Best Way on Testing Laptop Backlight (CCFL) and Inverter

We will be concentrating on LCD Inverter and CCFL bulb.

Laptop with black screen problem is commonly caused by:

1. a defective backlight, which is the cold cathode fluorescent lamp (CCFL) bulb malfunction
2. defective laptop’s inverter board
3. no video output going to the LCD Screen

It is not an easy job repairing laptops specially if we don’t have parts that we can use to replace to the parts we are suspecting to be the culprit. So now, we will going to try to make our own tools for testing a bad CCFL backlight of a laptop.

Tools Needed For this Project:

1. 9volts battery
2. 9v battery connector
3. known good CCFL inverter from any laptop or LCD monitor.

Once you have the tools that we needed, we can continue to the next procedure.

About The Video Output:

If the laptop is equipped with an external monitor connector, we can easily check if the problem of having a black screen is caused by a faulty video card or GPU within the laptop or maybe the problem resides inside the LCD which is the inverter and CCFL bulb.

Connect an external monitor to the VGA Port of the laptop and check if there is a video output to the monitor.

There is some model of laptop that requires you to press a FN key plus a key with a picture of a monitor to switch between the LCD laptop to external monitor.

Then now, if you get a video on your external monitor then you now know there is a LCD screen, CCFL bulb and inverter board problem. If the external monitor doesn’t get any video at all, then suspect a video (GPU) or video cable problem.

Checking the CCFL Bulb:

On checking whether your CCFL bulb if it is still functional, we can use our own known good inverter to test the CCFL bulb is still working or in good condition.

Using the Known Good Inverter:

Now, with our known good inverter, connect the CCFL bulb. And next, supplies a power to it using our 9v battery. A laptop inverter is usually powered by 12v and up but with our 9v battery, it is just enough to start the circuit of an inverter.

Connect the black probe from our battery source to the yellow wire, which is usually the 12v supply coming from laptop circuits, but to find more accurately the connection of the power source of an inverter, all you have to do is to find where is the connection of the SMD fuse in the circuit of the inverter. And the black probe to the ground screw hole of the inverter board.If our CCFL bulb lights up like in the picture below, then we now know that our CCFL bulb is good and working and now we can suspect that our inverter board is bad.

Checking Inverter:

Since that our known good inverter have able to light up the LCD Screen, and then connect the inverter of the laptop back to its position. Then we are going to conduct a test to it using the procedure we did to our known good inverter. And if it won’t lights up the CCFL bulb, then we can suspect that our inverter is defective and needs to be replaced to a new one or simply you can check it if the fuse is open. If it is open, try to make a jumper through the fuse using a thin wire to serves as our fuse, then redo the testing again with same procedure as we use on our known good inverter.

Checking the Power Supply Line:

If our known good inverter light up our CCFL bulb and the Laptop’s inverter also lights up using the 9v battery as its power source, then we are going to suspect the 12 volts power supply line from the laptop’s motherboard.

Let us get our multitester/multimeter and set it to DC Volts.

Plugged our AC Adapter and turn on our Laptop.

Put the black probe to the ground screw hole on the motherboard and the red probe to the yellow or the supply line and see if you have a voltage reading on that connection.

If you are can’t read any voltages from the connector then let us suspect a problem on the motherboard itself and this needs a lot of knowledge and experience on repairing Laptop.

At this point, we will have to bring the unit to a technician who have the knowledge of repairing a complicated problem of a Laptop.

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How-To Make Transformless Power Supply

Upon surfing the net, I have found this site: http://electroschematics.com displaying their projects on making a Transformerless Power Supply with a 12 volts output voltage and a current of 100mA.

This is a transformerless power supply for low current applications. C1 is the X rated AC capacitor that reduces high volt AC. D1-D4 rectifies AC to DC and C2 removes ripples. R1 is the bleeder to remove stored current in AC when power is off. R2 limits inrush current. A Zener can be used in the output to get regulated DC.

Schematic Diagram of Transformerless Power Supply

We usually see this kind of power supply on a China made model of rechargeable products like flashlights and mosquito killer. This circuit catches my attention because of its application in our work which needs a power supply and we can also use this power low current circuits like some of our projects that don’t needs too much power requirements.

Caution! Circuit is lethal since it carries high volt AC. Do not touch or test when connected to Mains. Enclose in a shock proof case.

Note: “Be careful, this circuit is not isolated from 220 volts AC. It needs some extra care in handling this kind of supply. Dangerous High Voltage AC.”

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Do-It-Yourself Piso Net

The Piso Net is most like the absolute solution for Internet Cafe owner that needless manning, for a minimum of single person to manage the small business. This Piso Net kit can be DIY and everything is available at Raon, Quiapo, Manila.

Just few of screenshot of the Piso Net kit, this Piso Net kit is also customizable that fits your needs.

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Piso Net Snap Review

Piso Net is a token Internet with your 1 (one) peso coin you can already usedand surf the net, the concept is just similar to the amusement token games before you can play you must insert first your token and the timer will starts.

Piso Net has been making quite a buzz in the metro since early 2010, but it’s not only until recently that the enterprise got the attention of business-minded folks. So what is Piso Net and how are things from a business standpoint? Is it really a viable source of extra income?

Piso Net is basically a merge of PC rental and Arcade rental services wherein customers can pay the services by inserting coins to the machine. The rate is typically 4mins/peso which also amounts to the typical Internet Cafe rate of Php15/hr. This rate can be tweaked higher or lower either to be more competitive and entice customers or gain more income by decreasing the minutes/peso.

So if there’s not much difference in pricing, what is the advantage of Piso Net over traditional Internet Cafe's? Well some internet Cafe have a fixed rates and minimum minutes of usage, this makes for not-so ideal scenario for budget-conscious Pinoys. And although the rate is the same, Piso Net offers a much flexible alternative that most internet Cafes don't and that is to have more control on how much time and money a customer is willing to spend at a given time.

The setup is rather simple with the bare PC parts are inside a wooden box similar to that of an Arcade machine or Videoke machine. Much like the Arcade machine, it is activated by inserting coin/s which triggers the machine. Once the time is consumed, the machine cuts off the display and will resume when a coin is inserted. The bottom wooden part inside the machine has a carved hole to collect the coins.

Now that you have a better perspective of how it works, let’s delve in to the business side of things. PC Express is one of the known providers of Piso Net machines. They offer a variety of configurations pegged at different price points.

Here are the available configurations on their website.

Intel Core i3-2100 3.10GHz dual-core
120GB/250GB IDE HDD
4GB DDR3 1333MHz RAM
NVidia GT430 1Gb DDR3 VRAM
18.5" BenQ LED Monitor
Creative 2W speakers
Php23,995

Intel Pentium dual-core G620 2.60GHz
120GB/250GB IDE HDD
4GB DDR3 1333MHz RAM
Radeon HD5570 1GB DDR3 VRAM
18.5" BenQ LED Monitor
Creative 2W speakers
Php21,495

There are also other providers who offer the same configuration for a cheaper price. Depending on your market, which is most of the time your neighbors, you can choose a configuration that suits your market’s needs (internet, gaming and/or document editing). Needless to say that gauging your market and choosing the right configuration is crucial to the success of the business and the amount of time to spend to return the investment.

