Regulations Compliance Report

Transcription

1 Regulations Compliance Report Approved Document L1A 21 edition assessed by Stroma FSAP 29 program, Version: Printed on 17 February 213 at 2:25:45 Project Information: Assessed By: Behdad Yazdani (STRO2254) Building Type: Detached House Dwelling Details: NEW DWELLING AS BUILT Site Reference : House 1 Plot Reference: 38, Salcott Road Address : Client Details: Name: Address : House A, 38, Salcott Road, LONDON, SW11 6DE This report covers items included within the SAP calculations. It is not a complete report of regulations compliance. 1 TER and DER Fuel for main heating system: Electricity Fuel factor: 1.14 x 1.47 (electricity) Target Carbon Dioxide Emission Rate (TER) kg/m² Dwelling Carbon Dioxide Emission Rate (DER) kg/m² OK 2 Fabric U-values Element Average Highest External wall.2 (max..3).2 (max..7) OK Floor.17 (max..25).17 (max..7) OK Roof.11 (max..2).11 (max..35) OK Openings 1.32 (max. 2.) 1.6 (max. 3.3) OK 3 Air permeability Air permeability at 5 pascals 5. Maximum 1. OK 4 Heating efficiency Main Heating system: Heat pumps with radiators or underfloor - electric Daikin Altherma ERHQ6BV3 + EKHBH8B Secondary heating system: None 5 Cylinder insulation Hot water Storage: Nominal cylinder loss: 1.6 kwh/day Permitted by DBSCG: 1.89 kwh/day Primary pipework insulated: Yes OK 6 Controls Space heating controls Time and temperature zone control OK Hot water controls: Cylinderstat OK Independent timer for DHW OK Yes OK 7 Low energy lights Percentage of fixed lights with low-energy fittings 1.% Minimum 75.% OK Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 2

2 Regulations Compliance Report 8 Mechanical ventilation Not applicable 9 Summertime temperature Overheating risk (Thames valley): Medium OK Based on: Overshading: Average or unknown Windows facing: East 8.53m², Overhang twice as wide as window, ratio NaN Windows facing: West 8.92m², Overhang twice as wide as window, ratio NaN Windows facing: North.39m², Overhang twice as wide as window, ratio NaN Windows facing: South 4.69m², Overhang twice as wide as window, ratio NaN Roof windows facing: West 1.6m² Ventilation rate: 2.5 Blinds/curtains: None shutter closed 1% of daylight hours 1 Key features Windows U-value Doors U-value Roofs U-value Floors U-value 1.3 W/m²K 1.3 W/m²K.11 W/m²K.17 W/m²K Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 2

3 SAP Input Property Details: House 1 Address: House A, 38, Salcott Road, LONDON, SW11 6DE Located in: England Region: Thames valley UPRN: Date of assessment: 25 January 213 Date of certificate: 17 February 213 Assessment type: New dwelling as built Transaction type: New dwelling Tenure type: Unknown Related party disclosure: No related party Thermal Mass Parameter: Indicative Value Medium Dwelling designed to use less than 125 litres per Person per day: True Property description: Dwelling type: House Detachment: Detached Year Completed: 213 Floor Location: Floor area: Storey height: Floor 59.6 m² 2.4 m Floor m² 2.71 m Living area: m² (fraction.28) Front of dwelling faces: East Opening types: Name: Source: Type: Glazing: Argon: Frame: FRONT DOOR Manufacturer Half glazed low-e, En =.5, soft coat Yes PVC-U EAST Manufacturer Windows low-e, En =.5, soft coat Yes PVC-U WEST Manufacturer Windows low-e, En =.5, soft coat Yes PVC-U NORTH Manufacturer Windows low-e, En =.5, soft coat Yes PVC-U SOUTH Manufacturer Windows low-e, En =.5, soft coat Yes PVC-U ROOF Manufacturer Roof Windows low-e, En =.5, soft coat Yes PVC-U Name: Gap: Frame Factor: g-value: U-value: Area: No. of Openings: FRONT DOOR 16mm or more mm EAST 16mm or more WEST 16mm or more NORTH 16mm or more SOUTH 16mm or more ROOF 16mm or more Name: Type-Name: Location: Orient: Width: Height: FRONT DOOR WALL East EAST WALL East WEST WALL West NORTH WALL North SOUTH WALL South ROOF ROOF West Overshading: Opaque Elements: Average or unknown Type: Gross area: Openings: Net area: U-value: Ru value: Curtain wall: Kappa: External Elements WALL False N/A ROOF N/A Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 3

4 SAP Input FLOOR N/A Internal Elements Party Elements Thermal bridges: Thermal bridges: User-defined y-value y =.4 Reference: ACCREDIATED Ventilation: Pressure test: Ventilation: Number of chimneys: Number of open flues: Number of fans: 3 Yes (As built) Natural ventilation (extract fans) Number of sides sheltered: 2 Pressure test: 5 (Assessed dwelling is tested) Main heating system: Main heating system: Main heating Control: Main heating Control: Secondary heating system: Secondary heating system: Water heating: Water heating: Others: Central heating systems with radiators or underfloor heating Heat pumps Fuel: Electricity Info Source: Boiler Database Database: (rev 334, product index 111, SEDBUK 361%): Brand name: Daikin Altherma Model: ERHQ6BV3 + EKHBH8B Model qualifier: (provides DHW all year) Underfloor heating and radiators, pipes in insulated timber floor Pump in heat space: No Time and temperature zone control Control code: 227 Boiler interlock: Yes None Electricity tariff: 7-hour tariff In Smoke Control Area: Yes Conservatory: No conservatory Low energy lights: 1% Terrain type: Dense urban EPC language: English Wind turbine: No From main heating system Water code: 91 Fuel :Electricity Hot water cylinder Cylinder volume: 15 litres Cylinder insulation: Measured loss, 1.6kWh/day Primary pipework insulation: True Cylinderstat: True Cylinder in heated space: True Solar panel: False Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 3

5 SAP Input Photovoltaics: Assess Zero Carbon Home: None No Stroma FSAP 29 Version: (SAP 9.9) - Page 3 of 3

6 SAP WorkSheet: New dwelling as built User Details: Assessor Name: Behdad Yazdani Stroma Number: STRO2254 Software Name: Stroma FSAP 29 Software Version: Version: Property Address: House 1 Address : House A, 38, Salcott Road, LONDON, SW11 6DE 1. Overall dwelling dimensions: Area(m²) Ave Height(m) Volume(m³) Ground floor (1a) x (2a) = (3a) First floor (1b) x (2b) = (3b) Total floor area TFA = (1a)+(1b)+(1c)+(1d)+(1e)+...(1n) (4) Dwelling volume (3a)+(3b)+(3c)+(3d)+(3e)+...(3n) = (5) Ventilation rate: main Secondary other total m³ per hour heating heating Number of chimneys + + = x 4 = (6a) Number of open flues + + = x 2 = (6b) Number of intermittent fans x 1 = (7a) 3 3 Number of passive vents x 1 = (7b) Number of flueless gas fires x 4 = (7c) Air changes per hour Infiltration due to chimneys, flues and fans = (6a)+(6b)+(7a)+(7b)+(7c) = 3 (5) =.11 (8) If a pressurisation test has been carried out or is intended, proceed to (17), otherwise continue from (9) to (16) Number of storeys in the dwelling (ns) (9) Additional infiltration [(9)-1]x.1 = (1) Structural infiltration:.25 for steel or timber frame or.35 for masonry construction (11) if both types of wall are present, use the value corresponding to the greater wall area (after deducting areas of openings); if equal user.35 If suspended wooden floor, enter.2 (unsealed) or.1 (sealed), else enter (12) If no draught lobby, enter.5, else enter (13) Percentage of windows and doors draught stripped (14) Window infiltration.25 - [.2 x (14) 1] = (15) Infiltration rate (8) + (1) + (11) + (12) + (13) + (15) = (16) Air permeability value, q5, expressed in cubic metres per hour per square metre of envelope area (17) 5 If based on air permeability value, then (18) = [(17) 2]+(8), otherwise (18) = (16) (18).36 Air permeability value applies if a pressurisation test has been done or a degree air permeability is being used Number of sides on which sheltered 2 (19) Shelter factor (2) = 1 - [.75 x (19)] =.85 (2) Infiltration rate incorporating shelter factor (21) = (18) x (2) = (21).31 Infiltration rate modified for monthly wind speed Monthly average wind speed from Table 7 (22)m= Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 9

