A nice feature of the Sawyer system is the benefit of using the same filter as a water treatment bottle, inline on a hydration pack, as an ultra light drink straw and attached to a faucet with the included faucet adaptor. If purchased with the faucet adaptor kit, it can be configured to drink straight from the tap during boil alerts or in areas of natural disasters such as floods, hurricanes, and earthquakes. The kit also provides hydration pack assembly kit for installing the inline filter on a hydration pack.
Photo by marcos ojedaPrepackaged meals are the perfect camping food – lightweight, convenient, and easy to prepare. While many prepackaged meals are commercially available, you can save money, get the types of meals you want, and have fun by making your own. Fill a small freezer bag with ½ cup quick-cooking oats, a tablespoon of dry milk, a teaspoon of sugar, and a handful of dried fruit and nuts for a nutritious breakfast. For lunch, try a third of a cup of dry couscous, ½ cup freeze dried vegetables, a tablespoon of shelf stable shredded Parmesan cheese, a teaspoon of vegetable bullion and a few seasonings. How about rice with beef and mushrooms for dinner? And let’s not forget about desert; how does a mixed up fruit cobbler sound?
One of the first steps in most conventional water purification processes is the addition of chemicals to assist in the removal of particles suspended in water. Particles can be inorganic such as clay and silt or organic such as algae, bacteria, viruses, protozoa and natural organic matter. Inorganic and organic particles contribute to the turbidity and color of water.
A solar-powered desalination unit produces potable water from saline water by using a photovoltaic system that converts solar power into the required energy for reverse osmosis. Due to the extensive availability of sunlight across different geographies, solar-powered reverse osmosis lends itself well to drinking water purification in remote settings lacking an electricity grid. Moreover, Solar energy overcomes the usually high-energy operating costs as well as greenhouse emissions of conventional reverse osmosis systems, making it a sustainable freshwater solution compatible to developing contexts. For example, a solar-powered desalination unit designed for remote communities has been successfully tested in the Northern Territory of Australia.
These tablets essentially use chlorination as their method of purification. Sodium chlorite generate chlorine dioxide giving it the ability to treat water. Chlorination, as most know, is a common method of disinfecting water, and is commonly used by municipalities world-wide for this purpose. Chlorine destroys bacteria by destroying the cell walls of the bacterium/virus, killing the organism. Fortunately, when we drink chlorinated water, our digestive system quickly neutralizes the chlorine. So chlorine concentrations along the gastrointestinal tract are, in all likelihood, too low to cause damage. The tablets are wrapped in a metallic foil which makes it easy to store and there are no concerns of a glass bottle breaking. This is one of our favorite items to carry as a backup to our water filtration system.
In 1904, Allen Hazen showed that the efficiency of a sedimentation process was a function of the particle settling velocity, the flow through the tank and the surface area of tank. Sedimentation tanks are typically designed within a range of overflow rates of 0.5 to 1.0 gallons per minute per square foot (or 1.25 to 2.5 litres per square meter per hour). In general, sedimentation basin efficiency is not a function of detention time or depth of the basin. Although, basin depth must be sufficient so that water currents do not disturb the sludge and settled particle interactions are promoted. As particle concentrations in the settled water increase near the sludge surface on the bottom of the tank, settling velocities can increase due to collisions and agglomeration of particles. Typical detention times for sedimentation vary from 1.5 to 4 hours and basin depths vary from 10 to 15 feet (3 to 4.5 meters).:9.39–9.40:790–1:140–2, 171