What size furnace do I need for a 1200 square foot house? Most 1,200-square-foot homes needs a furnace with an effective output of 40,000 to 50,000 BTUs. The effective BTU output, which is based on its efficiency rating, is a percentage of the BTU input rating. For example, a 50,000-BTU furnace with an efficiency rating of 80 percent provides a 40,000-BTU output. How do you choose the right size boiler for a house? How many BTUs do you need to heat your house? Factors such as construction type, building date, quality of insulation, quality of windows and doors, and the number and size of rooms are used to determine the exact size of furnace required for any home. The most effective method for choosing the right furnace is to obtain furnace estimates from local, licensed contractors. There are also free and paid software programs and websites that provide furnace size estimators. How big of a furnace do I need for my house? The size of furnace needed for a home depends on the size of the home or the geographic location of the home.

The needed BTUs are calculated based on the h... How many BTUs per square foot are needed when sizing a home furnace? The BTU of a home furnace should typically average between 40 to 45 BTU pre square foot, though this average applies only to homes located in cooler climat... Where can you buy an 80,000 BTU furnace? Furnaces with 80,000 British thermal units (BTUs) are available at major retailers, such as Home Depot and Sears. They are also available at online vendors... Where can you buy a Janitrol furnace? How do you find house rentals in Laguna Beach? Where can you get a DeLonghi space heater? What size is the sun? How do you change a corner fireplace? Where can you buy used gas heaters?Whether they're for journeymen, master electricians, or contractors, most electrical licensing exams require you to calculate residential loads and service or feeders sizes using one of two methods. The standard method, which is contained in Art. 220, Part II, involves more steps, but many people use it exclusively to avoid using the wrong method.

However, most residential construction qualifies for the optional method in Art. 220, Part III, so it's prudent to understand both methods. In either case, you're free to exceed the NEC requirements — these are minimum requirements, not design specifications. The standard method is where we'll start. It requires six sets of calculations for general lighting and receptacles, small-appliance, and laundry; air conditioning versus heat; The following example should help illustrate how to apply these steps. What size service conductor does a 1,500 sq ft dwelling unit need, if it contains the following loads? The service is 120/240V. Disposal (940VA) Dishwasher (1,250VA) Trash compactor (1,100VA) Water heater (4,500VA) Dryer (4,000VA) Cooktop (6,000VA) Two ovens (each 3,000VA) Air conditioning (5 hp, 230V) Three electric space heating units (each 3,000W) General lighting and receptacles, small-appliance, and laundry. The NEC recognizes these circuits won't all be on (loaded) simultaneously.

Thus, you may apply a demand factor to the total connected general lighting and receptacle load (220.16). To determine the service/feeder demand load, refer to Table 220.11 and follow these steps: First, determine the total connected load for general lighting and receptacles (3VA per sq ft) [Table 220.3(A)], two small-appliance circuits each at 1,500VA, and one laundry circuit at 1,500VA (220.16) (Fig. 1). ac units for warehouseSecond, apply Table 220.11 demand factors to the total connected general lighting and receptacle load. air conditioner window unit inventedCalculate the first 3,000VA at 100% demand and the remaining VA at 35% demand. new coil ac unitGeneral lighting/receptacles: 1,500 sq ft× 3VA=4,500VA Small-appliance circuits: 1,500VA×2 =3,000VA Laundry circuit: 1,500VA×1= 1,500VA Total connected load: 4,500VA+ 3,000VA+1,500VA=9,000VA First 3,000VA at 100%=3,000VA× 1.00=3,000VA Remainder at 35%=(9,000VA- 3,000VA)×0.35=2,100VA Total demand load=5,100VA Air-conditioning versus heat.

Because air-conditioning and heating loads aren't on simultaneously, you may omit the smaller of the two loads (220.21). Calculate each of these at 100% (220.15) (Fig. 2). Air conditioning: 5 hp, 230V VA=E×I (Table 430.148) 28 FL×230V=6,440 VA Heat: 3,000W×3 units=9,000W The air conditioning load is smaller than the heat load, therefore it can be omitted. Per 220.17, you can use a 75% demand factor when four or more “fastened in place” appliances, such as a dishwasher or waste disposal, are on the same feeder. Don't include clothes dryers, cooking equipment, air conditioning, or heat in this category (Fig. 3). Waste disposal: 940VA Dishwasher: 1,250VA Trash compactor: 1,100VA Water heater: 4,500VA Total connected appliance load: 7,790VA× 0.75=5,843VA Clothes dryer. Per 220.18, the feeder or service demand load for electric clothes dryers in a dwelling unit shall not be less than 5,000W. However, if the nameplate rating exceeds 5,000W, use that rating as the load. You can omit this calculation if the unit has no electric dryer provision.