7 SAP WorkSheet: New dwelling as built Wind Factor (22a)m = (22)m 4 (22a)m= Adjusted infiltration rate (allowing for shelter and wind speed) = (21a) x (22a)m Calculate effective air change rate for the applicable case If mechanical ventilation: If exhaust air heat pump using Appendix N, (23b) = (23a) Fmv (equation (N5)), otherwise (23b) = (23a) If balanced with heat recovery: efficiency in % allowing for in-use factor (from Table 4h) = a) If balanced mechanical ventilation with heat recovery (MVHR) (24a)m = (22b)m + (23b) [1 (23c) 1] (24a)m= b) If balanced mechanical ventilation without heat recovery (MV) (24b)m = (22b)m + (23b) (24b)m= c) If whole house extract ventilation or positive input ventilation from outside if (22b)m <.5 (23b), then (24c) = (23b); otherwise (24c) = (22b) m +.5 (23b) (24c)m= d) If natural ventilation or whole house positive input ventilation from loft if (22b)m = 1, then (24d)m = (22b)m otherwise (24d)m =.5 + [(22b)m² x.5] (24d)m= Effective air change rate - enter (24a) or (24b) or (24c) or (24d) in box (25) (25)m= (23a) (23b) (23c) (24a) (24b) (24c) (24d) (25) 3. Heat losses and heat loss parameter: ELEMENT Gross Openings Net Area U-value A X U k-value A X k area (m²) m² A,m² W/m2K (W/K) kj/m² K kj/k Doors 2.1 x 1.3 = 2.73 (26) Windows Type x 1/[1/( 1.3 )+.4] = 1.54 (27) Windows Type x 1/[1/( 1.3 )+.4] = 11.2 (27) Windows Type 3.39 x 1/[1/( 1.3 )+.4] =.48 (27) Windows Type x 1/[1/( 1.3 )+.4] = 5.8 (27) Rooflights 1.6 x 1/[1/(1.6) +.4] = 2.56 (27b) Floor 59.6 x.17 = 1.42 (28) Walls x.2 = (29) Roof x.11 = 6.32 (3) Total area of elements, m² (31) * for windows and roof windows, use effective window U-value calculated using formula 1/[(1/U-value)+.4] as given in paragraph 3.2 ** include the areas on both sides of internal walls and partitions Fabric heat loss, W/K = S (A x U) (26) (3) + (32) = (33) Heat capacity Cm = S(A x k ) ((28) (3) + (32) + (32a) (32e) = (34) Thermal mass parameter (TMP = Cm TFA) in kj/m²k Indicative Value: Medium 25 (35) For design assessments where the details of the construction are not known precisely the indicative values of TMP in Table 1f can be used instead of a detailed calculation. Thermal bridges : S (L x Y) calculated using Appendix K (36) Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 9

8 SAP WorkSheet: New dwelling as built if details of thermal bridging are not known (36) =.15 x (31) Total fabric heat loss (33) + (36) = (37) Ventilation heat loss calculated monthly (38)m =.33 (25)m x (5) (38)m= (38) Heat transfer coefficient, W/K (39)m = (37) + (38)m (39)m= Heat loss parameter (HLP), W/m²K (4)m = (39)m (4) Average = Sum(39) 1 12 /12= (39) (4)m= Number of days in month (Table 1a) Average = Sum(4) 1 12 /12= 1.33 (4) (41)m= (41) 4. Water heating energy requirement: kwh/year: Assumed occupancy, N 2.78 (42) if TFA > 13.9, N = x [1 - exp(-.349 x (TFA -13.9)2)] +.13 x (TFA -13.9) if TFA 13.9, N = 1 Annual average hot water usage in litres per day Vd,average = (25 x N) (43) Reduce the annual average hot water usage by 5% if the dwelling is designed to achieve a water use target of not more that 125 litres per person per day (all water use, hot and cold) Hot water usage in litres per day for each month Vd,m = factor from Table 1c x (43) (44)m= Total = Sum(44) 1 12 = (44) Energy content of hot water used - calculated monthly = 4.19 x Vd,m x nm x DTm / 36 kwh/month (see Tables 1b, 1c, 1d) (45)m= If instantaneous water heating at point of use (no hot water storage), enter in boxes (46) to (61) Total = Sum(45) 1 12 = (45) (46)m= (46) Water storage loss: a) If manufacturer s declared loss factor is known (kwh/day): (47) 1.6 Temperature factor from Table 2b (48).54 Energy lost from water storage, kwh/year (47) x (48) =.86 (49) If manufacturer s declared cylinder loss factor is not known: Cylinder volume (litres) including any solar storage within same (5) If community heating and no tank in dwelling, enter 11 litres in box (5) Otherwise if no stored hot water (this includes instantaneous combi boilers) enter '' in box (5) Hot water storage loss factor from Table 2 (kwh/litre/day) (51) Volume factor from Table 2a (52) Temperature factor from Table 2b (53) Energy lost from water storage, kwh/year ((5) x (51) x (52) x (53) = (54) Enter (49) or (54) in (55).86 (55) Water storage loss calculated for each month ((56)m = (55) (41)m (56)m= (56) Stroma FSAP 29 Version: (SAP 9.9) - Page 3 of 9

9 SAP WorkSheet: New dwelling as built If cylinder contains dedicated solar storage, (57)m = (56)m x [(5) (H11)] (5), else (57)m = (56)m where (H11) is from Appendix H (57)m= (57) Primary circuit loss (annual) from Table 3 36 (58) Primary circuit loss calculated for each month (59)m = (58) 365 (41)m (modified by factor from Table H5 if there is solar water heating and a cylinder thermostat) (59)m= (59) Combi loss calculated for each month (61)m = (6) 365 (41)m (61)m= (61) Total heat required for water heating calculated for each month (62)m =.85 (45)m + (46)m + (57)m + (59)m + (61)m (62)m= (62) Solar DHW input calculated using Appendix G or Appendix H (negative quantity) (enter '' if no solar contribution to water heating) (add additional lines if FGHRS and/or WWHRS applies, see Appendix G) (63)m= (63) Output from water heater (64)m= Output immersion Output from water heater (annual) (64) (64)m= Output from immersion (annual) (64) Heat gains from water heating, kwh/month.25 [.85 (45)m + (61)m] +.8 x [(46)m + (57)m + (59)m ] (65)m= (65) include (57)m in calculation of (65)m only if cylinder is in the dwelling or hot water is from community heating 5. Internal gains (see Table 5 and 5a): Metabolic gains (Table 5), Watts (66)m= (66) Lighting gains (calculated in Appendix L, equation L9 or L9a), also see Table 5 (67)m= (67) Appliances gains (calculated in Appendix L, equation L13 or L13a), also see Table 5 (68)m= (68) Cooking gains (calculated in Appendix L, equation L15 or L15a), also see Table 5 (69)m= (69) Pumps and fans gains (Table 5a) (7)m= (7) Losses e.g. evaporation (negative values) (Table 5) (71)m= (71) Water heating gains (Table 5) (72)m= (72) Total internal gains = (66)m + (67)m + (68)m + (69)m + (7)m + (71)m + (72)m (73)m= (73) 6. Solar gains: Solar gains are calculated using solar flux from Table 6a and associated equations to convert to the applicable orientation. Stroma FSAP 29 Version: (SAP 9.9) - Page 4 of 9

10 SAP WorkSheet: New dwelling as built Orientation: Access Factor Area Flux g_ FF Gains Table 6d m² Table 6a Table 6b Table 6c (W) North.9x.77 x.39 x 1.73 x.63 x.7 = 1.28 (74) North.9x.77 x.39 x 2.36 x.63 x.7 = 2.43 (74) North.9x.77 x.39 x x.63 x.7 = 3.97 (74) North.9x.77 x.39 x x.63 x.7 = 6.51 (74) North.9x.77 x.39 x x.63 x.7 = 8.96 (74) North.9x.77 x.39 x 84.9 x.63 x.7 = 1.2 (74) North.9x.77 x.39 x x.63 x.7 = 9.43 (74) North.9x.77 x.39 x x.63 x.7 = 7.34 (74) North.9x.77 x.39 x 41.9 x.63 x.7 = 4.9 (74) North.9x.77 x.39 x x.63 x.7 = 2.96 (74) North.9x.77 x.39 x x.63 x.7 = 1.58 (74) North.9x.77 x.39 x 8.94 x.63 x.7 = 1.7 (74) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = 1.41 (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x 98.3 x.63 x.7 = (76) East.9x 1 x 8.53 x 73.6 x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x 18.9 x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x 56.7 x.63 x.7 = 8.37 (78) South.9x.77 x 4.69 x 4.89 x.63 x.7 = (78) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = 15 (8) West.9x.77 x 8.92 x x.63 x.7 = (8) Stroma FSAP 29 Version: (SAP 9.9) - Page 5 of 9

