LESSON 3.5 — Thermal Comfort and Building Envelope Performance
A. Standard Map
| Topic | Governing Source | Exam Focus |
|---|---|---|
| Thermal comfort — definition | ASHRAE 55-2020; Fanger, P.O. (1970) | PMV-PPD model; six factors |
| Adaptive comfort model | ASHRAE 55; NBC 2016; ECBC 2017 | Naturally ventilated / mixed-mode buildings in India |
| Comfort factors — environmental and personal | ASHRAE 55; IS:3792 | 4 environmental + 2 personal |
| Comfort indices: ET, WBGT | Standard thermal comfort science | Effective Temperature; Wet Bulb Globe Temperature |
| Thermal transmittance (U-value) | IS:3792; ECBC 2017; NBC 2016 | U = W/m²K; lower = better insulation |
| Thermal time lag | Standard building physics | Formula; time delay between peak outside and peak inside temperature |
| Solar heat gain coefficient (SHGC) | ECBC 2017; ASHRAE 90.1 | Lower SHGC = less solar heat gain; fenestration spec |
| Albedo and surface reflectance | Standard building physics | High albedo = more reflected; cool roofs |
| Thermal bridges | Standard building physics | Paths of high conductivity bypassing insulation |
| Vapour barrier and condensation | Standard building physics | Dew point; interstitial condensation; placement rules |
| Ventilation — types and rates | NBC 2016 Part 8; IS:3103 | Natural, mechanical, hybrid; ACH; cross-ventilation vs stack |
B. Mechanism in Words
- Thermal comfort is a psychological state — the mind’s assessment that the body is thermally neutral, neither too hot nor too cold.
- The body gains heat from metabolism and solar radiation; it loses heat through convection, radiation, evaporation, and conduction. Comfort occurs when these gains and losses are balanced.
- Building materials slow or accelerate this exchange. High-conductivity materials (metals) transmit heat rapidly; insulating materials resist the transfer.
- The building envelope modulates the rate at which outdoor conditions reach the interior — thermal mass stores energy and releases it with a time lag; insulation reduces the amplitude of temperature swings.
- Windows are both the weakest insulating element (lowest thermal resistance) and the primary solar gain aperture — their specification involves a trade-off between daylighting, solar heat gain, and heat loss.
- Ventilation replaces stale air and removes heat and humidity; natural ventilation uses wind pressure and thermal buoyancy; mechanical ventilation uses fans; hybrid systems combine both.
C. Core Concept Explanations
C1. Thermal Comfort — Definition and Model
Definition (ASHRAE 55): “That condition of mind which expresses satisfaction with the thermal environment and is assessed by subjective evaluation.”
The most widely used analytical model for thermal comfort is the PMV-PPD model developed by P.O. Fanger (1970).
- PMV (Predicted Mean Vote): Predicts the average thermal sensation of a large group of people on a 7-point scale from −3 (cold) to +3 (hot); 0 = neutral (comfortable).
- PPD (Predicted Percentage Dissatisfied): The predicted percentage of people dissatisfied with the thermal environment. At PMV = 0, PPD ≈ 5% (even in ideal conditions, ~5% of people are dissatisfied).
- ASHRAE comfort standard: PMV between −0.5 and +0.5 gives PPD < 10% — typically considered acceptable.
C2. Six Factors Affecting Thermal Comfort
Thermal comfort depends on four environmental parameters and two personal parameters:
Environmental (can be measured and controlled by the designer):
| Factor | Description | Design implication |
|---|---|---|
| Air temperature (dry-bulb) | Temperature of the air surrounding the body | HVAC set-point; room layout to avoid stratification |
| Mean radiant temperature (MRT) | Average temperature of all surrounding surfaces (walls, ceiling, floor, windows) | Surface insulation; window specification; floor heating |
| Relative humidity (RH) | Amount of water vapour in air relative to saturation | 30–70% RH for comfort; high RH impairs evaporative cooling |
| Air velocity (wind speed) | Speed of air movement past the body | Ceiling fans; diffuser placement; natural ventilation design |
Personal (reflect occupant characteristics):
| Factor | Description | Range for normal activity |
|---|---|---|
| Metabolic rate (met) | Heat produced by the body per unit area; increases with activity | 1.0 met = seated at rest; 3.0 met = vigorous exercise |
| Clothing insulation (clo) | Thermal resistance of clothing | 0.5 clo = summer clothing; 1.0 clo = typical indoor clothing |
Exam Anchor: Thermal comfort has 6 factors: 4 environmental (air temp, MRT, humidity, air velocity) + 2 personal (metabolic rate, clothing). Of these, the designer can directly control the 4 environmental ones through architectural and HVAC design.