We did some research on how things are going on a revenue standpoint. We interviewed a housewife married to an OFW who runs a 3 Piso Net units business for little over six months now. She got it for Php20,000 apiece and placed it in small space inside their house. According to her the monthly revenue averages at Php17,000/month. If we break down on a per week and per day, the revenues averages at Php4,265 and Php610 respectively. So a Piso Net unit generates more or less Php5,600/month, Php1,410/week and Php200 a day. This revenue is based on 16×7 operation on a not-so developed areas.

In terms of cost of operation, she said that the 3 units electricity consumption amounts to Php2,700 per month and Php1,000 for the internet service connection. Since she’s not paying for the rental location, the total cost of operation only sums to Php3,700 per month. So if we deduct the TCO from the monthly average revenue (17,000 minus 3,700), you'd have an average net revenue of Php13,300 per month. At this pace, the turnaround for the return of investment is only 5 months.

Another benefit of Piso Net is that it requires less effort to maintain unlike with Internet Cafes. All the personnel need to do is to make sure that he/she has more than enough stock of 1 peso coins and units are pretty much on auto-pilot. I only wish that the future iteration of the machine supports coin amounts bigger than a Peso because it can be a pain in the neck to drop a coin every now and then.

So is the Piso Net a lucrative business? Given the breakdown of revenue and the right circumstances, yes we think it is a viable source of extra income. But in any business there will be potential drawbacks, we'd like to hear your thoughts on what are the potential disadvantages of running a Piso Net business.

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How-To Make Your Own Isolation Transformer

According to Wikipedia, “An isolation transformer is a transformer used to transfer electrical power from a source of alternating current (AC) power to some equipment or device while isolating the powered device from the power source, usually for safety.”

Circuit Diagram of Isolation Transformer Using Two Transformer

Making your very own Isolation Transformer can keep you away from the risk of hazardous electrical shock while we are doing some repairs. According to Mi25, ” It also keeps us away from further damage to the equipment we are repairing like TV set, power supplies, and amplifiers that are under test condition because it will make the AC output low. This may not absolutely prevent component damage but it will surely helps in most cases.”

Here are the sample photos of the isolation transformer based on the circuit diagram above:

Use two identical transformer with a 6amp/22o volts with an output of 12v-0v-12v center tap.

Connect it back to back the 12v-12v. The 0v don’t have any connection at all.

Completely wired with neon lamp connected as its power indicator.

Isolation Transformer Powering a 220V/100watt bulb this article and images are all credits to: Mi25 of Elab Forum

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Major Health Hazards of Using Compact Fluorescent Lights

Today majority of the people are concerned about environmental safety and take adequate measures to reduce green house effect. One of the simplest methods to protect the environment is with the use of CFL bulbs. Compact Fluorescent Lights are known to be energy efficient and inexpensive in comparison to ordinary incandescent bulbs. Today it is widely used all over the world as it possesses many beneficial features.

However, most people are unaware of its grave drawbacks even though it helps to conserve energy. It includes a greater health risk in comparison to the ordinary incandescent light bulbs. There are many serious health risks associated with the use of Compact Fluorescent Light bulbs and some of the most important drawbacks are elaborated in the following sections of this article.

Dangers of Using CFL Bulbs:

Mercury Content: The Compact Fluorescent Light bulbs are actually hazardous to the environment as it contains mercury. Mercury is a powerful neurotoxin that affects the functions of the neurotransmitters of the human brain. It also causes serious damages to the cell and tissues of the body. Exposure to mercury can cause autism, infertility, thyroid disorders, anxiety, memory loss and depression. It is highly dangerous to pets, pregnant women and small children.

The mercury contained in the bulbs pose little threat to the environment but when it is broken, it releases toxic fumes which are very harmful to health. It is hazardous to the environment when it is disposed in garbage cans and land fills. With the use of cfl bulbs, mankind is exposed to various types of illnesses. Today it is considered to be a hazardous waste material which should not be disposed in landfills and garbage cans.

Migraines: The use of CFL bulbs are also related to migraine attacks. Most people experience headaches and strains due to the excessive usage of these light bulbs. In the earlier days, CFL bulbs used to flicker which may have caused migraine attacks. There are no substantial evidence to prove the relation between migraine attacks and fluorescent lights. But many people have experienced headaches and blurring visions with the use of these light bulbs.

UV Emissions: Fluorescent light bulbs also emit ultraviolet rays and so it is considered to be harmful to human health. People experience skin rashes and other ailments due to the use of CFL bulbs. It also proves to be detrimental to people suffering from skin disorders.

Radio Frequency Radiation: Compact Fluorescent Light bulbs emit radio frequency radiations which affects the functions of wireless instruments.

Despite the consequences, CFL bulbs are used in homes, office spaces and other places as it is still considered to be one of the best lighting options. However, there are some steps which can be followed to avoid potential health hazards.

•  Choose to buy fluorescent lights with low UV radiation
•  Handle these bulbs with care
•  Buy bulbs with glass covers that will prevent UV radiation
•  Take proper measures to clean the area if the bulb breaks

LED and incandescent bulbs are still considered to be the best lighting options as it is safer and eco-friendly.

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Compact Fluorescent Lights And Environmental Issues

CFL (Compact fluorescent lights) bulbs are seen as an environmentally friendly replacement for incandescent lights. But are they really as good for the environment as claimed? The two issues often raised as arguments against using CFL's are

1 - It requires more energy to manufacture a CFL than an incandescent lamp.

2 - CFL's contain mercury which can potentially end up polluting the environment.

The first issue is fairly easily answered in that even though they do require additional energy to manufacture; this is soon offset as CFLs last a lot longer than incandescent bulb.

On this issue of mercury pollution I have summarized some of the for and against points of view below:

Arguments For CFL's

• Overall mercury emission by compact fluorescent lamps is less than the mercury released into the atmosphere by coal-fired power generation for an equivalent incandescent lamp over the same period. This assumption is based on the electricity generated to run lighting in your local area being generated via coal fired power stations. While this currently (2007) the case in Australia many places in the world today generate their electricity by other more environmentally friendly means.
• Mercury from used CFLs in landfills is not released into air and with proper disposal will not be released into the subsurface or groundwater.
• The mercury content of CFLs that use 25 to 40 watts of electricity will be capped at 6 mg per unit (this is proposed in the United States)
• Because CFLs longer life cycle, fewer bulbs and less packaging ends up in landfill.