11 SAP WorkSheet: New dwelling as built West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = 37.7 (8) West.9x.77 x 8.92 x 98.3 x.63 x.7 = (8) West.9x.77 x 8.92 x 73.6 x.63 x.7 = 2.65 (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) Rooflights.9x 1 x 1.6 x 26 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 54 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 94 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 15 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 19 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 21 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 194 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 164 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 116 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 68 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 33 x.63 x.7 = 2.96 (82) Rooflights.9x 1 x 1.6 x 21 x.63 x.7 = (82) Solar gains in watts, calculated for each month (83)m = Sum(74)m (82)m (83)m= (83) Total gains internal and solar (84)m = (73)m + (83)m, watts (84)m= (84) 7. Mean internal temperature (heating season) Temperature during heating periods in the living area from Table 9, Th1 ( C) 21 Utilisation factor for gains for living area, h1,m (see Table 9a) (86)m= Mean internal temperature in living area T1 (follow steps 3 to 7 in Table 9c) (87)m= Temperature during heating periods in rest of dwelling from Table 9, Th2 ( C) (88)m= Utilisation factor for gains for rest of dwelling, h2,m (see Table 9a) (89)m= Mean internal temperature in the rest of dwelling T2 (follow steps 3 to 7 in Table 9c) (9)m= (85) (86) (87) (88) (89) (9) fla = Living area (4) = (91).28 Mean internal temperature (for the whole dwelling) = fla T1 + (1 fla) T2 (92)m= (92) Stroma FSAP 29 Version: (SAP 9.9) - Page 6 of 9

12 SAP WorkSheet: New dwelling as built Apply adjustment to the mean internal temperature from Table 4e, where appropriate (93)m= Space heating requirement Set Ti to the mean internal temperature obtained at step 11 of Table 9b, so that Ti,m=(76)m and re-calculate the utilisation factor for gains using Table 9a Utilisation factor for gains, hm: (94)m= Useful gains, hmgm, W = (94)m x (84)m (95)m= Monthly average external temperature from Table 8 (96)m= Heat loss rate for mean internal temperature, Lm, W =[(39)m x [(93)m (96)m ] (97)m= (93) (94) (95) (96) (97) Space heating requirement for each month, kwh/month =.24 x [(97)m (95)m] x (41)m (98)m= Total per year (kwh/year) = Sum(98) 1...5, = (98) Space heating requirement in kwh/m²/year (99) 9a. Energy requirements Individual heating systems including micro-chp) Space heating: Fraction of space heat from secondary/supplementary system (21) Fraction of space heat from main system(s) (22) = 1 (21) = 1 (22) Fraction of total heating from main system 1 (24) = (22) [1 (23)] = 1 (24) Efficiency of main space heating system (26) Efficiency of secondary/supplementary heating system, % (28) kwh/year Space heating requirement (calculated above) (211)m = {[(98)m x (24)] + (21)m } x 1 (26) (211) Space heating fuel (secondary), kwh/month = {[(98)m x (21)] + (214) m } x 1 (28) Total (kwh/year) =Sum(211) = 1...5, (211) (215)m= Water heating Output from water heater (calculated above) Total (kwh/year) =Sum(215) = 1...5,1. 12 (215) Efficiency of water heater (216) (217)m= (217) Fuel for water heating, kwh/month (219)m = (64)m x 1 (217)m (219)m= Water heating requirement (immersion) Total = Sum(219a) = (219) Efficiency Stroma FSAP of 29 water Version: heater (Immersion) (SAP 9.9) - 1Page 7 of (216) 9

13 SAP WorkSheet: New dwelling as built (217)m= (217) Fuel for water heating (Immersion), kwh/month (219)m = [ (64)m + (218) m ] x 1 (217)m (219)m= Total = Sum(219a) = (219) Annual totals kwh/year kwh/year Space heating fuel used, main system Water heating fuel used Water heating fuel used (Immersion) Electricity for pumps, fans and electric keep-hot Total electricity for the above, kwh/year sum of (23a) (23g) = (231) Electricity for lighting (232) 1a. Fuel costs - individual heating systems: Fuel Fuel Price Fuel Cost kwh/year (Table 12) /year Space heating - main system 1 (211) x x.1 = (24) Space heating - main system 2 (213) x x.1 = (241) Space heating - secondary (215) x x.1 = (242) Water heating (electric off-peak tariff) High-rate fraction (Table 13, or Appendix F for electric CPSU).7 (243) Low-rate fraction 1. (243) = (244).3 High-rate cost (219) x (243) x x.1 = (245) Low-rate cost (219) x (244) x x.1 = (246) Water heating cost (Immersion) (219) x.1 = (247) Pumps, fans and electric keep-hot (231) x.1 = (249) (if off-peak tariff, list each of (23a) to (23g) separately as applicable and apply fuel price according to Table 12a Energy for lighting (232) x.1 = (25) Additional standing charges (Table 12) (251) 27 Appendix Q items: repeat lines (253) and (254) as needed Total energy cost (245)...(247) + (25) (254) = (255) 11a. SAP rating - individual heating systems Energy cost deflator (Table 12) (256).47 Energy cost factor (ECF) [(255) x (256)] [(4) + 45.] = (257) 1.3 SAP rating (Section 12) 12a. CO2 emissions Individual heating systems including micro-chp 81.9 (258) Energy Emission factor Emissions kwh/year kg CO2/kWh kg CO2/year Space heating (main system 1) (211) x = (261) Stroma FSAP 29 Version: (SAP 9.9) - Page 8 of 9

14 SAP WorkSheet: New dwelling as built Space heating (secondary) (215) x = (263) Water heating (219) x = (264) Water heating (Immersion) (219) x = (264) Space and water heating (261) + (262) + (263) + (264) = (265) Electricity for pumps, fans and electric keep-hot (231) x = (267).517 Electricity for lighting (232) x = (268) Total CO2, kg/year sum of (265) (271) = (272) CO2 emissions per m² (272) (4) = (273) EI rating (section 14) (274) 84 13a. Primary Energy Energy Primary P. Energy kwh/year factor kwh/year Space heating (main system 1) (211) x = (261) Space heating (secondary) (215) x = (263) Energy for water heating (219) x = (264) Energy for water heating (Immersion) (219) x = (264) Space and water heating (261) + (262) + (263) + (264) = (265) Electricity for pumps, fans and electric keep-hot (231) x = (267) 2.92 Electricity for lighting (232) x = (268) Total Primary Energy sum of (265) (271) = (272) Primary energy kwh/m²/year (272) (4) = (273) Stroma FSAP 29 Version: (SAP 9.9) - Page 9 of 9

15 Fabric Efficiency WorkSheet: New dwelling as built User Details: Assessor Name: Behdad Yazdani Stroma Number: STRO2254 Software Name: Stroma FSAP 29 Software Version: Version: Property Address: House 1 Address : House A, 38, Salcott Road, LONDON, SW11 6DE 1. Overall dwelling dimensions: Area(m²) Ave Height(m) Volume(m³) Ground floor (1a) x (2a) = (3a) First floor (1b) x (2b) = (3b) Total floor area TFA = (1a)+(1b)+(1c)+(1d)+(1e)+...(1n) (4) Dwelling volume (3a)+(3b)+(3c)+(3d)+(3e)+...(3n) = (5) Ventilation rate: main Secondary other total m³ per hour heating heating Number of chimneys + + = x 4 = (6a) Number of open flues + + = x 2 = (6b) Number of intermittent fans x 1 = (7a) 4 4 Number of passive vents x 1 = (7b) Number of flueless gas fires x 4 = (7c) Air changes per hour Infiltration due to chimneys, flues and fans = (6a)+(6b)+(7a)+(7b)+(7c) = 4 (5) =.15 (8) If a pressurisation test has been carried out or is intended, proceed to (17), otherwise continue from (9) to (16) Number of storeys in the dwelling (ns) (9) Additional infiltration [(9)-1]x.1 = (1) Structural infiltration:.25 for steel or timber frame or.35 for masonry construction (11) if both types of wall are present, use the value corresponding to the greater wall area (after deducting areas of openings); if equal user.35 If suspended wooden floor, enter.2 (unsealed) or.1 (sealed), else enter (12) If no draught lobby, enter.5, else enter (13) Percentage of windows and doors draught stripped (14) Window infiltration.25 - [.2 x (14) 1] = (15) Infiltration rate (8) + (1) + (11) + (12) + (13) + (15) = (16) Air permeability value, q5, expressed in cubic metres per hour per square metre of envelope area (17) 5 If based on air permeability value, then (18) = [(17) 2]+(8), otherwise (18) = (16) (18).4 Air permeability value applies if a pressurisation test has been done or a degree air permeability is being used Number of sides on which sheltered 2 (19) Shelter factor (2) = 1 - [.75 x (19)] =.85 (2) Infiltration rate incorporating shelter factor (21) = (18) x (2) = (21).34 Infiltration rate modified for monthly wind speed Monthly average wind speed from Table 7 (22)m= Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 7

