Energy Consumption in Mid- to High-Rise Multi-Unit ... · Energy Consumption in Mid- to High-Rise...

Current Trends and the Impacts of Enclosure Upgrades

Energy Consumption in Mid- to High-Rise Multi-Unit Residential Buildings

Graham Finch, MAScWarren Knowles, P.EngEric Burnett, PhD

BEST 2 - PortlandNovember 12, 2010

Overview

Energy Consumption within Mid to High-Rise Multi-Unit Residential Buildings –Current Trends, & Issues

Effective R-values and the Impacts of Enclosure Upgrades on Energy Savings

Recommendations for Energy Efficient MURBs

MURB Energy Study

Industry sponsored research project, governments, utilities, engineering consultantsLooks at energy consumption a large population of similar mid-to high-rise MURBsSelected representative MURBs of past and current architectural designDecade of natural gas & electricity data provided by gas & electric utilitiesAllows the assessment of actual, not modeled energy consumption trends

MURB Energy Study

Several MURBs selected for the study were rehabilitated for water-ingress issues, “leaky condos”

More efficiently re-clad, Better windowsReduced air-leakageHigher overall R-values

Allows the assessment of actual energy savings from enclosure retrofits

A Few of the Energy Study Goals

Provide data for the current state of MURB housing stock Set achievable targets for MURB energy efficiencyDevelop recommendations for building code changes affecting MURBsDevelop recommendations for effective & efficient MURB energy upgradesIncentive ProgramsCalibrate energy models

Context

Energy consumed in Buildings accounts for 30-40% of all the energy used in Canada/USA

~55% used in residential buildings~45% used in commercial/institutional

Of the residential use: ~20% (Canada) is used in multi-family residential Energy use, or incentives forMURBs have not been looked at in as much detail as for single familyhomes

Resident ial

17%

Commer cial &

Inst it ut ional

14%

Indust r ial

37%

Tr anspor t at ion

30%

Agr icul t ur e

2%

Canada

Context: Local Utility Providers

Suite Energy Consumption by Year of Building Construction

0

1,000

2,000

3,000

4,000

5,000

6,000

7,000

< 1970 1970s 1980s 1990s 2000s AllYear of Construction

kW

h/s

uite

Rentals

Condos

Common Area Energy Consumption by Year of Building Construction

0

1,000

2,000

3,000

4,000

5,000

6,000

7,000

< 1970 1970s 1980s 1990s 2000s AllYear of Construction

kW

h/s

uite

Rentals

Condos

BC Hydro Data for all MURBs in Vancouver, BC

BUT: BC Hydro & Terasen Gas werre missing each others data

Building Enclosure Rehabilitations

Focus is to cost effectively repair moisture damageOwners burdened with large repair costs and are typically unwilling to spend extra for energy consumption improvements, however

Windows typically replaced,Air-leakage reduced,Exterior insulated assemblies, Improved cladding attachment strategies.

Energy improvements, if any, are aside benefitOwners typically report improvements:

ComfortEnergy ConsumptionAcoustics, quieter

and Current Building Practices…

High glazing percentages, 50-70% are normalSteel stud framing/window-wallExposed concreteExposed slab edges, balconies, and “eyebrows”Very low effective R-values

“Not so Hot” MURB Architecture

1970’s Vintage Cooling Fins, Waterloo, ON

2010 “New and Improved” Cooling Fins, Vancouver, BC

One of John & Joes Waterloo Favourites Window-Wall “Cooling Tower”

Study Buildings

68 MURBs in study55 high-rise – 10 to 33 storeys13 mid-rise – 5 to 9 storeysConstructed from 1974-2002

RDH has looked at, or worked on, each in the past –access to drawings, sites~50% have had a major building enclosure rehab in past 3-10 yearsMajority heated with electric baseboard & gas-heated ventilation air to pressurized corridors. Two have hydronic gas-heat baseboardsAll market housing condominiums, not rental apartments or social housing.Non air-conditioned

Study Buildings

Will present data from 39 MURBs today

Data from several of the initial buildings was not usable for the study

• Missing or erroneous data• Metering issues

12 years of data from 1998-2009 for each building

Electricity for suites (combined) and for common areas separately1 gas meter per building is typical

• Includes domestic hot water, make-up air units, all fireplaces (some buildings), pools (sometimes)