C1b. Adaptive Comfort Model
The adaptive comfort model applies to naturally ventilated and mixed-mode buildings where occupants can open windows, adjust clothing, and use fans. Unlike the fixed PMV band for fully conditioned spaces, acceptable indoor temperature tracks the outdoor running mean temperature.
| Concept | Detail |
|---|---|
| Core idea | People adapt to seasonal outdoor conditions — wider comfort band when they control their environment |
| Relevance in India | Residences, classrooms, and offices with operable windows; ECBC and NBC acknowledge adaptive comfort for non-air-conditioned zones |
| Design implication | Prioritise ventilation, shading, and occupant control before defaulting to mechanical cooling |
| Exam distinction | PMV-PPD = analytical model for conditioned spaces; adaptive comfort = free-running / NV contexts |
Exam Anchor: Do not apply a narrow PMV ±0.5 criterion to a naturally ventilated Indian classroom — the adaptive model allows a broader, climate-linked comfort range when occupants can adapt.
C3. Comfort Indices
| Index | Full name | What it integrates | Use |
|---|---|---|---|
| ET (Effective Temperature) | Effective Temperature | Air temperature + humidity + air velocity → single comfort index | Standard comfort assessment; replaces individual parameter analysis |
| WBGT (Wet Bulb Globe Temperature) | Wet Bulb Globe Temperature | Dry-bulb, wet-bulb (humidity), globe (radiant) temperatures combined | Outdoor thermal stress assessment; industrial and sports applications |
| Comfort Temperature (T_c) | Neutral temperature / Comfort temperature | The temperature at which a building occupant feels neutral | Adaptive thermal comfort standard; varies with outdoor running mean temperature |
C4. Thermal Properties of Building Elements
Thermal Transmittance (U-value):
U-value measures the rate of heat transfer through a building element per unit area per unit temperature difference.
$$U = frac{1}{R_{total}} quad text{where } R_{total} = R_{si} + R_1 + R_2 + … + R_{so}$$
| Symbol | Meaning | Unit |
|---|---|---|
| U | Thermal transmittance | W/m²K |
| R | Thermal resistance (= thickness / conductivity = d/λ) | m²K/W |
| R_si, R_so | Internal and external surface resistances | m²K/W |
| λ (lambda) | Thermal conductivity of material | W/mK |
Lower U-value = better thermal insulation. A well-insulated wall may have U = 0.20 W/m²K; a single-glazed window has U ≈ 5.6 W/m²K (28× worse). Double glazing ≈ 2.8 W/m²K; triple glazing ≈ 0.7 W/m²K.
Thermal Time Lag (φ):
The time delay between peak outdoor temperature and peak indoor temperature due to thermal mass.
$$phi = text{time for temperature wave to propagate through wall}$$
- Lightweight construction: time lag = a few hours (1–4 hours)
- Heavy masonry (300 mm brick): time lag ≈ 8–12 hours
- Earth-sheltered (1 m compacted earth): time lag ≈ 30+ hours
Design application (hot-dry): Select a wall thickness such that peak indoor temperature arrives after sunset — when outdoor temperatures have dropped. A 300 mm brick wall peaks at midnight instead of 2 PM.
Thermal Diffusivity (α):
A material property combining thermal conductivity (λ), density (ρ), and specific heat capacity (c_p):
$$alpha = frac{lambda}{rho cdot c_p}$$
High diffusivity = heat propagates quickly; Low diffusivity = heat propagates slowly (better for time lag).