Arguments Against CFL's

• Many places in the world produce little energy from coal fired power plants (eg California). In the USA coal plants are now mandated to reduce their mercury emissions by between 70% and 90%.The issue of mercury is therefore likely to become more significant as electricity generation gets cleaner and CFLs become more widespread.
• The 6mg of mercury claimed for CFL's is largely a goal at present and not the current reality.
• A lot of CFL's are made in China with energy sourced from coal fired power plants.
• CFL's are delivered here on ships using bunker oil, the worst mercury producer of the fuel oils.
• There are currently very few recycling program in place or planned to handle the number of CFL's proposed.

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Kabang : famed dog lost her snout and upper jaw for saving lives

SAN FRANCISCO -- A famed dog that lost her snout and upper jaw saving two girls' lives in the Philippines was released from a California hospital Monday, officials said.

The dog – named Kabang – will be headed back to its owner in the Philippines following treatment at the University of California, Davis veterinary hospital, said UC Davis veterinary professor Frank Verstraete. Doctors at the hospital performed surgery to heal her wounds, though they could not reconstruct Kabang's jaw or snout, Verstraete said.

"She's a very, very happy, functional dog, and that is all that we were after," Verstraete said.

Kabang had her snout and upper jaw sheared off in December 2011 when she jumped in front of a motorcycle in the Philippines. She saved the lives of her owner's daughter and niece, who were apparently in the path of the oncoming cycle.

Nearly a year after Kabang sustained the injuries, a nurse from Buffalo, N.Y. was able to raise the money to bring her to the U.S. Veterinarians in the Philippines were apparently unable to treat her injuries.

Doctors at UC Davis were unable to perform surgery on Kabang initially because she needed to be treated for other ailments, including a tumor and heartworms. Treatment of those ailments would have prevented her wounds from healing.

Doctors took skin from her cheeks, neck, and forehead to cover up sensitive areas that were exposed on her face during the March surgery, Verstraete said.

Kabang is expected to fly back to the Philippines on Thursday. Via huffingtonpost

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Health Benefits of Alkaline Water

Water is the most important element of sustaining life. Water is also an important health nutrient. It is recommended that one drinks minimum of eight glasses of water to maintain the elasticity of the skin, to regulate body temperature, for absorption of nutrients into the blood and for transporting oxygen and nutrients to the cells. Do you know drinking water is essential to remove the toxins from the body and for proper bowel movements? However, the question is, are you drinking quality water? Does the water contain alkaline?

What is Alkaline Water?

Water which is neither neutral nor acidic on the pH scale is known as the alkaline water. In fact, the level of pH is higher in alkalized, or ionized, water compared to the normal tap water. Natural alkaline water is found in the springs, ponds and deep wells in the higher altitudes. It is also found in glacial runoff streams and mountain wells. However, alkaline water can be acquired in your home because it can be created using a water ionizer.

The Benefits of Alkaline Water

Drinking alkalized water has many benefits because alkaline neutralizes acid. Consumption of this water facilitates body to reduce as well as dispose off the acidic wastes. Remember, accumulation of acidic waste leads to aging. Alkaline water helps to reverse aging by dissolving acid wastes. However, you must understand water that is ionized is not a medicine but only an agent that has the ability to retain your health and youth. Let's delve into the benefits of ionized water.

To prevent your body from dehydration you need to drink at least four liters of water that is rich in minerals and alkaline. Alkaline water has a pH value between 8 and 9 and this helps in hydration. It is also an excellent conductor of electrochemical activity between cells. By flushing out the toxins and acids from the body, this water helps in regulating all the cellular functions from the heart beats to the neural performances of the brain.

Drinking water water before you eat helps in weight reduction. It is a fact that food cravings are more extreme when you are thirsty. Quenching your thirst can lead to eating less and healthier food.

Studies show that alkaline water is an anti-oxidant and helps to increase the energy level of your body. It also facilitates clarity of mind due to extra oxygen content.

Drinking ionized water before or after meals would enhance efficient absorption of nutrients and also improves digestion. In brief, alkaline water helps to maintain the pH level of your body. You can rightly say that it is one of the keys to stay healthy and young.

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Backtrack 5 OpenVas Tutorial

OpenVas is a open source vulnerability assesment system just like nessus, openVas used to find the vulnerabilities on a computer system, it is open source so you dont need to buy it, however you can get home feed of nessus for free too, but we consider both of them.

You can find nessus on backtrack 5 but you have to install openvas on backtrack5, so below is the tutorial for Openvas it includes how to install openvas in backtrack 5 and some basic usage.

Backtrack5 is not necessary to run openvas, if you are using some other version of backtrack or if you are using some other distro like Ubuntu than the procedure is same.

How To Install OpenVas

Open terminal on bt5 or ubuntu and type exactly

root@bt:~# apt-get install openvas

root@bt:~# sudo apt-get update

It begins your openvas installation and update all the applications. When Openvas has been installed you can find it on Application --> Backtrack --> Vulnerability assessment --> vulnerability scanner --> Openvas . See the picture.

On the next step click on openvas-check-setup, it will show you the problem and suggest some solution.
Its time to add user, from the menu select Openvas adduser, enter the login name and password, for rule type ctrl-d.

Now click on OpenVas NVT sync, by this you will get the latest NVT's from openvas database, you must do this step frequently to make update your Openvas.
Start openvas scanner from the menu, it may takes some time.
Open terminal for setting up openvas manager, use the command

root@bt:~# openvas-mkcert-client -n om -i

rebuild the database by the command

root@bt:~# openvasmd --rebuild

On the terminal type the command to set openvas administrator

root@bt:~# openvasad -c 'add_user' -n openvasadmin -r Admin

Now click on start Openvas manager from the menu and use the command.

root@bt:~# openvasmd -p 9390 -a 127.0.0.1

Start openvas administrator from the menu and type

root@bt:~# openvasad -a 127.0.0.1 -p 9393

Your are almost done, just start Greenbone security assistant and use

root@bt:~# gsad --http-only --listen=127.0.0.1 -p 9392

Now open your web browser and type http://127.0.0.1:9392/
Use your username and password that has been set on previous step.

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Free Energy Generator believe it or not!

To all my blog readers I want to share this YouTube video about this Free Energy Generator it looks like really convincing and believable without recalling your EE101. Feel free and enjoy watching to this video and credits to the uploader.

To prove this video for my hesitation I will start soon collecting all these electronics motors, magnet and the coils. It looks like this is unbelievable to my knowledge.

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Low-Head Microhydro - Thai Style

For the past several years, Chris Greacen has been living in Bangkok, Thailand, with his wife Chom and their two children, 5-year-old Ty and 3-year-old Isara. He and Chom run a small, nonprofit organization called Palang Thai. (“Palang” means energy or empowerment. “Thai” means freedom or independence.) Through policy and hands-on activities, the organization works to improve governance in the region’s energy sector, and to increase the use of renewable energy in Thailand and the Mekong region of Southeast Asia. They’ve enjoyed several victories in their tenure: drafting Thailand’s net metering regulations, helping to shape legislation that establishes an independent energy regulator, and installing solar-electric systems for medical clinics in war-torn areas of Burma (see “Solar Lights for a Dark Time in Burma” in HP113). Here Chris writes about one of their most recent projects: the installation of a low-head microhydro system in northern Thailand.

