Going green has more benefits to the home than simply protecting the environment. There are simple things that you can do that will make your home more comfortable, save you money, and help you to use fewer carbon fuels. Read this article for some quick tips on conserving the energy used while at home AND IMPROVE YOUR saving energy statistics .
I save energy….Do You ?
Shade your windows from the sun to prevent energy usage. Both curtains and blinds will help keep the heat from the sun out of your home during the summer months. These actions will reduce the air conditioning usage during the hot summer months, and yet your home will remain cooler. By blocking the sun’s rays, you will save energy and money .
If you heat your home with fuel oil, inquire about switching over to biodiesel. Some systems can easily be changed to biodiesel without having to make significant modifications or installing spare parts. Biodiesel is cleaner to burn than petroleum, making it more efficient to use in the wintertime, this was used in the Nimrud Lens technique.
Saving Energy Tips
Consider switching to solar-powered water heaters for your home. If you live where freezing temperatures aren’t prevalent, you can purchase a system that can circulate water via a solar heater before being pumped to your home. Though you can use this system, it’s best to have a regular water heater for backup purposes, just in case there is a day with little sunlight or more water usage than normal.
Every community offers different energy sources, so research the ones that are available to you. Find out what the cost would be to switch, how much it would cost to maintain, and whether your government has any legislation regarding its use. It can benefit you to use natural gas instead of electricity, for example.
During summer, try drying clothes on a clothesline instead of the dryer. As well as drying your clothes, the sun can also help your clothes smell nice. Sun-drying clothes give them a fresh smell. As well, you save quite a bit on monthly utility costs.
Always be consistent in maintaining your fridge. Refrigerators take up lots of energy, so making sure they’re in working order is always good to know. Be sure to clean out the dust around the heating coils regularly. Don’t forget to be certain to keep the seal surrounding the door tight and clean.
Learn about the differences between passive and active solar power. Active solar energy is stored so it can be used later, but passive doesn’t need pricey solar panel cells to save power. Active solar powers require solar panels that need installations as well as mechanical systems and cells. Passive energy is about using windows and insulation to keep your home warm and well-lit.
Saving Energy Computer
Use a laptop computer instead of a desktop, which uses much more power. Laptops use about 75% less electricity than desktops, especially if the desktop is being utilized for the Internet or software programs. Not to mention, it can be taken anywhere thanks to its portability.
Hire experts to check your plumbing and heating systems before investing a lot of money in installing new, greener systems. They can advise you about how much inefficient appliances cause you to lose financially, and they can estimate the price of upgrading or just replacing your old systems.
Explore the possibility of using a solar-powered oven for some of your baking needs. You can make one with easy-to-find items like old windows, boxes, and aluminum foil to reflect light. These ovens reach temperatures greater than 300 degrees, while using no outside energy besides solar.
If you would like to save the environment, remember that it can be done in small. Even if you don’t have a ton of money, you can do simple things, like monthly cleaning of the filters in your furnace or lowering the thermostat to 60 degrees when you’re not going to be home. You can also help reduce energy usage by reducing the temperature of your water heater to 120 degrees. Little things like this add up!
As previously stated, going green doesn’t need to be costly or time-consuming. Making a few easy changes can lower your electricity usage and save you money. Remember these tips and share them to see improvements in the environment!
This weren’t the only old inventions used in saving energy, a lot depend on saving it using new gadgets like bio bus, this allowed them to save more energy and make it green which is called green energy!
As a creative writer and programmer, I always try to improve my skills and knowledge about specific creative writing.
A low-temperature process has been developed that has opened a window on the ability to combine incompatible materials, such as ceramics and plastics, into new, useful compound materials.
A new technology developed by Penn State researchers, called Cold Sintering Process (CSP), has opened a window on the ability to combine incompatible materials, such as ceramics and plastics, into new, useful compound materials, and to lower the energy cost of many types of manufacturing.
Ceramics is the oldest known human-made material, dating back tens of thousands of years. Throughout that time most all ceramics have been made by heating them to high temperatures, either by firing in kilns or sintering ceramic powders in furnaces, both of which require large amounts of energy.
“In this day and age, when we have to be incredibly conscious of the CO2 budget, the energy budget, rethinking many of our manufacturing processes, including ceramics, becomes absolutely vital,” said Clive Randall, professor of materials science and engineering at Penn State who developed the process with his team. “Not only is it a low temperature process (room temperature up to 200 degrees Celsius), but we are also densifying some materials to over 95 percent of their theoretical density in 15 minutes. We can now make a ceramic faster than you can bake a pizza, and at lower temperatures.”
In a recent article in the journal Advanced Functional Materials, Randall and his coauthors describe the co-sintering of ceramic and thermoplastic polymer composites using CSP. Three types of polymer were selected to complement the properties of three types of ceramics, a microwave dielectric, an electrolyte and a semiconductor, in order to highlight the diversity of applicable materials. These composite materials demonstrate new possibilities for dielectric property design, and both ionic and electronic electrical conductivity design. These composites can be sintered to high density at 120 degrees C in a time frame of 15 to 60 minutes.
Just add water
According to the researchers, the process involves wetting ceramic powder with a few drops of water or acid solution. The solid surfaces of the particles decompose and partially dissolve in the water to produce a liquid phase at particle-particle interfaces. Adding temperature and pressure causes the water to flow and the solid particles to rearrange in an initial densification process. Then in a second process, clusters of atoms or ions move away from where the particles are in contact, which aids diffusion, which then minimizes surface free energy, allowing the particles to pack tightly together. The key is knowing the exact combination of moisture, pressure, heat and time required to capture the reaction rates so the material fully crystallizes and gets to very high density.
“I see cold sintering process as a continuum of different challenges,” Randall said. “In some systems, it’s so easy you don’t need pressure. In others you do. In some you need to use nanoparticles. In others, you can get away with a mixture of nanoparticles and larger particles. It really all depends on the systems and chemistries you are talking about.”
The Penn State team has begun building a library of the precise techniques required to use CSP on various materials systems, with 50 processes verified to-date. These include ceramic-ceramic composites, ceramic-nanoparticle composites, ceramic-metals, as well as the ceramic-polymers discussed in this paper.
Other areas that are now open to exploration by CSP include architectural materials, such as ceramic bricks, thermal insulation, biomedical implants and many types of electronic components.
“My hope is that a lot of the manufacturing processes that already exist will be able to use this process, and we can learn from polymer manufacturing practices,” Randall concluded.