C5. Solar Heat Gain Coefficient (SHGC)
SHGC is the fraction of incident solar radiation that passes through a glazing system (directly transmitted + absorbed and re-radiated inward).
| Property | Value | Implication |
|---|---|---|
| Range | 0.0 (no gain) to 1.0 (all gain) | Lower SHGC = less solar heat gain |
| Single glazing (clear) | ≈ 0.82 | High solar heat gain |
| Low-e glass | 0.25–0.45 | Significantly reduced solar heat gain |
| Tinted glass | 0.40–0.60 | Moderate reduction |
ECBC 2017 SHGC limits by climate zone (for conditioned buildings):
| Climate Zone | Maximum SHGC (WWR 40%) |
|---|---|
| Composite | 0.25 |
| Hot-dry | 0.25 |
| Warm-humid | 0.25 |
| Temperate | 0.40 |
| Cold | No limit (solar gain desired) |
Source: ECBC 2017, Bureau of Energy Efficiency (BEE), Ministry of Power, Government of India.
Exam Anchor: SHGC limits are tightest in composite, hot-dry, and warm-humid zones (all 0.25) where solar heat gain is the dominant cooling load driver. Cold zones have no upper SHGC limit — solar gain is beneficial.
C6. Window-to-Wall Ratio (WWR) and ECBC
WWR = Glazed area ÷ Total gross wall area (including glazing), expressed as a fraction or percentage.
ECBC 2017 prescribes maximum WWR for the fenestration of conditioned buildings. Excessive glazing increases both solar heat gain and conductive heat loss/gain, driving up energy use. ECBC sets WWR limits by climate zone.
| ECBC WWR limit | Maximum WWR |
|---|---|
| All climate zones (ECBC 2017 prescriptive) | 40% maximum |
Example: A south-facing 10 m × 3.5 m wall (35 m²) may have at most 35 × 0.40 = 14 m² of glazing.
C7. Thermal Bridges
A thermal bridge is a localised area of relatively high thermal conductance in an otherwise insulating building envelope — a path of low thermal resistance through which heat flows disproportionately.
| Type | Example | Effect |
|---|---|---|
| Structural (geometric) | RCC column within a masonry wall; concrete lintel over window | Column or lintel conducts heat at a much faster rate than the adjacent insulated masonry |
| Repeating | Metal wall ties in a cavity wall; fixings for external cladding | Multiple small high-conductivity paths create significant aggregate heat loss |
| Edge detail | Slab edge exposed through insulation; floor-wall junction | Common source of cold-surface condensation risk in cold climates |
Consequence in cold climates: Thermal bridges cause cold interior surface temperatures below the dew point → condensation forms on the interior surface → mould growth and fabric damage. Design to eliminate or thermally break all bridges.
C8. Ventilation Types and Rates
| Type | Mechanism | Key parameter | Application |
|---|---|---|---|
| Natural — cross-ventilation | Wind pressure drives air from windward openings through the space to leeward openings | Opening area ≥ 5% of floor area (NBC requirement) | Warm-humid; moderate climates; residential |
| Natural — stack (buoyancy) | Temperature difference between indoor and outdoor air; warm air rises and exits at high level; cooler air enters at low level | Height difference between inlet and outlet; temperature differential | Tall buildings; atriums; wind towers |
| Mechanical ventilation | Fans supply or extract air; ducted distribution | ACH (Air Changes per Hour) | High-occupancy spaces; sealed buildings; kitchens, toilets |
| Hybrid (mixed-mode) | Natural + mechanical; switches between modes based on conditions | Seasonal or daily switching logic | Large commercial buildings; energy-conscious design |
NBC 2016 Part 8 — Minimum ventilation requirements:
| Space | Minimum fresh air | Unit |
|---|---|---|
| Office / occupied space | 0.3 m³/person/minute | Or per NBC Part 8 Table |
| Kitchen (domestic) | 6 ACH | Air changes per hour |
| Bathroom/WC | 3 ACH | Air changes per hour |
| Car park (enclosed) | 6 ACH (mechanical) | Air changes per hour |
| Hospital ward | 0.42 m³/person/minute | Per ASHRAE 170 / NBC |
Source: NBC 2016 Part 8 (Building Services); IS:3103 (Industrial Ventilation).
