaller wind turbines!

Pros and Cons of Wind Turbines

- And the last and best one: you can build a wind turbine yourself [http://www.wereview-youdecide.com/2009/01/review-and-evaluation-of-the-earth-4-energy-renewable-energy-production-guide/]! It's an easy process and there are complete guides [http://www.wereview-youdecide.com/2009/01/review-and-evaluation-of-the-earth-4-energy-renewable-energy-production-guide/] available.

How to Make a Solar Oven - Making a Homemade Solar Oven

Solar power has a wide array of uses, like using it in to power cars, small boats, and homes. You can also use solar power to cook food through the use of a homemade solar oven. You do not have to be a professional to take advantage of the sun's energy since it is simple to do with the right guide, and you can do this at home. All you need are a few simple materials and a little ingenuity, and you will then know on how to make a solar oven.

How do Solar Ovens Work?

\"Energy Efficiency\"

Because the sun is a great producer of heat for our planet, what you have to do is to harness it to build simple devices. These devices will amplify the sun's heat exactly where you want it, and this is the principle behind making a solar oven. The solar oven or cooker will then cook a variety of foods at a temperature of around 200 degrees Fahrenheit depending on your location. It is far less expensive and perfect for outdoor meals.

How to Make a Solar Oven - Making a Homemade Solar Oven

What are the materials in building a solar cooker or oven?

The materials you need are:

1. pizza box
2. plastic wrap
3. black construction paper
4. aluminum foil
5. tape or glue.

A knife to cut a hole in the box is also needed, and a stick to prop open the door on your solar cooker/oven.

Here are the steps :

Cutting the Lid

First thing when building your solar oven or cooker is to cut a hole into the lid of your pizza box. So that the lid can flap open, cut around three edges, leaving about 1 inch of space on each edge. Do not completely remove the lid. If you make a mistake, just tape it on with a heavy duty tape.

Building the Solar Reflector

Fold the flap out so that it can stand up on its own. Use the stick to secure it on a desirable position. Completely cover the inside of the lid with aluminum foil, and use the tape or glue. This foil will reflect the sun's rays to the pizza box.

Making the Window

Get your plastic wrap and create a window over the hole on the pizza box. Open the box and flip it over so you will be able to look through the hole. Put the plastic wrap over the hole and tape it.

Heating things up

Take the aluminum foil and line the inside of the box with it. Cover the aluminum with the black construction paper. This will absorb the heat that is produced in your pizza box. The heat absorbent construction paper and the heat reflective aluminum foil will create an oven atmosphere in your solar oven.

Now that you have made your solar oven or cooker, it's time to use it. Bring it to a sunny spot and open the lid. Also adjust the opening so that sunlight is reflected off the lid and into the plastic window. You now know on how to make a solar oven or cooker.

How to Make a Solar Oven - Making a Homemade Solar Oven

Do you know that you only need the top guide to use everything solar in your home, RV, pool, boats, and many others?

www.FullEarth4EnergyReview.com will show you this to you.

Materials Which Absorb Solar Energy

Solar energy is simply energy which comes from the sun's power. This natural energy source can be used for a wide variety of things inside your home. Many people think of using solar energy for their electricity needs, and that is certainly an excellent way to use it. In most cases though, you can actually just use the sun's energy to help heat your home naturally. Doing this does not require the use of solar panels, solar cells, storage batteries, or any complicated grid setup. Of course you'll get much more benefit from setting up an actual solar power system using panels and grids, but if you simply want to start utilizing the natural power of the sun today, there are several ways you can do so.

Essentially all you need to do is set up a way to absorb the heat from the sun. In the winter for example, you can start reducing your electric bill by allowing the sun to supply some of the heat for your home. The easiest way to do this is to just open the curtains and allow the sun to shine into your home during the daylight hours. The sunlight will naturally bring warmth, and items inside your home will actually absorb that warmth too. Any items which help absorb the warmth from the sun will also help your house retain some of that heat after the sun goes down.

\"Energy Efficiency\"

You'll have much better results though if you purposely set out to try and absorb as much of the sun's heat as you can each day. And to do this, you simply need to know which types of materials absorb and retain the sun's heat easily.

