Changes

The HVAC system uses a blend of loosely coupled systems to provide maximum energy efficiency and redundancy for a year-round live-aboard. Fresh-air ventilation uses small zone-based air vents but this makes humidity control difficult. The heating and cooling systems use a shared circulating-water distribution system to minimise bulkhead pass-throughs. Heating is by a diesel furnace with backup from a diesel fireplace. Cooling is by a chiller with keel cooler, with backup from the cold-plate refrigeration system. Hot water is heated by the engine, the diesel oven, a [https://en.wikipedia.org/wiki/Solar_thermal_collector solar collector ] or AC elements using shore power or the house bank.

Use an anti-scald, balanced-pressure shower valve (not a tempering valve!) on the showers to regulate the water to 120 Fahrenheit (F°F) 48.8 Celsius (C°C). This will avoid scalding people, and reduce water consumption. Bathers will be able to mix the water faster to a comfortable temperature.

For heating, ventilation and air-conditioning distribution and control purposes, the boat is divided into the zones in the below table. With a K=1(see [[HeatingCalculation|Heating Calculation)]], the boat requires approx. 37,810 BTU/h of heating. The main diesel furnace supplies this, sufficient for the coldest weather.

But what happens in an emergency? In the event the furnace fails, the Bristol Pacific model diesel stove in the galley can provide 6,500-16,250 BTU to heat the forward accommodation. At the lower heat setting it could maintain a temperature differential of 21 C°C, while the higher one maintains the design differential requirement of 55 C °C in the forward compartment.

At the lower setting, water pipes, etc., are protected down to -20 C°C, a not infrequent winter temperature, which is why the design requirement is the higher 55 C °C differential. Because the galley stove alone cannot heat the whole boat in the event of a furnace failure, additional heat has to be supplied by the diesel fireplace in the salon. A fireplace such as the Bubble produces only 3.5 kW (11,946 BTU), good for a 17 C °C differential overall. So it will only heat the pilothouse and salon, not the aft cabin.

== Air Conditioning Calculation Related Pages ==A water-based chiller provides air conditioning. The chiller circulates chilled water through a water distribution system to the cabins, to cool them in summer. All pipes should be insulated to prevent condensation. (Similarly, if you opt for forced air, the ducts should be insulated.)

[[VentilationCalculation|Calculating air conditioning is more complex and so the answers are more varied. The next table gives three sets of estimates to illustrate the issue.Ventilation Requirements]]

Column A gives a series of BTU values derived from the buyenergyefficient.org web site <ref>http://buyenergyefficient.org/</ref>. Column B is based on an expert rule of thumb of 14 BTU per cubic foot, plus an extra 1000 BTU for good measure. Column C uses the spreadsheet calculator.  Except for the last two data points, methods A and C are in good agreement, but make your own judgement. This spreadsheet calculator is adapted from Air Conditioning Your Home <ref>http://www.nrcan.gc.ca/energy/publications/efficiency/residential/air-conditioning/6051</ref>, published by the Energy Office of Natural Resources Canada (NRCAN) and available from its web site. It appears to fall within the general range of the other methods, based on area alone. Most rules of thumb are designed for single rooms, or two rooms joined. The author's calculator considers numerous more factors:  * Number of occupants * Area of each accommodation * Area of windows and degree of sun exposure * Energy efficiency of windows * Shading of windows * Degree of insulation in the boat * Heat gain through the engine room bulkhead * Heat gain from AC machinery in the accommodation * Heat gain from DC machinery in the accommodationHeat gain from DC lights in the accommodation Several approximations were made in adapting the NRCAN model. For example, houses have a fixed position, allowing us to calibrate the different heat gain from windows facing any compass quadrant. Boats are mobile, allowing windows to face any direction at any time. The calculator assumes the worse case, with one full side of the boat having maximum southern sun exposure, the other minimum, i.e., it is moored east-to-west. The degree of insulation is set with the K factor in the heating calculation. The factor for heat gain through engine room bulkheads is a pure guess. The heat gain from AC and DC equipment is factored at 3.4 - 4.3, while NRCAN suggests 3.0 for AC appliances in a house. <table width="80%" border="1"> <tr> <th colspan="4">Recommended Cooling Capacity (BTU/h)</th></tr> <tr> <th rowspan="2">Area (ft²)</th> <th colspan="3">Method (ft)</th></tr><tr> <th>A<ref>http://www.energyefficient.org/</ref></th> <th>B<ref>Expert rule of thumb</ref><br>14 BTU/ft²</th> <th>C<ref>Provided [[#spreadsheetAirConditioningCalculation|Calculating Air Conditioning Requirements]]</ref><br>Calculator (K=0.7)</th></tr> <tr> <td>100 – 150</td> <td> 5,000</td> <td> 3,100</td> <td> 3,465</td></tr> <tr> <td>150 - 250</td> <td> 6,000</td> <td> 4,500</td> <td> 5,775</td></tr> <tr> <td>250 - 300</td> <td> 7,000</td> <td> 5,200</td> <td> 6,930</td></tr><tr> <td>300 - 350</td> <td> 8,000</td> <td> 5,900</td> <td> 8,085</td></tr><tr> <td>350 - 400</td> <td> 9,000</td> <td> 6,600</td> <td> 9,200</td></tr><tr> <td>400 - 450</td> <td> 10,000</td> <td> 7,300</td> <td> 10,395</td></tr><tr> <td>450 - 550</td> <td> 12,000</td> <td> 8,700</td> <td> 12,705</td></tr><tr> <td>550 - 700</td> <td>14,000</td> <td> 10,800</td> <td> 16,170</td></tr><tr> <td>700 - 1,000</td> <td> 18,000</td> <td> 15,000</td> <td> 23,100</td></tr></table>