Total Building Energy Usage per Gross Floor Area - Sorted from Low to High

-

50

100

150

200

250

300

350

81

14

4 95

24

26

16

31

8 76

21

22

61

93

33

22

04

52

91

74

36

03

12

8 61

4 33

9 25

73

04

12

4 14

05

92

13

65

8

Building ID - Sorted from Least to Greatest Energy Intensity

Energ

y C

onsum

pti

on - k

Wh

/m2/y

r

Common Electricity

Suite Electricity

Gas

Average = 213 kWh/ m2/ yr

Median = 217 kWh/ m2/ yr

Std Dev = 42 kWh/ m2/ yr

Range = 144 to 299 kWh/ m2/ yr

Total Annual Energy Consumption Intensity

Average = 67.5 kBtu/sf/yr

Range = 45.6 to 94.8 kBtu/sf/yr

Median = 68.8 kBtu/sf/yr

Std Dev = 13.3 kBtu/sf/yr

63 k

Btu

/sf/

yr

Total Energy Consumption per Suite

Total Building Energy Usage per Gross Floor Area - Sorted from Low to High

-

5,000

10,000

15,000

20,000

25,000

30,000

35,000

40,000

45,000

50,0008

11

44 9

52

42

61

63

18 7

62

12

26

19

33

32

20

45

29

17

43

60

31

28 6

14 3

39 2

57

30

41

24 1

40

59

21

36

58

Building ID - Sorted by total building energy intesity - low to high

Energ

y C

onsum

pti

on - k

Wh/s

uit

e

Common Electricity

Suite Electricity

Gas

Average = 21,926 kWh/ suite

Median = 21,358 kWh/ suite

Std Dev = 7,130 kWh/ suite

Range = 11,566 to 50,611 kWh/ suite

Building 57 Has Air-conditioning & several common amenities

Space Heat Energy Usage vs Year Built

-

50

100

150

200

250

300

350

19

72

19

74

19

76

19

78

19

80

19

82

19

84

19

86

19

88

19

90

19

92

19

94

19

96

19

98

20

00

20

02

20

04

Year of Construction

Energ

y C

onsum

pti

on - k

Wh

/m2/y

r

Total Energy

Space Heat Energy

Total Energy Consumption vs Age of Building

63 k

Btu

/sf/

yr

Space Heating

With exception of hydronic heated buildings, all buildings in the study have electric resistance baseboard heaters in suitesAll buildings have ventilation air, heated by indirect gas-fired rooftop MAUs – supplied to suites using pressurized corridor approach

MAU designed air flow rate observed from 30 cfm/suite in the 1980s to greater than 120-150 cfm/suite in recent yearsDesigned for 60-65F, however set at 68-74F by strata’s to reduce complaints of cold drafts

Some buildings have gas fireplaces (in some or all suites) in addition to electric baseboards & MAU