D. Worked Numerical(s)
D1. Parameter Quick Reference
| Parameter | Value | Source |
|---|---|---|
| PMV comfort range | −0.5 to +0.5 | ASHRAE 55 |
| PPD at PMV = 0 | ~5% (minimum possible) | ASHRAE 55 / Fanger |
| U-value unit | W/m²K | IS:3792; ECBC |
| R_total | R_si + Σ(d/λ) + R_so | Standard building physics |
| ECBC wall U max — Hot-Dry | ≤ 0.40 W/m²K | ECBC 2017 (prescriptive) |
| ECBC roof U max — Hot-Dry | ≤ 0.33 W/m²K | ECBC 2017 (prescriptive) |
| SHGC max (composite, hot-dry, warm-humid) | 0.25 | ECBC 2017 |
| WWR maximum (ECBC prescriptive) | 40% | ECBC 2017 |
D2. Worked Example 1 — Composite wall U-value (three layers)
Problem: A wall assembly (outside to inside): outer brick 50 mm (λ = 0.84 W/mK); insulation board 75 mm (λ = 0.04 W/mK); inner plasterboard 12.5 mm (λ = 0.16 W/mK). Surface resistances: R_so = 0.04 m²K/W; R_si = 0.13 m²K/W. Calculate U in W/m²K (two decimal places).
Solution:
| Layer | d (m) | λ (W/mK) | R = d/λ (m²K/W) |
|---|---|---|---|
| External surface | — | — | 0.040 |
| Brick | 0.050 | 0.84 | 0.0595 |
| Insulation | 0.075 | 0.04 | 1.8750 |
| Plasterboard | 0.0125 | 0.16 | 0.0781 |
| Internal surface | — | — | 0.130 |
R_total = 0.040 + 0.0595 + 1.8750 + 0.0781 + 0.130 = 2.1826 m²K/W
U = 1 / R_total = 1 / 2.1826 = 0.46 W/m²K
Answer: U ≈ 0.46 W/m²K — well-insulated wall (insulation layer dominates R_total).
D3. Worked Example 2 — ECBC compliance check (Hot-Dry zone, Jaipur)
Problem: A commercial wall in Jaipur (Hot-Dry) comprises: 20 mm external plaster (λ = 0.80); 200 mm brick (λ = 0.80); 50 mm EPS (λ = 0.035); 12 mm internal plaster (λ = 0.50). R_so = 0.04; R_si = 0.13 m²K/W. ECBC 2017 prescriptive limit for opaque walls in Hot-Dry = U ≤ 0.40 W/m²K. Does the wall comply? If not, find minimum EPS thickness.
Solution:
| Layer | d (m) | λ | R = d/λ |
|---|---|---|---|
| R_so | — | — | 0.040 |
| External plaster | 0.020 | 0.80 | 0.025 |
| Brick | 0.200 | 0.80 | 0.250 |
| EPS | 0.050 | 0.035 | 1.429 |
| Internal plaster | 0.012 | 0.50 | 0.024 |
| R_si | — | — | 0.130 |
R_total = 0.040 + 0.025 + 0.250 + 1.429 + 0.024 + 0.130 = 1.898 m²K/W
U = 1 / 1.898 = 0.53 W/m²K → Non-compliant (0.53 > 0.40)
Required R_total = 1 / 0.40 = 2.500 m²K/W
Fixed layers (excluding EPS) = 1.898 − 1.429 = 0.469 m²K/W
Required EPS resistance = 2.500 − 0.469 = 2.031 m²K/W
Required EPS thickness = 2.031 × 0.035 = 0.071 m ≈ 71 mm
Answer: Current U = 0.53 W/m²K (fails). Need ≥ 71 mm EPS for compliance.
D4. Worked Example 3 — Roof U-value (four layers)
Problem: Roof assembly (outside to inside): 10 mm waterproofing (λ = 0.19); 100 mm RCC slab (λ = 1.60); 50 mm XPS insulation (λ = 0.033); 10 mm plaster soffit (λ = 0.72). R_so = 0.04; R_si = 0.13 m²K/W. Calculate U (W/m²K, two decimal places). ECBC Hot-Dry roof limit = 0.33 W/m²K — compliant?