16 Fabric Efficiency WorkSheet: New dwelling as built Wind Factor (22a)m = (22)m 4 (22a)m= Adjusted infiltration rate (allowing for shelter and wind speed) = (21a) x (22a)m Calculate effective air change rate for the applicable case If mechanical ventilation: If exhaust air heat pump using Appendix N, (23b) = (23a) Fmv (equation (N5)), otherwise (23b) = (23a) If balanced with heat recovery: efficiency in % allowing for in-use factor (from Table 4h) = a) If balanced mechanical ventilation with heat recovery (MVHR) (24a)m = (22b)m + (23b) [1 (23c) 1] (24a)m= b) If balanced mechanical ventilation without heat recovery (MV) (24b)m = (22b)m + (23b) (24b)m= c) If whole house extract ventilation or positive input ventilation from outside if (22b)m <.5 (23b), then (24c) = (23b); otherwise (24c) = (22b) m +.5 (23b) (24c)m= d) If natural ventilation or whole house positive input ventilation from loft if (22b)m = 1, then (24d)m = (22b)m otherwise (24d)m =.5 + [(22b)m² x.5] (24d)m= Effective air change rate - enter (24a) or (24b) or (24c) or (24d) in box (25) (25)m= (23a) (23b) (23c) (24a) (24b) (24c) (24d) (25) 3. Heat losses and heat loss parameter: ELEMENT Gross Openings Net Area U-value A X U k-value A X k area (m²) m² A,m² W/m2K (W/K) kj/m² K kj/k Doors 2.1 x 1.3 = 2.73 (26) Windows Type x 1/[1/( 1.3 )+.4] = 1.54 (27) Windows Type x 1/[1/( 1.3 )+.4] = 11.2 (27) Windows Type 3.39 x 1/[1/( 1.3 )+.4] =.48 (27) Windows Type x 1/[1/( 1.3 )+.4] = 5.8 (27) Rooflights 1.6 x 1/[1/(1.6) +.4] = 2.56 (27b) Floor 59.6 x.17 = 1.42 (28) Walls x.2 = (29) Roof x.11 = 6.32 (3) Total area of elements, m² (31) * for windows and roof windows, use effective window U-value calculated using formula 1/[(1/U-value)+.4] as given in paragraph 3.2 ** include the areas on both sides of internal walls and partitions Fabric heat loss, W/K = S (A x U) (26) (3) + (32) = (33) Heat capacity Cm = S(A x k ) ((28) (3) + (32) + (32a) (32e) = (34) Thermal mass parameter (TMP = Cm TFA) in kj/m²k Indicative Value: Medium 25 (35) For design assessments where the details of the construction are not known precisely the indicative values of TMP in Table 1f can be used instead of a detailed calculation. Thermal bridges : S (L x Y) calculated using Appendix K (36) Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 7

17 Fabric Efficiency WorkSheet: New dwelling as built if details of thermal bridging are not known (36) =.15 x (31) Total fabric heat loss (33) + (36) = (37) Ventilation heat loss calculated monthly (38)m =.33 (25)m x (5) (38)m= (38) Heat transfer coefficient, W/K (39)m = (37) + (38)m (39)m= Heat loss parameter (HLP), W/m²K (4)m = (39)m (4) Average = Sum(39) 1 12 /12= (39) (4)m= Number of days in month (Table 1a) Average = Sum(4) 1 12 /12= 1.34 (4) (41)m= (41) 4. Water heating energy requirement: kwh/year: Assumed occupancy, N 2.78 (42) if TFA > 13.9, N = x [1 - exp(-.349 x (TFA -13.9)2)] +.13 x (TFA -13.9) if TFA 13.9, N = 1 Annual average hot water usage in litres per day Vd,average = (25 x N) (43) Reduce the annual average hot water usage by 5% if the dwelling is designed to achieve a water use target of not more that 125 litres per person per day (all water use, hot and cold) Hot water usage in litres per day for each month Vd,m = factor from Table 1c x (43) (44)m= Total = Sum(44) 1 12 = (44) Energy content of hot water used - calculated monthly = 4.19 x Vd,m x nm x DTm / 36 kwh/month (see Tables 1b, 1c, 1d) (45)m= If instantaneous water heating at point of use (no hot water storage), enter in boxes (46) to (61) Total = Sum(45) 1 12 = (45) (46)m= (46) Water storage loss: a) If manufacturer s declared loss factor is known (kwh/day): (47) Temperature factor from Table 2b (48) Energy lost from water storage, kwh/year (47) x (48) = (49) If manufacturer s declared cylinder loss factor is not known: Cylinder volume (litres) including any solar storage within same (5) If community heating and no tank in dwelling, enter 11 litres in box (5) Otherwise if no stored hot water (this includes instantaneous combi boilers) enter '' in box (5) Hot water storage loss factor from Table 2 (kwh/litre/day) (51) Volume factor from Table 2a (52) Temperature factor from Table 2b (53) Energy lost from water storage, kwh/year ((5) x (51) x (52) x (53) = (54) Enter (49) or (54) in (55) (55) Water storage loss calculated for each month ((56)m = (55) (41)m (56)m= (56) Stroma FSAP 29 Version: (SAP 9.9) - Page 3 of 7

18 Fabric Efficiency WorkSheet: New dwelling as built If cylinder contains dedicated solar storage, (57)m = (56)m x [(5) (H11)] (5), else (57)m = (56)m where (H11) is from Appendix H (57)m= (57) Primary circuit loss (annual) from Table 3 (58) Primary circuit loss calculated for each month (59)m = (58) 365 (41)m (modified by factor from Table H5 if there is solar water heating and a cylinder thermostat) (59)m= (59) Combi loss calculated for each month (61)m = (6) 365 (41)m (61)m= (61) Total heat required for water heating calculated for each month (62)m =.85 (45)m + (46)m + (57)m + (59)m + (61)m (62)m= (62) Solar DHW input calculated using Appendix G or Appendix H (negative quantity) (enter '' if no solar contribution to water heating) (add additional lines if FGHRS and/or WWHRS applies, see Appendix G) (63)m= (63) Output from water heater (64)m= Output immersion Output from water heater (annual) (64) (64)m= Output from immersion (annual) (64) Heat gains from water heating, kwh/month.25 [.85 (45)m + (61)m] +.8 x [(46)m + (57)m + (59)m ] (65)m= (65) include (57)m in calculation of (65)m only if cylinder is in the dwelling or hot water is from community heating 5. Internal gains (see Table 5 and 5a): Metabolic gains (Table 5), Watts (66)m= (66) Lighting gains (calculated in Appendix L, equation L9 or L9a), also see Table 5 (67)m= (67) Appliances gains (calculated in Appendix L, equation L13 or L13a), also see Table 5 (68)m= (68) Cooking gains (calculated in Appendix L, equation L15 or L15a), also see Table 5 (69)m= (69) Pumps and fans gains (Table 5a) (7)m= (7) Losses e.g. evaporation (negative values) (Table 5) (71)m= (71) Water heating gains (Table 5) (72)m= (72) Total internal gains = (66)m + (67)m + (68)m + (69)m + (7)m + (71)m + (72)m (73)m= (73) 6. Solar gains: Solar gains are calculated using solar flux from Table 6a and associated equations to convert to the applicable orientation. Stroma FSAP 29 Version: (SAP 9.9) - Page 4 of 7

19 Fabric Efficiency WorkSheet: New dwelling as built Orientation: Access Factor Area Flux g_ FF Gains Table 6d m² Table 6a Table 6b Table 6c (W) North.9x.77 x.39 x 1.73 x.63 x.7 = 1.28 (74) North.9x.77 x.39 x 2.36 x.63 x.7 = 2.43 (74) North.9x.77 x.39 x x.63 x.7 = 3.97 (74) North.9x.77 x.39 x x.63 x.7 = 6.51 (74) North.9x.77 x.39 x x.63 x.7 = 8.96 (74) North.9x.77 x.39 x 84.9 x.63 x.7 = 1.2 (74) North.9x.77 x.39 x x.63 x.7 = 9.43 (74) North.9x.77 x.39 x x.63 x.7 = 7.34 (74) North.9x.77 x.39 x 41.9 x.63 x.7 = 4.9 (74) North.9x.77 x.39 x x.63 x.7 = 2.96 (74) North.9x.77 x.39 x x.63 x.7 = 1.58 (74) North.9x.77 x.39 x 8.94 x.63 x.7 = 1.7 (74) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = 1.41 (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x 98.3 x.63 x.7 = (76) East.9x 1 x 8.53 x 73.6 x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x 18.9 x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x 56.7 x.63 x.7 = 8.37 (78) South.9x.77 x 4.69 x 4.89 x.63 x.7 = (78) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = 15 (8) West.9x.77 x 8.92 x x.63 x.7 = (8) Stroma FSAP 29 Version: (SAP 9.9) - Page 5 of 7

