Town of Milton Shoreland Protection Project

Mettee Planning Consultants (MPC) worked with the Milton Conservation Commission to evaluate and streamline the town’s water resource protection regulations. One of the outcomes was revision and passage of a Shoreland Protection Overlay District as part of the town’s zoning ordinance

Emergency Notification System

This document contains the impact structures, breach area, and location of high hazard dams within the City of Austin.Waller Creek Working Grou

The evaluation of national accounting matrices with environmental accounts (NAMEA) as a methodology for carrying out a sustainability assessment of the Scottish food and drink sector

This report introduces environmental input-output (IO) accounts for Scotland as an example of a NAMEA framework. It provides an introduction to the use of basic IO multiplier methodology, which can be applied to examine pollution/waste generation and/or resource use under production and consumption accounting principles

(2008) Wellhead Protection Program - Lary Lane, Gilman, and Stadium Wells in the Town of Exeter, NH

A Wellhead Protection Program (WHPP) identifies existing and potential sources of contamination to public water supply wells. The purpose of a WHPP is to prevent contamination of groundwater used for drinking water, recognizing the best way to maintain high quality drinking water is to prevent contaminants from reach drinking water sources. The Federal Safe Drinking Water Act requires states to develop Wellhead Protection Programs. New Hampshire’s Groundwater Protection Act, NH RSA 485-C, provides the basis for protection in New Hampshire. The Town of Exeter, New Hampshire has developed this WHPP for three wells, the Lary Lane well, the Gilman well, and the Stadium well. Funding for the development of this WHPP was provided by the New Hampshire Estuaries Project. The Plan was written by the Rockingham Planning Commission (RPC) with assistance from the Town of Exeter’s Department of Public Works and the Water and Sewer Advisory Committee. The RPC gratefully acknowledges the information provided by Brian Goetz of Weston & Sampson. The water supply for the Town of Exeter is a combination of surface and groundwater. The Exeter River is the principal supply source for the Town’s municipal water system. Water from the River is diverted to the Town’s water treatment plant through the pumping station located on the east side of the Exeter River, near the Phillips Exeter Academy football stadium. During the winter months, water is taken from the Exeter Reservoir adjacent to Portsmouth Avenue because ice build-up prevents intake from the Exeter River. The water stored in the Reservoir comes from the Exeter River, Dearborn Brook and Skinner Springs. Groundwater from the Lary Lane well is also used to meet an average water system daily demand of 1.1 million gallons. The Gilman well and Stadium well are not active at this time. The Town of Exeter purchased the water system from the Exeter Water Works Company in 1950. Until the renovation of the water treatment plant in 1974, the Town relied on groundwater to supply the municipal system. The Town is revisiting the option of using groundwater supplies in conjunction with the surface water supply to provide the town with a more diversified system. Included in this investigation is a review of current land use surrounding three existing wells located in Town, the Lary Lane well, Gilman well, and Stadium well

Eyewear protection

Sports-related eye injuries increased more than 100% in the last three years. More significant is the fact thai nearly 90% could have been prevented had the athletes been wearing protective eyewear. A key to getting athletes to wear proper and protective eyewear is education. Educating not only the athletes, but coaches, parents and others involved in athletic activities is of paramount importance by the sports practitioner, because an eye injury can be very serious and have permanent consequences

Electroshock protection circuit

Circuit was developed to prevent accidental shock through electrodes used to test subjects as part of Skylab program. This circuit is placed between electrical apparatus and electrode that is attached to patient's body. Thus, patient is effectively protected from dangerous electrical shock that might be caused by failure in electrical apparatus

Protection for Sale or Surge Protection?

This paper asks whether the results obtained from using the standard approach to testing the influential Grossman and Helpman "protection for sale" (PFS) model of political economy might arise from a simpler setting. A model of imports and quotas with protection occuring in response to import surges, but only for organized industries, is simulated and shown to provide parameter estimates consistent with the protection for sale framework. This suggests that the standard approach may be less of a test than previously thought.Common agency, Political economy, Protection for sale, Quotas, Non tariff barriers

A dynamic modelling environment for the evaluation of wide area protection systems

This paper introduces the concept of dynamic modelling for wide area and adaptive power system protection. Although not limited to these types of protection schemes, these were chosen due to their potential role in solving a multitude of protection challenges facing future power systems. The dynamic modelling will be implemented using a bespoke simulation environment. This tool allows for a fully integrated testing methodology which enables the validation of protection solutions prior to their operational deployment. Furthermore the paper suggests a distributed protection architecture, which when applied to existing and future protection schemes, has the potential to enhance their functionality and avoid mal-operation given that safety and reliability of power systems are paramount. This architecture also provides a means to better understand the underlying dynamics of the aforementioned protection schemes and will be rigorously validated using the modelling environment