Last summer, while my family and I were visiting Doi Inthanon National Park in northern Thailand, we spent some time in Mae Klang Luang—a hill-tribe village about 12 miles inside the park. Though the 200-year-old village only recently opened its doors to tourists, it has quickly become a sought-after destination for its cultural and ecological allure. The village sits in the shadow of Doi Inthanon, Thailand’s tallest mountain—among the easternmost beginnings of the Himalayas. The villagers are members of the Karen ethnic minority who migrated to the Thai/Burma area centuries ago from Mongolia. Though the village is very traditional in most ways—the people still harvest and thresh rice by hand—the electric grid was brought into Mae Klang Luang in 2007. Even with utility electricity on hand, some of the villagers still prefer energy independence—tapping the watershed’s abundant streams and rivers to generate their own electricity.

We ended up in Mae Klang Luang after a friend told me about a homestay program that would allow us to live with a local family for a few days. Chom and I liked the idea of supporting the community while exposing our children to the Karen way of life. When we finally arrived in the village, after a two-hour car ride along winding roads, we were surprised to find a film production crew, complete with police barricades, setting up to film a documentary that involved a member of the Thai royal family. An overzealous policeman told us that we could not stay in the village and we would have to turn back. Luckily, a local man, admittedly upset by the policeman’s readiness to turn away tourism dollars, overheard the conversation and intervened. Our new friend introduced himself as Somsak Khiriphumthong and directed us down the road to a host home.

Later that evening, I met up with Somsak at a bamboo shed where community members gather to roast, grind, and drink locally produced organic coffee. I came to learn that Somsak runs a training center that teaches local people about the importance of organic farming, environmental preservation, and watershed management. His mission, as he explained, is to promote ecologically sound microenterprise while still preserving the cultural traditions of his people. Somewhere between our first and second cups of coffee, the topic shifted to renewable energy and my work with Palang Thai.

Somsak admitted that he had reluctantly brought grid electricity to the training center from the Provincial Electricity Authority (PEA), Thailand’s rural distribution company. Initially he had resisted using PEA because of his concern for the environment. “Trees have to be cut down to get the power poles in, and PEA electricity comes from Thailand’s mineral resources, like coal,” says Somsak. “When they take coal from the mountains, they destroy them, and the air too. Plus, PEA power means paying a bill every month.”

Even with grid electricity now on site, Somsak was still interested in using a nearby stream to generate electricity to power some of the center’s loads. Somsak said that he had tried his hand at hydro-electricity several years ago, and rehashed one failed attempt that involved a makeshift Pelton turbine he made from a bicycle wheel and an automotive alternator. After talking some more about the water resource at the center, I said, “Well, I know of a turbine that I can bring up. Let’s do it.”

Back for the Installation

In November, I made my way back to Mae Klang Luang with a $90 Vietnamese-manufactured, low-head hydro turbine in hand. While the use of these turbines is still fairly uncommon in this region, they are popular with the few locals who already use them, primarily due to the units’ low cost. The fact that the technology is pretty straightforward is attractive too. There are few parts, worn-out bearings can be easily replaced, and the weir and waterway that deliver water to the turbine can be inexpensively built using local lumber, rocks, sandbags, and bamboo.

The turbine I purchased for Somsak’s installation came equipped with a guide vane and propeller assembly, a 2-foot-long enclosed shaft, and a permanent-magnet, 220-volt (nominal) AC alternator. The $90 price tag also included a small voltage controller. The turbine/controller combination is designed to power AC loads directly, without any kind of battery storage in the system. If the combined household electric load is insufficient, the controller’s simple transistor circuit drives a silicon-controlled rectifier (SCR) to maintain a constant load on the turbine by diverting excess electricity to a resistive submersible heating element. This control method regulates the turbine’s AC voltage.

Prior to my arrival, Somsak and his friends had built a small support for the turbine’s trough (waterway) from scrap wood and bamboo. The support, which needed to be strong enough to support the weight of the trough, turbine, and several hundred pounds of water, was positioned near a small stream that runs year-round by the training center. At this location, the streambed dropped about 6 feet over a 15-foot span.

When I arrived in Mae Klang Luang, we immediately got to work building a 15-foot-long waterway in two sections, using lumber and bamboo that was on hand. Much of the work was done with a multitool and a machete—though we grabbed hammers, wire cutters, and screwdrivers as needed. We cut a 6-inch-diameter hole for the turbine in the bottom of one end of the trough and wrapped the end with a rounded section of galvanized sheet metal.

Once the waterway was fastened to the bamboo support structure, we secured the bottom of the turbine in the trough and then fit the draft tube—6.5 feet of 6-inch PVC pipe—to the base of the trough. We positioned the pipe slightly above the streambed but still submersed in the pool below so that the water discharge from the draft tube was unobstructed.

The wiring of the project was pretty simple. We ran 150 feet of cable from the turbine to the controller, which we mounted inside one of the center’s buildings. We installed the diversion-heating element in a 20-gallon bucket of water located under the building to keep it away from the village children. I made sure Somsak understood it was imperative to keep the diversion load submerged to prevent it from burning out.

Up & Running

After everything was installed, we went over the hydro setup one last time, double-checking the wiring and installation details. Once we determined that everything was good to go, we opened the intake in the stream, watched the trough fill with water, and listened as the hydro turbine spun.

Along with the turbine’s whirring, a loud sucking sound caught our attention. Through trial and error, we discovered that a bad seal between the draft tube and the trough was affecting the turbine’s output. Somsak disappeared for a bit and miraculously, considering our remote location, came back with a sheet of firm synthetic sponge material used to make the soles of sandals, the locals’ preferred footwear. We cut a gasket from the material, fit it between the trough and draft tube, and just like that, the turbine’s output jumped to 0.7 amps at 220 VAC—154 watts—from about 500 gallons per minute of water falling only 6 feet.

I did a little more geeking with my digital multimeter and noticed that the turbine’s voltage controller seemed to produce a waveform with considerable harmonics. At one point, my meter, obviously reading the third harmonic, indicated a frequency of 155 hertz. This “dirty” waveform really wasn’t very surprising. The control unit operates by slicing part of the alternator’s sine wave to send to the diversion load, which means that only a sliced portion of the waveform is going to the appliances. For lighting, fluorescent bulbs with the old-fashioned magnetic ballasts seem to be more tolerant of the turbine’s low power quality than compact fluorescents (CFs) with electronic ballasts.

Power quality aside, our hydro installation was both fun and successful, and Somsak was delighted to have a functioning hydro system at the education center. The turbine powers fluorescent lights in several buildings and the occasional small appliance, like a radio or CD player.

Low Head & Low Cost

Reportedly, 100,000 low-head hydro turbines have been installed in rural Vietnam. And every one of these turbines creates more interest in utilizing local hydro resources to generate renewable electricity at remote sites beyond the reach of the utility grid. In Somsak’s case, even though utility power was available, he opted to produce his own electricity, independently—further proving that the call for clean, independent energy is not only heard across the United States, but also in the remote villages in Thailand, and everywhere in between.