20 Fabric Efficiency WorkSheet: New dwelling as built West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = 37.7 (8) West.9x.77 x 8.92 x 98.3 x.63 x.7 = (8) West.9x.77 x 8.92 x 73.6 x.63 x.7 = 2.65 (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) Rooflights.9x 1 x 1.6 x 26 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 54 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 94 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 15 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 19 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 21 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 194 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 164 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 116 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 68 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 33 x.63 x.7 = 2.96 (82) Rooflights.9x 1 x 1.6 x 21 x.63 x.7 = (82) Solar gains in watts, calculated for each month (83)m = Sum(74)m (82)m (83)m= (83) Total gains internal and solar (84)m = (73)m + (83)m, watts (84)m= (84) 7. Mean internal temperature (heating season) Temperature during heating periods in the living area from Table 9, Th1 ( C) 21 Utilisation factor for gains for living area, h1,m (see Table 9a) (86)m= Mean internal temperature in living area T1 (follow steps 3 to 7 in Table 9c) (87)m= Temperature during heating periods in rest of dwelling from Table 9, Th2 ( C) (88)m= Utilisation factor for gains for rest of dwelling, h2,m (see Table 9a) (89)m= Mean internal temperature in the rest of dwelling T2 (follow steps 3 to 7 in Table 9c) (9)m= (85) (86) (87) (88) (89) (9) fla = Living area (4) = (91).28 Mean internal temperature (for the whole dwelling) = fla T1 + (1 fla) T2 (92)m= (92) Stroma FSAP 29 Version: (SAP 9.9) - Page 6 of 7

21 Fabric Efficiency WorkSheet: New dwelling as built Apply adjustment to the mean internal temperature from Table 4e, where appropriate (93)m= Space heating requirement Set Ti to the mean internal temperature obtained at step 11 of Table 9b, so that Ti,m=(76)m and re-calculate the utilisation factor for gains using Table 9a Utilisation factor for gains, hm: (94)m= Useful gains, hmgm, W = (94)m x (84)m (95)m= Monthly average external temperature from Table 8 (96)m= Heat loss rate for mean internal temperature, Lm, W =[(39)m x [(93)m (96)m ] (97)m= Space heating requirement for each month, kwh/month =.24 x [(97)m (95)m] x (41)m (98)m= (93) (94) (95) (96) (97) Total per year (kwh/year) = Sum(98) 1...5, = (98) Space heating requirement in kwh/m²/year 5.59 (99) 8c. Space cooling requirement Calculated for June, July and August. See Table 1b Heat loss rate Lm (calculated using 25 C internal temperature and external temperature from Table 1) (1)m= (1) Utilisation factor for loss hm (11)m= (11) Useful loss, hmlm (Watts) = (1)m x (11)m (12)m= (12) Gains (solar gains calculated for applicable weather region, see Table 1) (13)m= (13) Space cooling requirement for month, whole dwelling, continuous ( kwh) =.24 x [(13)m (12)m ] x (41)m set (14)m to zero if (14)m < 3 (98)m (14)m= Total = Sum(14) = (14) Cooled fraction f C = cooled area (4) = 1 (15) Intermittency factor (Table 1b) (16)m= Space cooling requirement for month = (14)m (15) (16)m (17)m= Total = Sum(14) = Total = Sum(17) = Space cooling requirement in kwh/m²/year (17) (4) = 3.15 (18) 8f. Fabric Energy Efficiency (calculated only under special conditions, see section 11) Fabric Energy Efficiency (99) + (18) = (19) (16) (17) Stroma FSAP 29 Version: (SAP 9.9) - Page 7 of 7

22 DER WorkSheet: New dwelling as built User Details: Assessor Name: Behdad Yazdani Stroma Number: STRO2254 Software Name: Stroma FSAP 29 Software Version: Version: Property Address: House 1 Address : House A, 38, Salcott Road, LONDON, SW11 6DE 1. Overall dwelling dimensions: Area(m²) Ave Height(m) Volume(m³) Ground floor (1a) x (2a) = (3a) First floor (1b) x (2b) = (3b) Total floor area TFA = (1a)+(1b)+(1c)+(1d)+(1e)+...(1n) (4) Dwelling volume (3a)+(3b)+(3c)+(3d)+(3e)+...(3n) = (5) Ventilation rate: main Secondary other total m³ per hour heating heating Number of chimneys + + = x 4 = (6a) Number of open flues + + = x 2 = (6b) Number of intermittent fans x 1 = (7a) 3 3 Number of passive vents x 1 = (7b) Number of flueless gas fires x 4 = (7c) Air changes per hour Infiltration due to chimneys, flues and fans = (6a)+(6b)+(7a)+(7b)+(7c) = 3 (5) =.11 (8) If a pressurisation test has been carried out or is intended, proceed to (17), otherwise continue from (9) to (16) Number of storeys in the dwelling (ns) (9) Additional infiltration [(9)-1]x.1 = (1) Structural infiltration:.25 for steel or timber frame or.35 for masonry construction (11) if both types of wall are present, use the value corresponding to the greater wall area (after deducting areas of openings); if equal user.35 If suspended wooden floor, enter.2 (unsealed) or.1 (sealed), else enter (12) If no draught lobby, enter.5, else enter (13) Percentage of windows and doors draught stripped (14) Window infiltration.25 - [.2 x (14) 1] = (15) Infiltration rate (8) + (1) + (11) + (12) + (13) + (15) = (16) Air permeability value, q5, expressed in cubic metres per hour per square metre of envelope area (17) 5 If based on air permeability value, then (18) = [(17) 2]+(8), otherwise (18) = (16) (18).36 Air permeability value applies if a pressurisation test has been done or a degree air permeability is being used Number of sides on which sheltered 2 (19) Shelter factor (2) = 1 - [.75 x (19)] =.85 (2) Infiltration rate incorporating shelter factor (21) = (18) x (2) = (21).31 Infiltration rate modified for monthly wind speed Monthly average wind speed from Table 7 (22)m= Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 8

23 DER WorkSheet: New dwelling as built Wind Factor (22a)m = (22)m 4 (22a)m= Adjusted infiltration rate (allowing for shelter and wind speed) = (21a) x (22a)m Calculate effective air change rate for the applicable case If mechanical ventilation: If exhaust air heat pump using Appendix N, (23b) = (23a) Fmv (equation (N5)), otherwise (23b) = (23a) If balanced with heat recovery: efficiency in % allowing for in-use factor (from Table 4h) = a) If balanced mechanical ventilation with heat recovery (MVHR) (24a)m = (22b)m + (23b) [1 (23c) 1] (24a)m= b) If balanced mechanical ventilation without heat recovery (MV) (24b)m = (22b)m + (23b) (24b)m= c) If whole house extract ventilation or positive input ventilation from outside if (22b)m <.5 (23b), then (24c) = (23b); otherwise (24c) = (22b) m +.5 (23b) (24c)m= d) If natural ventilation or whole house positive input ventilation from loft if (22b)m = 1, then (24d)m = (22b)m otherwise (24d)m =.5 + [(22b)m² x.5] (24d)m= Effective air change rate - enter (24a) or (24b) or (24c) or (24d) in box (25) (25)m= (23a) (23b) (23c) (24a) (24b) (24c) (24d) (25) 3. Heat losses and heat loss parameter: ELEMENT Gross Openings Net Area U-value A X U k-value A X k area (m²) m² A,m² W/m2K (W/K) kj/m² K kj/k Doors 2.1 x 1.3 = 2.73 (26) Windows Type x 1/[1/( 1.3 )+.4] = 1.54 (27) Windows Type x 1/[1/( 1.3 )+.4] = 11.2 (27) Windows Type 3.39 x 1/[1/( 1.3 )+.4] =.48 (27) Windows Type x 1/[1/( 1.3 )+.4] = 5.8 (27) Rooflights 1.6 x 1/[1/(1.6) +.4] = 2.56 (27b) Floor 59.6 x.17 = 1.42 (28) Walls x.2 = (29) Roof x.11 = 6.32 (3) Total area of elements, m² (31) * for windows and roof windows, use effective window U-value calculated using formula 1/[(1/U-value)+.4] as given in paragraph 3.2 ** include the areas on both sides of internal walls and partitions Fabric heat loss, W/K = S (A x U) (26) (3) + (32) = (33) Heat capacity Cm = S(A x k ) ((28) (3) + (32) + (32a) (32e) = (34) Thermal mass parameter (TMP = Cm TFA) in kj/m²k Indicative Value: Medium 25 (35) For design assessments where the details of the construction are not known precisely the indicative values of TMP in Table 1f can be used instead of a detailed calculation. Thermal bridges : S (L x Y) calculated using Appendix K (36) Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 8