Materials Which Absorb Solar Energy

Most types of metal for example will absorb heat quickly and easily. Some metal gets hot faster than others and releases that heat much more slowly. If you lay a sheet of copper in the sun for example, you'll notice it gets hot quite quickly. Once the sun goes down, the copper will start releasing its heat into the air around it. And this can be used as a natural heating system for your home. You could do the same type of thing with most metals.

Dark colored items also get hot quickly. You may have experienced this yourself in the summertime actually. Getting inside of a vehicle which has black seats will be much hotter to the touch than getting inside of one which has light-colored seats. And you can use this to your advantage when heating your home in the winter time as well. If you have dark colored furniture, then simply positioning them in a location of the room which gets sunlight during the day will allow them to absorb heat. You can also place dark curtains at the window, or position dark pieces of furniture, accents, or decor in the sunlight too.

Other materials which absorb heat very nicely include concrete, brick, Adobe, and water. If you live in a home which has concrete or brick walls for example, those walls will absorb heat from the sun throughout the day and store it. Then as the nighttime coolness creeps in the stored heat will slowly be released which helps maintain a comfortable temperature in your home while using less electricity.

Materials Which Absorb Solar Energy

©2008, Kathy Burns-Millyard. Get the latest solar power news, tips, information, tutorials, and advice plus learn more about solar water heating, solar cooking, solar electricity and much more at OfficialSolarPower.com

Can You Really Make Money With Solar Power?

What's the real truth behind all those ads?

Just searching around online for information about solar power, solar energy, and installing solar panels on your own home, you've probably run across many claims which say you can earn money from solar power. So is it true? Yes... sort of.

\"Energy Efficiency\"

You see, it's not nearly as cut and dry as many advertisements would lead you to believe. There is a process involved, and for most people it requires extensive investments before you can actually start "making money" from the solar power you're generating.

Can You Really Make Money With Solar Power?

It's becoming a well known fact that installing solar panels on your home can drastically reduce your electricity bills. In fact, if you install enough of them, you can eliminate your monthly electric bill entirely. And if you happen to generate extra electricity... and you live in the appropriate place... you might be able to get "paid" for the solar power you generate.

The catch though, is that you have to be generating more power from your solar panels than you actually use.

Most residential solar installations only provide part of the total household electric usage, because installing a large enough solar panel system to cover the entire load can cost upwards of ,000. And even though building your own solar panels is much less expensive at an average of about 0 per panel, many standard size households in the United States need 10-20 panels just to get close to covering their own electricity usages each month.

Here's how the reality tends to work for most American families:

1. They install a small, starter solar panel system that's relatively inexpensive. This system helps them reduce their overall monthly electric bill, but in most cases the starter system only provides enough electricity to reduce the bills by 30%-50%.

Larger reductions can be obtained easily of course, simply by installing a larger solar panel system right from the start. Not everyone can afford that large initial investment though, so they go with a starter system instead.

2. Over time the family may add to their home solar panel array. As you add solar panels, you continue taking more of the load off of public electricity needs. This of course continues lowering your electricity bills.

3. If the family continues investing in additional solar panels over time, they will eventually reach the point where they are providing 100% of their own home's electricity needs. This is when the public electric bill is hopefully at .00 per month year round.

At that point, if the family wants to start "earning money" from their solar power installation, they will need to reduce their own power consumption, install more solar panels, or both. The only way they can earn money directly from this investment is to generate extra electrical power which can be sold back to the public electric company.

Not all electric companies will actually "buy back" the power you generate either. In fact, most of them simply give you energy credits which can be applied to your existing utility bill. In most cases if you have no electric bill to pay though, those credits can be cashed in a few times each year, for a partial part of their value.

So before you decide to install solar panels as a way to make money, evaluate your true situation first. Figure out how much electricity your family uses on average, and use that figure to know how many solar panels you'll need to buy. Calculate that cost first and if you're still determined to try and make money from this venture, research your local laws. Also be sure to talk to your local power company so you'll know their policies and restrictions before you invest more money than you need to.

Can You Really Make Money With Solar Power?

Related Reading: How Much Solar Power Do I Need?