Solution:
| Layer | d (m) | λ | R = d/λ |
|---|---|---|---|
| R_so | — | — | 0.040 |
| Waterproofing | 0.010 | 0.19 | 0.053 |
| RCC | 0.100 | 1.60 | 0.063 |
| XPS | 0.050 | 0.033 | 1.515 |
| Plaster | 0.010 | 0.72 | 0.014 |
| R_si | — | — | 0.130 |
R_total = 0.040 + 0.053 + 0.063 + 1.515 + 0.014 + 0.130 = 1.815 m²K/W
U = 1 / 1.815 = 0.55 W/m²K → Non-compliant for Hot-Dry roof (0.55 > 0.33)
Design note: XPS contributes 1.515 / 1.815 ≈ 83% of total resistance despite being only 50 mm thick — insulation specification dominates envelope performance.
Answer: U ≈ 0.55 W/m²K — fails ECBC roof limit; increase insulation thickness or use lower-λ board.
E. Common Confusions
| Confusion | Correct Distinction |
|---|---|
| Low U-value = poor insulation | LOWER U-value = BETTER insulation. U-value is the rate of heat LOSS — minimising it is the goal. R-value is the inverse (1/U) — higher R = better insulation. |
| SHGC and U-value are the same property | SHGC = solar heat gain fraction through glazing. U-value = overall thermal transmittance (conductive + convective heat flow). A high-SHGC glass can have a low U-value. They are independent properties. |
| High thermal mass = always good | Thermal mass is beneficial where there is a large diurnal temperature range (hot-dry, cold) to exploit. In warm-humid climates where night temperatures remain high, thermal mass retains unwanted heat. |
| Cross-ventilation requires openings only on one side | Cross-ventilation requires openings on BOTH windward and leeward sides. Single-sided openings provide only limited mixing ventilation, not true cross-ventilation. |
| Thermal bridge is a design feature | Thermal bridges are DEFECTS to be minimised or eliminated — they represent short-circuit paths for heat flow that bypass insulation. |
| PPD can be 0% in an ideal thermal environment | Minimum PPD ≈ 5% even at PMV = 0. Individual variation means that some people will always be dissatisfied in any shared environment. |
F. Exam Traps
| Trap | Incorrect Assumption | Correct Answer |
|---|---|---|
| T23 | “MRT = air temperature” | MRT (Mean Radiant Temperature) is the average temperature of all surrounding surfaces — walls, floor, ceiling, windows. It is NOT air temperature. Both contribute to thermal comfort but are independent. |
| T24 | “SHGC should be maximised for energy efficiency” | SHGC should be minimised in hot climates to reduce cooling loads. Only in cold climates (where solar gain is desired) is higher SHGC beneficial. Maximising SHGC in hot climates increases energy use. |
| T25 | “6 ACH in kitchens is optional” | NBC 2016 Part 8 requires 6 ACH for domestic kitchens. This is a minimum code requirement, not a recommendation. |
| T26 | “A single-glazed window has better thermal performance than a wall” | A single-glazed window has a U-value of ~5.6 W/m²K — far worse than even an un-insulated masonry wall (~2.0 W/m²K). Glass is among the poorest insulating building materials. |
| T27 | “WWR has no code limit in India” | ECBC 2017 prescribes a maximum WWR of 40% for conditioned buildings across all climate zones. |
G. Answer-Writing Cues
For U-value questions:
“Thermal transmittance (U-value) measures the rate of steady-state heat transfer through a building element per unit area per unit temperature difference, in W/m²K. A lower U-value indicates better thermal insulation. U is the reciprocal of total thermal resistance R_total. For glazing, lower U-value is achieved through additional panes (double, triple glazing) and low-emissivity coatings.”
For ECBC compliance numericals:
“Compute R for each layer as d/λ, sum with R_si and R_so to get R_total, then U = 1/R_total. Compare U against the ECBC prescriptive limit for the climate zone (e.g. Hot-Dry wall ≤ 0.40 W/m²K, roof ≤ 0.33 W/m²K). If non-compliant, solve for the additional insulation resistance required: R_insulation = (1/U_limit) − R_other_layers.”