24 DER WorkSheet: New dwelling as built if details of thermal bridging are not known (36) =.15 x (31) Total fabric heat loss (33) + (36) = (37) Ventilation heat loss calculated monthly (38)m =.33 (25)m x (5) (38)m= (38) Heat transfer coefficient, W/K (39)m = (37) + (38)m (39)m= Heat loss parameter (HLP), W/m²K (4)m = (39)m (4) Average = Sum(39) 1 12 /12= (39) (4)m= Number of days in month (Table 1a) Average = Sum(4) 1 12 /12= 1.33 (4) (41)m= (41) 4. Water heating energy requirement: kwh/year: Assumed occupancy, N 2.78 (42) if TFA > 13.9, N = x [1 - exp(-.349 x (TFA -13.9)2)] +.13 x (TFA -13.9) if TFA 13.9, N = 1 Annual average hot water usage in litres per day Vd,average = (25 x N) (43) Reduce the annual average hot water usage by 5% if the dwelling is designed to achieve a water use target of not more that 125 litres per person per day (all water use, hot and cold) Hot water usage in litres per day for each month Vd,m = factor from Table 1c x (43) (44)m= Total = Sum(44) 1 12 = (44) Energy content of hot water used - calculated monthly = 4.19 x Vd,m x nm x DTm / 36 kwh/month (see Tables 1b, 1c, 1d) (45)m= If instantaneous water heating at point of use (no hot water storage), enter in boxes (46) to (61) Total = Sum(45) 1 12 = (45) (46)m= (46) Water storage loss: a) If manufacturer s declared loss factor is known (kwh/day): (47) 1.6 Temperature factor from Table 2b (48).54 Energy lost from water storage, kwh/year (47) x (48) =.86 (49) If manufacturer s declared cylinder loss factor is not known: Cylinder volume (litres) including any solar storage within same (5) If community heating and no tank in dwelling, enter 11 litres in box (5) Otherwise if no stored hot water (this includes instantaneous combi boilers) enter '' in box (5) Hot water storage loss factor from Table 2 (kwh/litre/day) (51) Volume factor from Table 2a (52) Temperature factor from Table 2b (53) Energy lost from water storage, kwh/year ((5) x (51) x (52) x (53) = (54) Enter (49) or (54) in (55).86 (55) Water storage loss calculated for each month ((56)m = (55) (41)m (56)m= (56) Stroma FSAP 29 Version: (SAP 9.9) - Page 3 of 8

25 DER WorkSheet: New dwelling as built If cylinder contains dedicated solar storage, (57)m = (56)m x [(5) (H11)] (5), else (57)m = (56)m where (H11) is from Appendix H (57)m= (57) Primary circuit loss (annual) from Table 3 36 (58) Primary circuit loss calculated for each month (59)m = (58) 365 (41)m (modified by factor from Table H5 if there is solar water heating and a cylinder thermostat) (59)m= (59) Combi loss calculated for each month (61)m = (6) 365 (41)m (61)m= (61) Total heat required for water heating calculated for each month (62)m =.85 (45)m + (46)m + (57)m + (59)m + (61)m (62)m= (62) Solar DHW input calculated using Appendix G or Appendix H (negative quantity) (enter '' if no solar contribution to water heating) (add additional lines if FGHRS and/or WWHRS applies, see Appendix G) (63)m= (63) Output from water heater (64)m= Output immersion Output from water heater (annual) (64) (64)m= Output from immersion (annual) (64) Heat gains from water heating, kwh/month.25 [.85 (45)m + (61)m] +.8 x [(46)m + (57)m + (59)m ] (65)m= (65) include (57)m in calculation of (65)m only if cylinder is in the dwelling or hot water is from community heating 5. Internal gains (see Table 5 and 5a): Metabolic gains (Table 5), Watts (66)m= (66) Lighting gains (calculated in Appendix L, equation L9 or L9a), also see Table 5 (67)m= (67) Appliances gains (calculated in Appendix L, equation L13 or L13a), also see Table 5 (68)m= (68) Cooking gains (calculated in Appendix L, equation L15 or L15a), also see Table 5 (69)m= (69) Pumps and fans gains (Table 5a) (7)m= (7) Losses e.g. evaporation (negative values) (Table 5) (71)m= (71) Water heating gains (Table 5) (72)m= (72) Total internal gains = (66)m + (67)m + (68)m + (69)m + (7)m + (71)m + (72)m (73)m= (73) 6. Solar gains: Solar gains are calculated using solar flux from Table 6a and associated equations to convert to the applicable orientation. Stroma FSAP 29 Version: (SAP 9.9) - Page 4 of 8

26 DER WorkSheet: New dwelling as built Orientation: Access Factor Area Flux g_ FF Gains Table 6d m² Table 6a Table 6b Table 6c (W) North.9x.77 x.39 x 1.73 x.63 x.7 = 1.28 (74) North.9x.77 x.39 x 2.36 x.63 x.7 = 2.43 (74) North.9x.77 x.39 x x.63 x.7 = 3.97 (74) North.9x.77 x.39 x x.63 x.7 = 6.51 (74) North.9x.77 x.39 x x.63 x.7 = 8.96 (74) North.9x.77 x.39 x 84.9 x.63 x.7 = 1.2 (74) North.9x.77 x.39 x x.63 x.7 = 9.43 (74) North.9x.77 x.39 x x.63 x.7 = 7.34 (74) North.9x.77 x.39 x 41.9 x.63 x.7 = 4.9 (74) North.9x.77 x.39 x x.63 x.7 = 2.96 (74) North.9x.77 x.39 x x.63 x.7 = 1.58 (74) North.9x.77 x.39 x 8.94 x.63 x.7 = 1.7 (74) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = 1.41 (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x 98.3 x.63 x.7 = (76) East.9x 1 x 8.53 x 73.6 x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) East.9x 1 x 8.53 x x.63 x.7 = (76) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x 18.9 x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x x.63 x.7 = (78) South.9x.77 x 4.69 x 56.7 x.63 x.7 = 8.37 (78) South.9x.77 x 4.69 x 4.89 x.63 x.7 = (78) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = 15 (8) West.9x.77 x 8.92 x x.63 x.7 = (8) Stroma FSAP 29 Version: (SAP 9.9) - Page 5 of 8

27 DER WorkSheet: New dwelling as built West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = 37.7 (8) West.9x.77 x 8.92 x 98.3 x.63 x.7 = (8) West.9x.77 x 8.92 x 73.6 x.63 x.7 = 2.65 (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) West.9x.77 x 8.92 x x.63 x.7 = (8) Rooflights.9x 1 x 1.6 x 26 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 54 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 94 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 15 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 19 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 21 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 194 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 164 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 116 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 68 x.63 x.7 = (82) Rooflights.9x 1 x 1.6 x 33 x.63 x.7 = 2.96 (82) Rooflights.9x 1 x 1.6 x 21 x.63 x.7 = (82) Solar gains in watts, calculated for each month (83)m = Sum(74)m (82)m (83)m= (83) Total gains internal and solar (84)m = (73)m + (83)m, watts (84)m= (84) 7. Mean internal temperature (heating season) Temperature during heating periods in the living area from Table 9, Th1 ( C) 21 Utilisation factor for gains for living area, h1,m (see Table 9a) (86)m= Mean internal temperature in living area T1 (follow steps 3 to 7 in Table 9c) (87)m= Temperature during heating periods in rest of dwelling from Table 9, Th2 ( C) (88)m= Utilisation factor for gains for rest of dwelling, h2,m (see Table 9a) (89)m= Mean internal temperature in the rest of dwelling T2 (follow steps 3 to 7 in Table 9c) (9)m= (85) (86) (87) (88) (89) (9) fla = Living area (4) = (91).28 Mean internal temperature (for the whole dwelling) = fla T1 + (1 fla) T2 (92)m= (92) Stroma FSAP 29 Version: (SAP 9.9) - Page 6 of 8

28 DER WorkSheet: New dwelling as built Apply adjustment to the mean internal temperature from Table 4e, where appropriate (93)m= Space heating requirement Set Ti to the mean internal temperature obtained at step 11 of Table 9b, so that Ti,m=(76)m and re-calculate the utilisation factor for gains using Table 9a Utilisation factor for gains, hm: (94)m= Useful gains, hmgm, W = (94)m x (84)m (95)m= Monthly average external temperature from Table 8 (96)m= Heat loss rate for mean internal temperature, Lm, W =[(39)m x [(93)m (96)m ] (97)m= (93) (94) (95) (96) (97) Space heating requirement for each month, kwh/month =.24 x [(97)m (95)m] x (41)m (98)m= Total per year (kwh/year) = Sum(98) 1...5, = (98) Space heating requirement in kwh/m²/year (99) 9a. Energy requirements Individual heating systems including micro-chp) Space heating: Fraction of space heat from secondary/supplementary system (21) Fraction of space heat from main system(s) (22) = 1 (21) = 1 (22) Fraction of total heating from main system 1 (24) = (22) [1 (23)] = 1 (24) Efficiency of main space heating system (26) Efficiency of secondary/supplementary heating system, % (28) kwh/year Space heating requirement (calculated above) (211)m = {[(98)m x (24)] + (21)m } x 1 (26) (211) Space heating fuel (secondary), kwh/month = {[(98)m x (21)] + (214) m } x 1 (28) Total (kwh/year) =Sum(211) = 1...5, (211) (215)m= Water heating Output from water heater (calculated above) Total (kwh/year) =Sum(215) = 1...5,1. 12 (215) Efficiency of water heater (216) (217)m= (217) Fuel for water heating, kwh/month (219)m = (64)m x 1 (217)m (219)m= Water heating requirement (immersion) Total = Sum(219a) = (219) Efficiency Stroma FSAP of 29 water Version: heater (Immersion) (SAP 9.9) - 1Page 7 of (216) 8