Via Homepower

Access

Chris Greacen (www.palangthai.org) and his family will move stateside this spring. Thanks to a long-term lease from the Lopez Community Land Trust, the family will build a net zero energy, solar-powered home on Lopez Island in Washington’s Puget Sound.

Web Extra: Video of this project can be viewed at: www.youtube.com/profile_videos?user=cgreacen

Center for Water Resources Conservation & Development • info@warecod.org • www.warecod.org • Vietnamese low-head turbines

Energy Systems & Design • www.microhydropower.com • Canadian low-head turbine manufacturer

PowerPal • www.powerpal.com • Canadian importer of Vietnamese low-head turbines

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Solar Chimney Power Plants

Solar Chimneys work on the simple principle that hot air rises. This is the power that drove the domestic Smoke Jack which turned, for over 300 years, the roasting spits of Western Europe. However the Solar Chimney utilises solar power unlike the Smoke Jack which turns in the rising hot gasses of the cooking range.

A tall chimney is built in the center of a large transparent solar collector. The suns rays will heat the air beneath the collector and the warmed, becoming less dense, ascends the chimney. The rising hot air will cool become denser and draw up more air in the same fashion as a tall chimney. As with normal chimneys or flues the taller the chimney the greater the draught obtained .

A turbine set at the base of the chimney drives an electrical generator. Greatest power will be obtained during the day however the stored heat in the ground below the solar collector will enable the turbine to operate at reduced power during the hours of darkness.

The first Solar Chimney Power Plant was built and commissioned in 1983, in Manzanares, Spain. The project was funded by a research grant awarded by the German Federal Ministry for Research and Technology .

This Solar Chimney was in operation for approximately seven years. The successful operation of this pilot plant led to the construction of two small scale demonstration plants in Sri Lanka.

An interesting secondary use is one of Greenhouse Cultivation, since plants may be grown under 75% of of the solar collector area. The greenhouse effect provides stabile even temperature conditions. However since Solar chimneys are best sited in dry and infertile lands, in order to support intensive agriculture, additional water would be required.

Further information on Solar Chimney Power Plants can be found in this PDF format document

For information on developments in Australia see www.enviromission.com.au

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Solar Air Conditioning

This goes back to something the Romans actually did. It is called a solar chimney. It turns out that the soil about 5 feet underground remains a constant temperature year round. For instance, on the southern tip of Vancouver Island it is about 52 F year round. We don't really need air conditioning though. But a lot of furnaces bring in fresh air, so why not preheat that air from 30 F up to 52 F? So, we could use part of this system as well.

With the solar chimney, the sun heats the air in a black metal pipe or a black box acting like a solar oven. When the air gets hot it rises, but it is connected through the attic to a ceiling vent. If the windows are all closed, then this causes a suction in the house. That suction causes air to come into a lower vent that connects to a pipe or pipes that run underground like in the picture above. The pipe isn't under the house, it is just buried in the yard about 5 to 6 feet deep.

There is a lot of math involved, but you could assume certain things. First, use the 4 inch pvc pipe. Secondly, you will need about 50 feet of it per 60 - 80 cfm of air flow you need. And you would want to use a solar chimney for each pvc pipe you use. Thirdly, use one pipe for every main room in your house. If you had a dining room, kitchen, 3 bedrooms, living room and 2 bathrooms (just ignore the bathrooms) then you would need 6 pvc pipes and 6 solar chimneys on the roof. The pvc pipe would join up in a common place when they enter the house and the solar chimneys would all be running parallel. You don't have 6 seperate ceiling vents and 6 seperate cold air vents coming in.

And it is better to run 2 lengths of 50 feet than to run one at 100 feet. You get 120 - 160 cfm, plus twice the surface area for cooling.

This page talks about using the pipes with your current AC fan.
http://mb-soft.com/solar/saving.html

Warning: the above page is very long but full of some great info.

Also, if you live in a place with dry soil or if your ground temp is closer to 60 F than 50, then you will want a few more pipes. Even more if your ground temp is closer to 70 F.

But I would like to point out something because it may not hit home until you read the above link. A 50 foot pipe that is 4 inches in diameter touches over 50 square feet of soil. At 52 F soil temp, then that is about 15,000 BTU/hr cooling. After about an hour the soil temp starts to rise and eventually you are down to about 5,000 BTU/hr. But if you were just cooling one room, then it is perfect. Not because 5,000 BTU/hr is perfect for a small room, but because if you are cooling a small room, then it gets cool and you shut the system down. This gives the soil time to cool off again around the pipe. If you try to cool a whole house with the one pipe, it never would cool enough and it would run all the time and the soil temp rises and it stops cooling completely.

I am sad that all new houses weren't built with this kind of thing in mind. It can save over 100 kWh per day in the summer per house that uses this type of setup. Even if it isn't solar chimney but underground piping and existing air handler in the home. A 200 to 600 watt fan sure beats a 5,000 to 10,000 watt compressor. Imagine if the housing boom just didn't create big Mcmansions that cost more (for no good reason) but it created new houses that could add value to society. All that energy and money wasted and nothing to show for it except houses that will use up energy like nobody's business and will fall apart (due to shoddy construction and cheap parts) within 10 years. And what is really sad, a system like this could be installed by the builder for less than $1,000. But instead, that builder chose to pay more than that for a conventional air conditioner. And the system talked about on the above link uses your existing air conditioner minus the compressor. So, once it is designed and built correctly, it acts just like a conventional AC, but almost energy free. Or you could use solar and batteries for the AC fan at that point.

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Alkaline Water, the Most Effective Healthy Habit

Why Alkaline?

Research has shown that diseases cannot live in an alkaline environment. Highly acidic diets common in current lifestyles are directly related to the excessive incidence of people suffering from allergies, weight issues, premature aging and far more serious diseases. Thus by increasing alkaline intake to balance pH, our bodies will be more resistant to health issues and better equipped for disease prevention.

To really achieve and maintain a healthy pH balance in your body, you need to take your entire diet and lifestyle into consideration, ensuring you mainly consume alkaline forming foods. This could seem a daunting task and is better achieved by making small changes over a period of time. However, drinking alkaline water is a simple first step you can take to get you started on your endeavor to gain a healthier lifestyle and prevent diseases.

