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Inhabitat May 8, 2007 iSAVE Water-Saving Faucets by Jorge Whether you live in a drought-plagued region or you’re just trying to be efficient, there are a myriad reasons to conserve water. That’s why we love the iSAVE faucet by Reamon Yu- a design so clever and efficient that it was recently chosen as a runner-up in the Metropolis Magazine Next Generation awards. The gadget easily attaches to your sink or showerhead to provide a digital readout of the amount of water that was being used in a shower. What’s more, iSAVE is powered by energy generated by the water passing through it using a small turbine embedded the device.

Only Looks Like a Tempest when You're in the Teapot > Bad news: > Greywater reuse offers much more benefits than are realized > in most systems. > Good news: > Even the worst shortfalls in greywater design rarely cause > actual harm, and for the few that do, it's not much. > For every hundred greywater users in the US, probably 15 are achieving most > of the benefit they should, eighty-some could do better, and a few systems have > overall negative net benefit. > Of these, most have an overbuilt system—the problem is that the ecological > cost of the pumps and pipe are greater than the saved water. > Perhaps one greywater user in a thousand is discharging diaper greywater directly > to a water way, which is about the only way you can create a significant health > hazard. Almost all such systems date from a time when the ecosystem was much > bigger and the human imprint much smaller. > There has not been one documented case of greywater transmitted illness > in the US. > In our area, we have curbside recycling of mixed recyclables as well as trash > pick up. > I've observed that well-meaning citizens put plenty of stuff which looks vaguely > recyclable but is not in their recycling bins (e.g., polystyrene packing), as > well as totally recyclable materials in in a form which is impractical to recycle, > like thousands of bits of loose paper, broken glass, and specs of plastic. At > the sorting facility, they send this sort of stuff to the landfill. > For some households, the percentage of their recyclables which are actually > recycled is as low as 20%, though it could be 95% with good information. This > does not mean recycling is dangerous or illegal. > This is a totally different kind of "failure" than, say, burning > PVC in the backyard (which forms clouds of carcinogenic dioxin). These folks > just need to know what they're doing wrong, and how to do it better. > The aim of this web page is to share with greywater users and regulators > what they're doing wrong. The aim of our > greywater > books > is to detail how to do it better. > Please bear in mind as you read the exhaustive litany of "problems" > that even the most pathetically misguided attempts at greywater reuse still > wind up showing some net benefit relative to the alternatives. > Here's an overview of the failure of greywater reuse to achieve more of the > benefit which it easily could: > Most new complex grey water reuse systems are > abandoned, most simple ones achieve less than 10% irrigation efficiency within > five years. > If grey water treatment systems were built according > to overdone legal requirements, many would consume so much energy and materials > to save so little water that the Earth would be better off if the water were > just wasted instead. > Claims made for packaged grey water filtration > systems are often inflated. Some are very expensive and many don't work. > Some also have the preceding problem. > The majority of successful grey water recycling > systems are so simple and inexpensive they are beneath recognition by regulators, > manufacturers, consultants, and salespeople. > A web search on "grey water" "greywater" > "gray water" or "graywater" will yield hundreds examples > of the errors below. Many are designs from the early 70's, reprinted on the > web as cutting edge, despite having been discredited in the field for twenty > years. >

On-Site Reuse of Concrete From Demolition Projects for New Construction Projects– Rich Jones, John Gottleib, Richard Scheidet, and Peter D. Pohlot During 2006, Brookhaven National Laboratory (BNL) demolished 10 buildings/structures while constructing 2 new facilities (the Research Support Building and the Center for Functional Nanomaterials). This paper details how the concrete from the demolition projects was re-used as part of the new construction projects at a significant cost savings to the Laboratory. BNL has an authorization from the New York Department of Environmental Conservation to operate what’s known as the “Borrow Pit”. The Borrow Pit is an area where sand was mined for a Laboratory project, leaving a large void space in the firebreak area south of the Laboratory. The authorization allows BNL to fill the void space with Construction & Demolition (C&D) debris. Approximately 4-years ago when the Borrow Pit was close to capacity, a decision was made to bring in a concrete crusher and mine the Pit to generate Recycled Concrete Aggregate (RCA) to be used around the Laboratory’s firebreak road system to stabilize the roadways and as new road base for new parking areas and roads. Prior to this, the Laboratory purchased virgin crushed blue stone to stabilize the firebreaks. During 2006, numerous older structures (pre-1950) were demolished due to issues such as advanced stages of deterioration, energy inefficiency, and repairs not being cost effective. The following table details the buildings that were demolished and the respective amounts of material (in tons) that were recycled (concrete and metals) and the remains that were sent off-site to a C&D management facility (i.e., roofing shingles, lumber, siding, etc…) Building Concrete Metals C&D 86 300 3 260 326 5 0 18 400 parking lot 2000 0 0 422 80 0 160 445 2600 2 12 527 0 0 150 707/707A 220 20 0 707B 32 0 0 715 6 0 6 753 12 0 12 750 CT & Tank Storage 250 10 0 Totals (tons) 5505 35 618 These demolition projects generated over 5500 tons concrete, which was crushed at the Borrow Pit and recycled as RCA (see Figures 1 and 2). The majority of this RCA (approximately 4800 tons) was used as the predominant base for the parking lots of the two new construction projects – the Research Support Building and the Center for Page 2 Functional Nanomaterials (see Figures 3 and 4). The remainder was used for position: absolu