29 DER WorkSheet: New dwelling as built (217)m= (217) Fuel for water heating (Immersion), kwh/month (219)m = [ (64)m + (218) m ] x 1 (217)m (219)m= Total = Sum(219a) = (219) Annual totals kwh/year kwh/year Space heating fuel used, main system Water heating fuel used Water heating fuel used (Immersion) Electricity for pumps, fans and electric keep-hot Total electricity for the above, kwh/year sum of (23a) (23g) = (231) Electricity for lighting (232) 12a. CO2 emissions Individual heating systems including micro-chp Energy Emission factor Emissions kwh/year kg CO2/kWh kg CO2/year Space heating (main system 1) (211) x = (261) Space heating (secondary) (215) x = (263) Water heating (219) x = (264) Water heating (Immersion) (219) x = (264) Space and water heating (261) + (262) + (263) + (264) = (265) Electricity for pumps, fans and electric keep-hot (231) x = (267).517 Electricity for lighting (232) x = (268) Total CO2, kg/year sum of (265) (271) = (272) Dwelling CO2 Emission Rate (272) (4) = (273) EI rating (section 14) (274) 83 Stroma FSAP 29 Version: (SAP 9.9) - Page 8 of 8

30 TER WorkSheet: New dwelling as built User Details: Assessor Name: Behdad Yazdani Stroma Number: STRO2254 Software Name: Stroma FSAP 29 Software Version: Version: Property Address: House 1 Address : House A, 38, Salcott Road, LONDON, SW11 6DE 1. Overall dwelling dimensions: Area(m²) Ave Height(m) Volume(m³) Ground floor (1a) x (2a) = (3a) First floor (1b) x (2b) = (3b) Total floor area TFA = (1a)+(1b)+(1c)+(1d)+(1e)+...(1n) (4) Dwelling volume (3a)+(3b)+(3c)+(3d)+(3e)+...(3n) = (5) Ventilation rate: main Secondary other total m³ per hour heating heating Number of chimneys + + = x 4 = (6a) Number of open flues + + = x 2 = (6b) Number of intermittent fans x 1 = (7a) 3 3 Number of passive vents x 1 = (7b) Number of flueless gas fires x 4 = (7c) Air changes per hour Infiltration due to chimneys, flues and fans = (6a)+(6b)+(7a)+(7b)+(7c) = 3 (5) =.11 (8) If a pressurisation test has been carried out or is intended, proceed to (17), otherwise continue from (9) to (16) Number of storeys in the dwelling (ns) (9) Additional infiltration [(9)-1]x.1 = (1) Structural infiltration:.25 for steel or timber frame or.35 for masonry construction (11) if both types of wall are present, use the value corresponding to the greater wall area (after deducting areas of openings); if equal user.35 If suspended wooden floor, enter.2 (unsealed) or.1 (sealed), else enter (12) If no draught lobby, enter.5, else enter (13) Percentage of windows and doors draught stripped (14) Window infiltration.25 - [.2 x (14) 1] = (15) Infiltration rate (8) + (1) + (11) + (12) + (13) + (15) = (16) Air permeability value, q5, expressed in cubic metres per hour per square metre of envelope area (17) 1 If based on air permeability value, then (18) = [(17) 2]+(8), otherwise (18) = (16) (18).61 Air permeability value applies if a pressurisation test has been done or a degree air permeability is being used Number of sides on which sheltered 2 (19) Shelter factor (2) = 1 - [.75 x (19)] =.85 (2) Infiltration rate incorporating shelter factor (21) = (18) x (2) = (21).52 Infiltration rate modified for monthly wind speed Monthly average wind speed from Table 7 (22)m= Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 7

31 TER WorkSheet: New dwelling as built Wind Factor (22a)m = (22)m 4 (22a)m= Adjusted infiltration rate (allowing for shelter and wind speed) = (21a) x (22a)m Calculate effective air change rate for the applicable case If mechanical ventilation: If exhaust air heat pump using Appendix N, (23b) = (23a) Fmv (equation (N5)), otherwise (23b) = (23a) If balanced with heat recovery: efficiency in % allowing for in-use factor (from Table 4h) = a) If balanced mechanical ventilation with heat recovery (MVHR) (24a)m = (22b)m + (23b) [1 (23c) 1] (24a)m= b) If balanced mechanical ventilation without heat recovery (MV) (24b)m = (22b)m + (23b) (24b)m= c) If whole house extract ventilation or positive input ventilation from outside if (22b)m <.5 (23b), then (24c) = (23b); otherwise (24c) = (22b) m +.5 (23b) (24c)m= d) If natural ventilation or whole house positive input ventilation from loft if (22b)m = 1, then (24d)m = (22b)m otherwise (24d)m =.5 + [(22b)m² x.5] (24d)m= Effective air change rate - enter (24a) or (24b) or (24c) or (24d) in box (25) (25)m= (23a) (23b) (23c) (24a) (24b) (24c) (24d) (25) 3. Heat losses and heat loss parameter: ELEMENT Gross Openings Net Area U-value A X U k-value A X k area (m²) m² A,m² W/m2K (W/K) kj/m² K kj/k Doors 1.85 x 2 = 3.7 (26) Windows x 1/[1/( 2 )+.4] = (27) Floor 59.6 x.25 = (28) Walls x.35 = (29) Roof x.16 = 9.45 (3) Total area of elements, m² (31) * for windows and roof windows, use effective window U-value calculated using formula 1/[(1/U-value)+.4] as given in paragraph 3.2 ** include the areas on both sides of internal walls and partitions Fabric heat loss, W/K = S (A x U) (26) (3) + (32) = (33) Heat capacity Cm = S(A x k ) ((28) (3) + (32) + (32a) (32e) = (34) Thermal mass parameter (TMP = Cm TFA) in kj/m²k Indicative Value: Medium 25 (35) For design assessments where the details of the construction are not known precisely the indicative values of TMP in Table 1f can be used instead of a detailed calculation. Thermal bridges : S (L x Y) calculated using Appendix K (36) if details of thermal bridging are not known (36) =.15 x (31) Total fabric heat loss (33) + (36) = (37) Ventilation heat loss calculated monthly (38)m =.33 (25)m x (5) (38)m= (38) Heat transfer coefficient, W/K (39)m = (37) + (38)m (39)m= Average = Sum(39) 1 12 /12= (39) Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 7

32 TER WorkSheet: New dwelling as built Heat loss parameter (HLP), W/m²K (4)m = (39)m (4) (4)m= Number of days in month (Table 1a) Average = Sum(4) 1 12 /12= 2.4 (4) (41)m= (41) 4. Water heating energy requirement: kwh/year: Assumed occupancy, N 2.78 (42) if TFA > 13.9, N = x [1 - exp(-.349 x (TFA -13.9)2)] +.13 x (TFA -13.9) if TFA 13.9, N = 1 Annual average hot water usage in litres per day Vd,average = (25 x N) (43) Reduce the annual average hot water usage by 5% if the dwelling is designed to achieve a water use target of not more that 125 litres per person per day (all water use, hot and cold) Hot water usage in litres per day for each month Vd,m = factor from Table 1c x (43) (44)m= Total = Sum(44) 1 12 = (44) Energy content of hot water used - calculated monthly = 4.19 x Vd,m x nm x DTm / 36 kwh/month (see Tables 1b, 1c, 1d) (45)m= If instantaneous water heating at point of use (no hot water storage), enter in boxes (46) to (61) Total = Sum(45) 1 12 = (45) (46)m= (46) Water storage loss: a) If manufacturer s declared loss factor is known (kwh/day): (47) Temperature factor from Table 2b (48) Energy lost from water storage, kwh/year (47) x (48) = (49) If manufacturer s declared cylinder loss factor is not known: Cylinder volume (litres) including any solar storage within same 15 (5) If community heating and no tank in dwelling, enter 11 litres in box (5) Otherwise if no stored hot water (this includes instantaneous combi boilers) enter '' in box (5) Hot water storage loss factor from Table 2 (kwh/litre/day) (51).2 Volume factor from Table 2a.93 (52) Temperature factor from Table 2b.54 (53) Energy lost from water storage, kwh/year ((5) x (51) x (52) x (53) = 1.44 (54) Enter (49) or (54) in (55) 1.44 (55) Water storage loss calculated for each month ((56)m = (55) (41)m (56)m= (56) If cylinder contains dedicated solar storage, (57)m = (56)m x [(5) (H11)] (5), else (57)m = (56)m where (H11) is from Appendix H (57)m= (57) Primary circuit loss (annual) from Table 3 61 (58) Primary circuit loss calculated for each month (59)m = (58) 365 (41)m (modified by factor from Table H5 if there is solar water heating and a cylinder thermostat) (59)m= (59) Combi loss calculated for each month (61)m = (6) 365 (41)m (61)m= (61) Stroma FSAP 29 Version: (SAP 9.9) - Page 3 of 7