Alkaline Water Benefits

The importance of drinking water is already well known and consuming at least 2L a day is already high on our to-do list for health. Given that the human body is 70% water, it makes sense then that drinking alkaline water is key to obtaining a healthy pH balance and a great starting point for an alkaline diet. Specifically, alkaline water is attributed to the following:

1. High Antioxidant Power - We hear a lot about antioxidants and their ability to slow the aging process by counteracting free radicals. Free radicals enter the body quite naturally through environmental toxins found in food, water and air and they actually help the body to fight infections. However excess free radicals attack healthy cells by taking oxygen from them. Antioxidants contain surplus oxygen which is donated to free radicals thus preventing destruction of healthy cells. The antioxidants in alkaline water are especially useful as they are easily assimilated due to its liquid form.
2. Aids Colon Cleansing - The intestines is where many health issues first arise, thus it's very important for overall health to cleanse toxins from the colon. Alkaline water is very effective in flushing out toxins and poisons which cling on to the intestine walls, generally with less side effects than from other detox programs.
3. Detoxify and hydrate skin - Likewise, alkaline water is very effective in clearing the skin of unwanted toxins. When the skin is pH balanced, it is better able to absorb vital nutrients ensuring skin is rejuvenated and hydrated.
4. Aids weight loss - Fat storage is associated to high acidity in the body. By alkalizing the body we can break down fatty cells and improve digestion resulting in weight loss. Alkaline water is especially effective as it is more readily absorbed than alkaline forming foods.
5. Boost energy and fight fatigue - Fatigue is so common these days that it seems to be a normal part of life. But it's actually a side effect of too much acid in the body which dehydrates and tires the human body. Alkaline water with its high oxygen content and ability to detoxify, cleanse and hydrate naturally raises energy levels.

Sources of Alkaline Water

There are various sources available and it's probably best to experiment to find which is best for you.

• Squeezing lemon into your water is the simplest way to alkalize water at home.
• pH drops can be added directly to water.
• A water ionizer stick can be submerged in water to increase alkalinity which is great when you're on the move.
• Likewise, a portable water ionizer bottle is an excellent way to alkalize water when away from home.
• An alkaline water ionizer which connects to your faucets provides the greatest range of alkaline and acidic water in the home. This allows for acidic water to sterilize and clean cooking equipment and wounds, and alkaline water for cooking and drinking.

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Return of Solar Chimney?

"The idea for solar updraft towers…[originated in 1903]…In 1982 a German engineer…[trapped hot air] under a wide expanse of heat-absorbing material and then forced [it] up a central ventilation shaft, powering a turbine in the process…[but] only two fully-functioning solar updraft towers have ever been built: a 22-metre-high chimney in Botswana in 2005, and the 1982 prototype constructed by Jörg Schlaich of Schlaich Bergermann and Partners in Manzanares, Spain…

"Schlaich admits his pilot tower—a small-scale construction which produced up to 50 kW, had a height of 195 metres and a heat-collecting canopy measuring 46,000 sq meters…[was not optimal but] impressed with the results… In the Manzanares pilot, daytime heating of the ground under the canopy meant air continued to be heated into the night, driving the turbine around the clock. Researchers were also surprised to find that condensation allowed plants to blossom in the erstwhile dry earth…"

"…[A solar chimney] requires no water, has virtually no running costs and can be built from low-tech materials…Professor Christos Papageorgiou, whose company FSC Technologies aims to commercialise air-filled, fabric-based ‘floating solar chimneys’ in place of rigid solar updraft towers, estimates a 5 MW plant could be built for around €10 million, producing some 20 GWh per year….[FSC argues that 3% of Earth’s desert] and 1%-efficient solar aero-electric power plants…can produce 50% of [world electricity in 2050]…

"But first the concept will have to win over sceptics, including many in the investor and analyst communities…[They say solar updraft towers] are inefficient, take up a lot of land..[are] not cost-effective…[have investor-detering] long lead times…[and] might lose out to more conventional projects, such as photovoltaic arrays…"

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Solar Energy Vs Solar Power

The terms solar power and solar energy are used interchangeably, however the terms have different definitions. Solar Energy is utilizing the radiant energy from the Sun. Solar Power is the conversion of sunlight into electricity, either by photovoltaics and concentrating solar thermal devices, or the utilization of thermoelectric converters, solar chimneys or solar ponds. (some of the latter are experimental) When we consider building design, solar energy (and shading) are considerations. In order to conserve heat that the Sun delivers, thermal mass is used.

Optimization of the light in buildings is called a 'Daylighting' technique. Solar water heaters are used in many applications including swimming pools and domestic hot water. Farmers use greenhouses to lengthen the growing seasons, as well as pumps that derive power from solar cells (photovoltaics) in order to move water for grazing animals. In order to harvest salt, as well as clean waste streams, evaporation ponds are used. In order to increase the supply of potable (drinking, cooking etc.) water, solar distillation and disinfection methods provide water for a great many people around the world. There are many simple uses for this renewable energy and the prospect for a great deal more.

Consider solar chimneys or solar towers, this technology is experimental, however if we lobby our elected officials we can get them to fund these options and they can be up and running in a very short time. These solar updraft towers (solar chimneys or towers) consist of large greenhouses that funnel into a central tower. Sunlight then shines on the greenhouse, and the inside air is heated and it expands. The expanding air flows into the central tower, where a turbine converts the air flow into electricity. This technology is not difficult to put into use, it will simply cost money. Sadly, it won't cost a lot of money but it is more than our elected officials have earmarked for renewable energy. The number of new jobs that pursuing this technology would create would offset the cost and put a lot of unemployed people back to work.

There are even ways of harnessing solar power from space. Space solar power systems would use a solar array in geosynchronous orbit to collect the sunlight and then it would beam this energy as microwaves to receivers set up on Earth for distribution. Once again this concept is still experimental, however it could deliver power close to 100% of the time. We simply have to pursue this concept and get it to a workable point.

The story is, now we have to get serious about the alternatives, as there will soon be no choice. We are destroying our environment, natural habitats are polluted to the point that some creatures are approaching extinction. Take a look at frogs, many species are already extinct and this is no small matter. We depend on these amphibians to eat insects from swamps that are dangerous to humans. Soon we will face threats from diseases right here in the U.S., like malaria that we had long forgotten. We have to embrace renewable, alternative energy now. Fossil fuels are destroying us, both financially and physically. Global warming, rampant pollution and the depletion of those fossil fuels will bring about our demise if we don't act now.

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What is a Stirling Engine and How Does it Work?

Model Stirling engines are fascinating and fun to build...but they can be difficult to understand. If you're interested in model Stirling engines but aren't sure exactly what they are (or why they're so great), this article will answer some of your questions.

The Stirling engine is named for its inventor, Robert Stirling. It is a closed-cycle regenerative heat engine. It works by cyclically compressing and expanding air or other gas (known as the working fluid) at different temperature levels. The heat energy produced makes the engine run.

A Stirling engine is an external combustion engine, like a steam engine. This means that all of the engine's heat goes in and out through the wall of the engine, from an external heat source. But unlike a steam engine, which uses water in both liquid and gas form, Stirling engines use only the gas forms of liquids such as hydrogen, helium or oxygen. This working fluid is compressed, heated, expanded, and then cooled again in an ongoing cycle.

Stirling engines contain a fixed amount of working fluid. The engine is sealed, so none of the gas leaves the engine, and none enters from outside. When you have a fixed amount of gas in a fixed amount of space, raising the temperature of the gas will increase its pressure. If you compress the gas, its temperature will go up.