For SHGC selection:
“Solar Heat Gain Coefficient (SHGC) is the fraction of incident solar radiation that enters a space through glazing. For buildings in composite, hot-dry, and warm-humid climates, ECBC 2017 prescribes a maximum SHGC of 0.25 at 40% WWR — limiting solar heat gain to reduce cooling loads. In cold climates where solar heat gain is beneficial, no SHGC limit is prescribed.”
H. PYQ Linkage Note
| Topic | Exam Appearance | Pattern |
|---|---|---|
| Six factors of thermal comfort | GATE, UPSC-CPWD | MCQ: list the factors; distinguish environmental from personal |
| PMV model — Fanger | GATE, UPSC-CPWD | MCQ: “PMV scale range is ___ to ___” |
| U-value definition | GATE multiple years | MCQ: “Low U-value means ___”; NAT: compute U from R |
| SHGC maximum (ECBC) | GATE, UPSC-CPWD | MCQ: limit for hot-dry zone |
| Thermal time lag concept | GATE, UPSC-CPWD | MCQ: concept; which material gives longer lag |
| Cross-ventilation requirements | UPSC-CPWD | MCQ: openings needed on which sides |
| Thermal bridges | UPSC-CPWD | MCQ: definition; where they occur |
I. Mini-Check — Lesson 3.5 (5 Questions)
Q1 (MCQ): The thermal comfort model based on Predicted Mean Vote (PMV) and Predicted Percentage Dissatisfied (PPD) was developed by:
(A) V. Olgyay (B) T.L. Mahoney (C) P.O. Fanger (D) T.R. Oke
A1: (C) P.O. Fanger, 1970 (Thermal Comfort: Analysis and Applications in Environmental Engineering). Olgyay (A) = bioclimatic chart 1963; Mahoney (B) = tabular climate analysis 1975; Oke (D) = Urban Heat Island energy balance 1982.
Q2 (MCQ): Which of the following statements about U-value is correct?
(A) A higher U-value indicates better thermal insulation
(B) U-value is measured in W/mK (thermal conductivity)
(C) U-value is the reciprocal of total thermal resistance; lower is better
(D) U-value and SHGC describe the same thermal property
A2: (C). U = 1 / R_total (W/m²K); lower U = better insulation. (A) reverses the relationship; (B) gives the unit for conductivity (λ), not U-value; (D) SHGC and U-value are independent properties.
Q3 (NAT): A wall has three layers: outer brick (50 mm, λ = 0.84 W/mK); insulation board (75 mm, λ = 0.04 W/mK); inner plasterboard (12.5 mm, λ = 0.16 W/mK). Internal surface resistance R_si = 0.13 m²K/W; external surface resistance R_so = 0.04 m²K/W. Calculate the U-value of the wall (W/m²K, to 2 decimal places).
A3:
– R_brick = 0.050 / 0.84 = 0.0595 m²K/W
– R_insulation = 0.075 / 0.04 = 1.875 m²K/W
– R_plasterboard = 0.0125 / 0.16 = 0.0781 m²K/W
– R_total = 0.13 + 0.0595 + 1.875 + 0.0781 + 0.04 = 2.1826 m²K/W
– U = 1 / 2.1826 = 0.46 W/m²K
Q4 (MCQ): Per ECBC 2017, the maximum permitted Solar Heat Gain Coefficient (SHGC) for fenestration in a hot-dry climate zone (at 40% WWR) is:
(A) 0.40 (B) 0.60 (C) 0.25 (D) No limit applies
A4: (C) 0.25. ECBC 2017 prescribes SHGC ≤ 0.25 for composite, hot-dry, and warm-humid zones. Cold zone has no limit. Temperate zone = 0.40.
Q5 (MCQ): For effective cross-ventilation in a room, openings must be provided on:
(A) The windward wall only (B) The south-facing wall only (C) Both windward and leeward walls (D) The ceiling level only via skylights
A5: (C) Both windward AND leeward walls. Cross-ventilation requires an inlet (windward) and an outlet (leeward) to create airflow across the space. Openings on one side only create single-sided ventilation — air mixing near the opening with limited penetration into the room depth.