33 TER WorkSheet: New dwelling as built Total heat required for water heating calculated for each month (62)m =.85 (45)m + (46)m + (57)m + (59)m + (61)m (62)m= (62) Solar DHW input calculated using Appendix G or Appendix H (negative quantity) (enter '' if no solar contribution to water heating) (add additional lines if FGHRS and/or WWHRS applies, see Appendix G) (63)m= (63) Output from water heater (64)m= Output from water heater (annual) (64) Heat gains from water heating, kwh/month.25 [.85 (45)m + (61)m] +.8 x [(46)m + (57)m + (59)m ] (65)m= (65) include (57)m in calculation of (65)m only if cylinder is in the dwelling or hot water is from community heating 5. Internal gains (see Table 5 and 5a): Metabolic gains (Table 5), Watts (66)m= (66) Lighting gains (calculated in Appendix L, equation L9 or L9a), also see Table 5 (67)m= (67) Appliances gains (calculated in Appendix L, equation L13 or L13a), also see Table 5 (68)m= (68) Cooking gains (calculated in Appendix L, equation L15 or L15a), also see Table 5 (69)m= (69) Pumps and fans gains (Table 5a) (7)m= (7) Losses e.g. evaporation (negative values) (Table 5) (71)m= (71) Water heating gains (Table 5) (72)m= (72) Total internal gains = (66)m + (67)m + (68)m + (69)m + (7)m + (71)m + (72)m (73)m= (73) 6. Solar gains: Solar gains are calculated using solar flux from Table 6a and associated equations to convert to the applicable orientation. Orientation: Access Factor Area Flux g_ FF Gains Table 6d m² Table 6a Table 6b Table 6c (W) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x 98.3 x.72 x.7 = (76) Stroma FSAP 29 Version: (SAP 9.9) - Page 4 of 7

34 TER WorkSheet: New dwelling as built East.9x 1 x x 73.6 x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) East.9x 1 x x x.72 x.7 = (76) Solar gains in watts, calculated for each month (83)m = Sum(74)m (82)m (83)m= (83) Total gains internal and solar (84)m = (73)m + (83)m, watts (84)m= (84) 7. Mean internal temperature (heating season) Temperature during heating periods in the living area from Table 9, Th1 ( C) 21 Utilisation factor for gains for living area, h1,m (see Table 9a) (86)m= Mean internal temperature in living area T1 (follow steps 3 to 7 in Table 9c) (87)m= Temperature during heating periods in rest of dwelling from Table 9, Th2 ( C) (88)m= Utilisation factor for gains for rest of dwelling, h2,m (see Table 9a) (89)m= Mean internal temperature in the rest of dwelling T2 (follow steps 3 to 7 in Table 9c) (9)m= (85) (86) (87) (88) (89) (9) fla = Living area (4) = (91).28 Mean internal temperature (for the whole dwelling) = fla T1 + (1 fla) T2 (92)m= Apply adjustment to the mean internal temperature from Table 4e, where appropriate (93)m= Space heating requirement Set Ti to the mean internal temperature obtained at step 11 of Table 9b, so that Ti,m=(76)m and re-calculate the utilisation factor for gains using Table 9a Utilisation factor for gains, hm: (94)m= Useful gains, hmgm, W = (94)m x (84)m (95)m= Monthly average external temperature from Table 8 (96)m= Heat loss rate for mean internal temperature, Lm, W =[(39)m x [(93)m (96)m ] (97)m= (92) (93) (94) (95) (96) (97) Space heating requirement for each month, kwh/month =.24 x [(97)m (95)m] x (41)m (98)m= Total per year (kwh/year) = Sum(98) 1...5, = (98) Space heating requirement in kwh/m²/year (99) Stroma FSAP 29 Version: (SAP 9.9) - Page 5 of 7

35 TER WorkSheet: New dwelling as built 9a. Energy requirements Individual heating systems including micro-chp) Space heating: Fraction of space heat from secondary/supplementary system.1 (21) Fraction of space heat from main system(s) (22) = 1 (21) =.9 (22) Fraction of total heating from main system 1 (24) = (22) [1 (23)] =.9 (24) Efficiency of main space heating system (26) Efficiency of secondary/supplementary heating system, % 1 (28) kwh/year Space heating requirement (calculated above) (211)m = {[(98)m x (24)] + (21)m } x 1 (26) (211) Space heating fuel (secondary), kwh/month = {[(98)m x (21)] + (214) m } x 1 (28) Total (kwh/year) =Sum(211) = 1...5, (211) (215)m= Water heating Output from water heater (calculated above) Total (kwh/year) =Sum(215) = 1...5, (215) Efficiency of water heater 68.8 (216) (217)m= (217) Fuel for water heating, kwh/month (219)m = (64)m x 1 (217)m (219)m= Total = Sum(219a) = (219) Annual totals kwh/year kwh/year Space heating fuel used, main system Space heating fuel used, secondary Water heating fuel used Electricity for pumps, fans and electric keep-hot central heating pump: boiler with a fan-assisted flue (23c) (23e) Total electricity for the above, kwh/year sum of (23a) (23g) = 175 (231) Electricity for lighting (232) 12a. CO2 emissions Individual heating systems including micro-chp Energy Emission factor Emissions kwh/year kg CO2/kWh kg CO2/year Space heating (main system 1) (211) x = (261) Space heating (secondary) (215) x = (263) Water heating (219) x = (264) Stroma FSAP 29 Version: (SAP 9.9) - Page 6 of 7

36 TER WorkSheet: New dwelling as built Space and water heating (261) + (262) + (263) + (264) = (265) Electricity for pumps, fans and electric keep-hot (231) x = (267) Electricity for lighting (232) x = (268) Total CO2, kg/year sum of (265) (271) = (272) Dwelling CO2 Emission Rate (272) (4) = (273) EI rating (section 14) (274) 7 TER value = Stroma FSAP 29 Version: (SAP 9.9) - Page 7 of 7

37 SAP 29 Overheating Assessment Calculated by Stroma FSAP 29 program, produced and printed on 17 February 213 Property Details: House 1 Dwelling type: Detached House Located in: England Region: Thames valley Cross ventilation possible: No Number of storeys: 2 Front of dwelling faces: East Overshading: Average or unknown Overhangs: None Thermal mass parameter: Night ventilation: False Blinds, curtains, shutters: None Ventilation rate during hot weather (ach): 2.5 ( Windows open half the time) Overheating Details: Summer ventilation heat loss coefficient: (P1) Transmission heat loss coefficient: 89.6 Summer heat loss coefficient: (P2) Overhangs: Orientation: Ratio: Z_overhangs: East (EAST) 1 West (WEST) 1 North (NORTH) 1 South (SOUTH) 1 West (ROOF) 1 Solar shading: Orientation: Z blinds: Solar access: Overhangs: Z summer: East (EAST) (P8) West (WEST) (P8) North (NORTH) (P8) South (SOUTH) (P8) West (ROOF) (P8) Solar gains: Orientation (calculation for July) Area Flux g_ FF Shading Gains East (EAST).9 x West (WEST).9 x North (NORTH).9 x South (SOUTH).9 x x Total (P3/P4) Internal gains: June July August Internal gains Total summer gains (P5) Summer gain/loss ratio (P6) Mean summer external temperature (Thames valley) Stroma FSAP 29 Version: (SAP 9.9) - Page 1 of 2

38 SAP 29 Overheating Assessment Thermal mass temperature increment Threshold temperature (P7) Likelihood of high internal temperature Slight Medium Medium Assessment of likelihood of high internal temperature: Medium Stroma FSAP 29 Version: (SAP 9.9) - Page 2 of 2

39 Predicted Energy Assessment House A 38, Salcott Road LONDON SW11 6DE Dwelling type: Detached House Date of assessment: 25 January 213 Produced by: Behdad Yazdani Total floor area: m² This is a Predicted Energy Assessment for a property which is not yet complete. It includes a predicted energy rating which might not represent the final energy rating of the property on completion. Once the property is completed, an Energy Performance Certificate is required providing information about the energy performance of the completed property. Energy performance has been assessed using the SAP 29 methodology and is rated in terms of the energy use per square metre of floor area, energy efficiency based on fuel costs and environmental impact based on carbon dioxide (CO2) emissions. Energy Efficiency Rating Environmental Impact (CO ) Rating 2 The energy efficiency rating is a measure of the overall efficiency of a home. The higher the rating the more energy efficient the home is and the lower the fuel bills are likely to be. The environmental impact rating is a measure of a home s impact on the environment in terms of carbonn dioxide (CO2) emissions. The higher the rating the less impact it has on the environment.