The gas is moved back and forth between hot and cold heat exchangers. To put it simply, a basic Stirling engine works like this:

1. A hot heat exchanger (a heated cylinder) is exposed to an external heat source, which then heats the gas in that cylinder and causes the pressure of the gas to increase. This increased pressure makes the piston in the heated cylinder move down and do work.

2. The piston on the other side moves up as the other moves down, and this then pushes the heated gas into the cold heat exchanger, or cold cylinder. The cold cylinder is cooled by the ambient temperature of the surrounding environment or by an external source of cold. As the gas cools, its pressure is lowered and it becomes easier to compress.

3. The piston in the cold cylinder then moves down and compresses the cooled gas. Any heat generated by the compression is removed by the cooling source (known as the heat sink).

4. The piston in the heating cylinder moves up, and gas is forced back in to the heated cylinder. As it heats up the pressure increases, the piston moves down, and the cycle repeats over and over.

Usually a regenerator is placed in between the heated area and the cooling area. This acts as a heat store and increases the engines efficiency by retaining and recycling the heat that passes through the engine, rather than allowing it to diminish.

This is a basic overview of how Stirling engines work. There are many different types and models, but they all work according to the same theory. Model Stirling engines can be very simple, or more complex...but as long as you have a heat source, a hot air and a cool air exchanger and a heat sink and of course, all the parts, they will work.

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Steam Electricity

I live in an off-grid cottage and my biggest energy expense is for propane, which I use for space heating in winter. Because my farm has more firewood than I can possibly use, I’m planning to install a wood-fired, water-heating stove to eliminate the need for propane. I would like to find a way to convert wood to electrical energy as a backup, so I don’t need to rent a generator and can run electricity to other dwellings and buildings on the farm.

I know this technology was around long ago, because steam locomotives used it to generate electricity for their running lights. Only 100 to 150 psi of steam was needed. A small boiler/turbo generator could be installed for backup or full-time power as needed, with no dependency on outside energy sources.

Are there any companies that make small boiler turbo generators (5–20 kW) that could be run on wood?

You’ll likely be out of luck trying to buy a commercial, home-scale steam turbine generator that burns wood, for two very good reasons—safety and practicality.

Water expands to 1,700 times its original volume when heated to steam, and each gallon of water in a boiler carries the potential energy of a stick of dynamite! Boilers for steam turbines and steam engines must be monitored constantly, especially when burning fuels like wood where the energy density varies from one chunk to the next. Even a 10-minute trip to the fridge for a soda and sandwich is too long to leave a woodfired steam system unattended.

We have a wood-burning steam engine here at our off-grid shop, spinning a 2 kW alternator, but it’s there for fun, not to depend on for backup electricity. Someone has to monitor, stoke, and water the boiler all day long, thus getting little work done in the shop, making steam backup power impractical for us. Steam power is fascinating, though, and there are many science-fair-sized steam turbine models on Internet video sites, or you could join a steam-engine enthusiasts club for help in restoring an antique or building your own.

There are other options besides steam for making electricity from wood, but all are complicated and expensive do-it-yourself projects at the 5 to 20 kW scale you want:

• Stirling cycle engine: These heat-powered machines are quite safe, but very pricey. Plans for machining and building your own are available, but few actual products larger than toy model fans for your wood heater exist. Plus, they have a reputation for early failure.

• Thermoelectric cells: Also common in wood heater fans, these use the Peltier- Seebeck effect to make DC power directly from heat. Modules of 25 to 100 watts are very expensive, and past products have suffered reliability problems from overheating.

• Wood gasification: This technology uses heat and chemical reactions to break down wood into flammable gases for burning in a standard internal combustion engine. Tens of thousands of vehicles were retrofitted with gasifiers in Europe and Asia during 1940s wartime gasoline shortages. You can buy a parts kit today to build your own, and plans abound. However, wood gas is not a “hit the switch and forget it” sort of fuel, and deadly carbon monoxide is one of the gases it produces and burns. You can’t just throw logs into your gasifier; charcoal, sawdust, or very small chunks of wood are required. Gasification is a very advanced do-it-yourself project, but is probably your best bet if you choose to continue your quest.

Making electricity with firewood is a difficult way to go, and requires lots of time, money, advanced skills, and imperturbable enthusiasm. If I had a huge surplus of wood as you describe, I’d harvest sustainably, sell the extra wood, and invest the proceeds in greater energy efficiency for my home and more solar-electric modules for my roof. - source

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Hard Water Treatment Methods

Hard water treatment methods are grouped into four categories depending on how they work. They all reduce, inhibit or eliminate limescale and each method has its own advantages and disadvantages. Below is a synopsis of how each of the four categories work, what they do, how they do it, and their advantages and disadvantages.

1) Physical Water Conditioners

Physical Water Conditioners, so called because they physically alter the properties of hard water to reduce or eliminate limescale formation, come in three different types - electronic, electrolytic and magnetic.

1a) Electronic water conditioners, also know as electronic descalers or limescale inhibitors, generally comprise of a small box of electronics and one or more coils wrapped around the pipework.

What they do: Electronic conditioners work by transmitting an audio frequency or radio frequency signal into the water via induction coils wrapped around the pipework. This inhibits the build up of limescale inside water pipes and through time, reduces existing scale. A softer scale may still form on shower heads, taps and other surfaces, but is much easier to clean.

Advantages: Electronic descalers are relatively cheap in comparison with other hard water treatment methods and offer a cost effective solution to limescale problems. No plumbing is required, making them very easy to install. And because nothing is removed or added to the water, healthy minerals are retained and the water remains safe to drink.

Disadvantages: Although sometimes not as effective as other treatment methods, most manufacturers offer a full money back guarantee if the device does not work as well as expected.

1b) Electrolytic water conditioners are inline devices that need to be plumbed into the water system. They can be bought with 15mm, 22mm, or 28mm end connectors to suit the pipework.

What they do: Inside an electrolytic conditioner are two dissimilar metals, normally copper and zinc, which act as a cathode and an anode. The electrolytic current that flows from the cathode to the anode causes small quantities of metal ions to dissolve into the water. The metal ions then disrupt the positively charged scale forming particles so that they don't clump together and form scale.

Advantages: Like electronic descalers, electrolytic scale inhibitors are relatively cheap to buy. They do not need an electric power supply and so annual running costs are zero. They provide whole house protection against limescale problems and treated water is safe to drink.

Disadvantages: Electrolytic water conditioners need to be periodically replaced to maintain the full level of protection and, unlike electronic conditioners, they need to be plumbed into the pipework, adding to the initial cost.

1c) Magnet water conditioners come in two forms. They either clamp onto the outside of the pipework or are fitted inline with the pipework in the same way as electrolytic softeners.

What they do: Magnetic conditioners work in a similar way to electronic conditioners, but use a magnetic field rather than an electric field to alter the characteristics of the scale producing minerals in the water. Scale particles in the treated water lose their ability to adhere to one another and to pipes, boilers and other internal surfaces.