However, it's common to provide both gas and electric sources. If you see gas on the plans, verify electric will be omitted (Fig. 4). The service and feeder demand load for a 4kW dryer is 5,000W. For household-cooking appliances rated higher than 1.75kW, you can use the demand factors listed in 220.19, Table and Notes 1, 2, and 3. All three of the units in the example are rated higher than 1.75kW and not higher than 8.75kW, so follow the instructions in Note 3. The two ovens are rated less than 3.5kW, so Table 220.19 Column A demand factor applies. The cooktop is 6kW, so Column B demand factor applies (Fig. 5). Column A demand: 3kW×2 units× 0.75 demand factor=4.5kW Column B demand: 6kW×1 unit× 0.8=4.8kW Demand load=4.5kW+4.8kW= 9.3kW=9,300W Feeder and service conductor size. 400A and less: For 3-wire, 120/240V, single-phase systems, size the feeder or service conductors according to Table 310.15(B)(6). For all others, use Table 310.16. Size the grounded (neutral) conductor to the maximum unbalanced load (220.22) per Table 310.16.

Over 400A: Size the ungrounded and grounded (neutral) conductors per Table 310.16. Now we can total up the demand loads from steps 1 through 5. Step 1: 5,100VA Step 2: 9,000VA Step 3: 5,843VA Step 4: 5,000VA Step 5: 9,300W Step 6: 34,243VA total demand load To determine the amperes need for the service use the formula: I5VA÷E. I=34,243VA÷240V=143A We can use 310.15(B)(6) for a 120/240V single-phase dwelling service and feeder up to 400A. This Table allows a smaller conductor size than Table 310.16. A 143A demand load means this house requires at least a 150A service with 1 AWG conductors. You can use the easier optional method found in 220.30 only when the total connected load is served by a single 3-wire, 120/240V or 208Y/120V set of service or feeder conductors with an ampacity of 100A or greater. Because this condition describes the typical residential service, the optional method is likely to apply. Using it can simplify the design process and save you time because you have so many fewer sets of calculations.

The calculated load shall not be less than 100% for the first 10kW, plus 40% of the remainder of the following loads: Small-appliance and laundry branch circuits: 1,500VA for each 20A circuit. General lighting and receptacles: 3VA per sq ft Appliances: The nameplate VA rating of all appliances and motors fastened in place (permanently connected) or on a specific circuit. Be sure to use the range and dryer at nameplate rating. Include the largest of the following: 100% of the nameplate rating of the air-conditioning equipment. 100% of the heat-pump compressors and supplemental heating, unless the controller prevents simultaneous operation of the compressor and supplemental heating. 100% of the nameplate ratings of electric thermal storage and other heating systems where you expect the usual load to be continuous at the full nameplate value. Don't configure such systems under any other selection in this table. 65% of the nameplate rating(s) of the central electric space heating, including integral supplemental heating in heat pumps where the controller prevents simultaneous operation of the compressor and supplemental heating.

65% of the nameplate rating(s) of electric space heating, if there are less than four separately controlled units. 40% of the nameplate rating(s) of electric space heating of four or more separately controlled units. Now that we've seen how to determine residential loads, let's size the service/feeder conductors. We'll use the same specifications that we used for the standard method so we can compare apples to apples. Step 1: Determine general loads [230.30(B)]. Small appliance: 1,500VA×2 circuits = 3,000VA General lighting: 1,500 sq ft×3VA= 4,500VA Laundry circuit=1,500VA Now add up the appliance ratings. The total connected load=32,790VA Calculate the first 10,000VA at 100%=10,000VA× 1.00=10,000VA Calculate the remainder at 40%= 22,790VA×0.40= 9,116VA Demand load=10,000VA+9,116VA= 19,116VA Step 2: Compare air conditioner at 100% vs. heat at 65% [220.30(C)]. Air conditioner: 230V×28A=6,440VA Heat [220.30(C)(5)]: 9,000 W×0.65 = 5,850 W (omit) Step 3: Calculate service/feeder conductors per 310.15(B)(6).