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� <br />� <br />� <br />� <br />l� <br />� <br />r <br />� <br />� <br />i� <br />1# <br />� t� <br />1� <br />i� <br />1� <br />7� <br />17 <br />�� <br />�� <br />Roseville Skating Center anci City Hall <br />Feasibility Study September 23, 2007 <br />integrated system adds significant amounts of thermal energy to the system that can be <br />transferred to other campus buildings. <br />The integration of the two refrigeration systems in the campus buildings with ftte heating, <br />ventilation, air conditioning and water heating systems in the buildings is accomplished <br />by connecting the mechanical equipment to a common, fluid based system that can <br />store thermal energy. <br />In practical terms this is accomplished by making two basic changes to the mechanical <br />heating, cooling and refrigeration systems in the buildings. <br />The first change is to convert or replace refrigeration and air conditioning systems that <br />reject thermal energy to the outdoor air (via cooling towers and air cooled condensers), <br />to a fluid based system connected to a GHX that is designed �a store thermal energy in <br />the ground around the buildings. <br />The second change is to replace gas burning appliances (gas boilers, roof-mounted gas <br />furnaces, gas water heaters, etc.) to fluid based equipment designed to extract thermal <br />energy from a GHX buried in the ground around the buildings. <br />2� <br />�7 By connecting equipment that provides heating, cooling and refrigeration that often <br />�� operates simultaneously, to a common GHX, it is possible to transfer energy easily and <br />23 efficiently from one building to another. And since the ground can store large amounts of <br />�� thermal energy by simply increasing in temperature a few degrees, or release large <br />�� amounts of energy by cooling a few degrees, temporary energy imbalances are easily <br />�� addressed. <br />�7 <br />�� The GHX operates much like a bank account. When there is excess thermal energy that <br />�� is not required immediately it can be deposited into a thermal energy savings account. <br />3� When heating is needed in a building and no thermal energy is available from the <br />31 refrigeration systems, it is possible to dip into the energy savings account. <br />�� <br />33 �.�. Thermal Energy ��e��'�g�: ��°�a�a�d h9��� ���9������ (GHX� <br />3� <br />�� <br />�C� <br />37 <br />�� <br />3� <br />�� <br />—�t <br />�!� <br />�� <br />� <br />�� <br />A� <br />�� <br />�� <br />The earth has an enormous capacity to store low grade thermal energy. This is <br />accomplished simply by burying a heat exchanger in the earth around the buildings on <br />the campus. A heat exchanger can be built by burying high-density polyethylene (HDPE) <br />pipe in the ground. HDPE pipe can be buried either in a horizontal trench at a depth of 5' <br />to $', or in vertical boreholes drilled to a depth of 150' to 400'. <br />The ambient ground temperature in Minneapolis is approximately A�7°�. When more <br />thermal energy is removed from the ice surFace in the �ce Arena than can be used in the <br />Ice Arena / Banquet Hali, the refrigeration system can be designed to warm fluid that is <br />circulated through the GHX. When the fluid is warmer than the surrounding ground <br />temperature, heat is dissipated to the ground, while the fluid is cooled by the 47°� earth. <br />As more thermal energy is dissipatedto the GHX, the ground graduallywarms creating a <br />large mass of warm ground. <br />Gecs-�ergy Systems Page 14 of 33 <br />