Advantages: Magnetic conditioners are fairly popular due to their relatively low cost. The clamping type is easy to fit and normally just needs tightening onto the pipework with a spanner. They do not need any electrical power and so running costs are zero.

Disadvantages: Magnetic conditioners are generally not suitable for whole house protection, only single appliances. Some magnetic conditioners need to be plumbed into the pipework and they all have to be replaced periodically to maintain full performance.

2) Chemical Water Conditioners

Chemical water conditioners fall into two categories, packaged softeners and dosing systems. Packaged softeners can be further split into precipitating and non-precipitating types. The principal use of packaged softeners is to soften water for washing clothes

2a) Precipitating packaged softeners include washing soda and borax. Although borax has a number of uses around the home, the main purpose of packaged softeners is for washing clothes and as such they are not suitable for whole house water softening and treated water is not fit to drink.

What they do: Precipitating softeners soften the water by combining with calcium and magnesium ions found in hard water. This causes the mineral ions to precipitate out, so that they don't interfere with the washing process.

Advantages: Cheap, easy to use softener that, in addition to softening, also cleans and deodorises. Adding borax or washing soda to the wash, will also prevent limescale build-up in the washing machine.

Disadvantages: Precipitating softeners make the water cloudy and can cling to materials in the wash. They also increase the alkalinity of the water, which can damage skin and some fabrics.

2b) Non-precipitating softeners include products such as calgon and more commonly used than precipitating softeners. Like all packaged softeners, they are only intended for use in the laundry.

What they do: They work by using phosphates, which react with the calcium and magnesium ions in hard water and holds them in solution.

Advantages: As the name suggests, non-precipitating softeners do not form a precipitate and so the water remains clear. They do not increase the alkalinity of the water and so they're safe to use with all fabrics.

Disadvantages: Generally more expensive than precipitating softeners and not so eco friendly because of their high phosphate content.

2c) Phosphate dosing systems comprise of a cartridge of phosphate held in a container that is fitted to the plumbing system. Water passing through the cartridge is dosed with small quantities of phosphate which softens the water.

What they do: Like non-precipitating softeners, they work by adding phosphates to the water. However, in dosing systems, food grade polyphosphates are used. The polyphosphates act as a sequester to stop the hardness minerals in hard water from precipitating out.

Advantages: Dosing systems typically cost in the region of £60 to buy, plus installation costs. Although generally only used for single appliance protection, they can provide whole house treatment.

Disadvantages: Most people prefer not to have phosphates in their drinking water, even if they are food grade safe. Replacement cartridges incur additional annual running costs of between £30 and £60.

3) Mechanical Water Softeners

Mechanical Water Softeners, or ion exchange softeners as they are also know, are true water softeners. Physical and chemical conditioners, although sometimes referred to as 'softeners', do not remove hardness minerals from the water; they merely prevent them from precipitating out or from sticking to surfaces. The only true way to soften hard water is to remove the calcium and magnesium minerals that make it hard. Only ion exchange softeners, and some filter treatment methods, do this.

What they do: Ion exchange softeners work by swapping negative hardness ions in hard water with positive sodium atoms in a resin contained within the softener. Periodically, the resin needs to be regenerated to remove the build up of hardness minerals. This is done by flushing the resin with brine. During the regeneration process, household water is diverted around the softener and so only hard water is available. This is normally set to occur during the night. Alternatively, two resin tanks can be used, with one regenerating while the other is in service.

Advantages: Ion exchange softeners offer all the advantages of truly soft water for the whole house.

Disadvantages: The main drawbacks with ion exchange softeners are that they're expensive to buy, costly to run and can take up quite a bit of room (normally on the kitchen). A further drawback is that treated water contains sodium (salt). That said, they produce truly soft water and issues with sodium in the water can be resolved by leaving one outlet in the house untreated.

4) Water Filters

Water filters come in many shapes and guises from stand-alone jugs to fully integrated reverse osmosis units. The three most common types found in UK homes that will remove calcium and magnesium from hard water are carbon resin filters, reverse osmosis units and water distillers. There are many other types of filter available, but they do not produce soft water.

Since filtered water is normally only available from a single outlet, water filters do not alleviate hard water problems throughout the rest of the home. Limescale deposits will still exist through the plumbing and heating system and on taps, showerheads and other surfaces.

4a) Carbon resin filters are normally used in conjunction with activated carbon filters. The carbon resin removes hardness minerals from the water and the activate carbon filter then filters out chemicals.

What they do: Carbon resin filters use an ion exchange resin to remove hardness minerals from the water in a similar manner to mechanical water softeners. An activated carbon filter then removes chlorine and other chemicals to improve the taste and eliminate odours.

Advantages: Pleasant tasting, cheap, chlorine free, soft water.

Disadvantages: Unlike mechanical water softeners, the ion exchange resin is not regenerated and builds up contaminants until it needs to be replaced. The charcoal filter also needs periodic replacement and like all filter systems, they do not offer a practical solution to limescale problems elsewhere in the house.

4b) Reverse osmosis systems are perhaps the most popular type of filter for household water treatment. Whilst RO systems will remove calcium and magnesium ions from hard water, they are not normally installed purely for this purpose. Many homes with soft water have RO systems. Most home owners buy reverse osmosis systems to obtain cleaner, purer, water than is normally available from their water supplier.

What they do: Reverse osmosis filters work by forcing water through a semi-permeable membrane which filters out impurities. The membrane has microscopic holes through which water molecules can pass, but larger particles and molecules (like the hardness minerals) are blocked.

Advantages: In addition to effectively removing most contaminants, RO treated water tastes better, enhances the flavour of drinks like coffee, tea and fruit squashes. And in hard water areas, household appliances such as steam irons, coffee makers and kettles, will not suffer from the normal scaling.

Disadvantages: The main drawback with reverse osmosis units is that they use lots of water. Typical RO filter units purify only ten percent of the water that enters the system; the rest is piped to waste. This makes them unsuitable for whole house water treatment. Additionally, filter cartridges and the RO membrane require periodic cleaning / replacement (sometimes by a professional). Hard water also reduces the life of the RO membrane. With filter replacements typically costing between £150 and £700, they can also be expensive to maintain.

4c) Water distillers produce the purest water possible. Appliance for the home look like large kettles, while larger under-counter units are available for commercial premises and dental surgeries.

What they do: Distillers work by boiling water into steam, which then condenses back into water and is collected in a storage container. Impurities in the water are not converted into steam and so only pure water condenses into the storage container. Contaminants are left behind in the boiling chamber, which can then be cleaned with special crystals.

Advantages: Distillers offer the purest water money can buy. They have all the benefits of reverse osmosis filters plus a few others. The water they produce is purer than bottled water, always on tap and there are no heave bottles to carry back from the supermarket.

Disadvantages: Distillation is not practical or economically viable for whole house water treatment, so limescale will still build up in pipes, boilers and heat exchangers as well as on taps, shower heads and other surfaces.

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