Distribution of Purchased Space Heat Energy

% of Total Building Energy Used for Space Heat

0%

10%

20%

30%

40%

50%

60%

26 18 11 6 1

57 2 7

43 21

32

61

52 14 24

59

44 17 29

42

40

30 31

41

20

28

62

45

60

33

19 36

58 12 39 3 8

63 9

Building ID

% T

ota

l Energ

y W

hic

h is H

eat

Electrical Heat

Gas Heat

Average 37% of total building energy is

used for heat

Of this portion an average of 69% of

this energy is from gas

% Total Building Heat which is Gas

0%

20%

40%

60%

80%

100%

11

42

62

61

44 6

18

17

43 7

28

40

29

32 1 2

57

26 8

33

14

31 3

59

30

52

63

60 9

20

39

12

24

41

21

58

45

36

19

% S

pace

Heat fr

om

Gas

Average of 69%, Majority of Space-Heat

Energy from Gas Sources

Hydronic Gas Heat

MURBs with fireplaces in

majority of suites

Percentage of Purchased Space-Heat from Gas Sources

% of Total Building Energy Used for Space Heat

-

20

40

60

80

100

120

140

160

19

74

19

75

19

81

19

84

19

85

19

85

19

85

19

86

19

87

19

89

19

90

19

90

19

90

19

90

19

92

19

92

19

92

19

93

19

93

19

93

19

94

19

94

19

94

19

94

19

94

19

95

19

95

19

95

19

95

19

95

19

96

19

96

19

96

19

97

19

97

20

01

20

01

20

02

20

02

Year of Construction

Space

Heat Energ

y C

onsum

ed

- k

Wh/m

2/y

r Gas MAU or Fireplace Space Heat

Electric Resistance Space Heat

Type of Space heat versus Age of Building

% of Total Building Energy Used for Space Heat

-

20

40

60

80

100

120

140

160

19

74

19

75

19

81

19

84

19

85

19

85

19

85

19

86

19

87

19

89

19

90

19

90

19

90

19

90

19

92

19

92

19

92

19

93

19

93

19

93

19

94

19

94

19

94

19

94

19

94

19

95

19

95

19

95

19

95

19

95

19

96

19

96

19

96

19

97

19

97

20

01

20

01

20

02

20

02

Year of Construction

Space

Heat Energ

y C

onsum

ed

- k

Wh/m

2/y

r Gas MAU or Fireplace Space Heat

Electric Resistance Space Heat

Electric Space Heat Trend

Gas Space Heat Trend

Impact of Make-up Air Unit Flow Rate on Space Heat

Influence of Gas Fireplaces and MAU on Electric HeatGas and Electric Space Heat Use

0

20

40

60

80

100

120

140

160

30% 40% 50% 60% 70% 80% 90% 100%

Percent of Total Space Heat Energy which is Gas

Gas a

nd

Ele

ctri

c S

pace H

eat En

erg

y k

Wh

/m2/y

r

Electric Space Heat

Gas Space Heat

Total Space Heat

Gas Space Heat Trend

Electric Space Heat Trend

hydronic

buildings

Buildings without Gas Fireplaces Buildings with Gas Fireplaces

Space Heat Efficiency & Total Energy ConsumptionWhole Building Energy Consumption vs Space Heat Energy Consumption

0

20

40

60

80

100

120

140

160

100 120 140 160 180 200 220 240 260 280 300

Total Whole Building Energy Consumption - kWh/ m2/ yr

Tota

l S

pace

Heat Energ

y C

onsum

pti

on - k

Wh/m

2/y

r

2 to 3.5 x more heat used

Range of more efficient buildings

Average high-rise MURB (67.5 kBtu/sf/yr)49% of Energy is Electricity (32.4 kBtu/sf/yr)

• 57% of Electricity is used in Suites – 38% is used for electric baseboard heating– 62% is used for appliances, lighting, electronics etc

• 43% of Electricity is used in Common Areas– Elevator, Lighting, HVAC distribution,

ventilation, plumbing, fans, pumps etc.

51% of Energy is Gas (35.2 kBtu/sf/yr)• 51% is used for Ventilation Air (MAU) heating

and fireplaces (where provided)• 49% is used for domestic hot-water

37% of Total Energy is for Space Heat

Where does the energy go?

22% Heat

Other

Electricity

51% Heat

OtherGas

Average 280 Tons CO2/yr in BC

Operating Energy Costs

Whole Building (Average):

$128,000 per Year (Range$27,000 to $260,000)

$1.07/sqft floor area/year

$49,000 Gas

$79,000 Electricity

Per Suite (Average):

$1,200 (Range of $700 to $3000 per year)

Occupants Pay for Suite Electricity Individually – see bills monthlyCommon Electricity and Gas is paid by Strata (HOA)

Paid by occupants through monthly strata fees of $100-400+/month Occupants do not typically see complete energy bills, or understand what for

Average MURB Energy Cost Distribution28% Suite Electricity Energy = $408/yr (Occupant Paid)21% Common Area Electricity = $323/yr (Strata Paid)51% Gas Heat and Hot water = $455/yr (Strata Paid)

Only 36% of Total Energy Cost is Directly Paid by Occupant

69% of Building Space Heat is from Gas (Paid by Strata):Occupants are only directly paying for 31% of space heating costNeed to address this disconnect to become more energy efficient

Disconnect Between Consumption and Billing

Common Gas & Elec.

Suite Elec.

The Impacts of Building Enclosure Rehabilitations

Results from 4 buildings presented here todayEnclosure rehabilitations to address water leakage Various window types & claddingsEnergy improvements were unfortunately not a primary consideration when designing rehabilitations

Detailed R-value Calculations

Pre- & Post-Rehabilitation R-values to assess space-heat savingsCalculated U-values for every detail of each wall, roof, window assemblyCalculated area-weighted U-values using detailed areas from sketch-up

PRE R-2.92 POST R-4.26

Building 19 – Pre Rehabilitation

Building 19 – Post Rehabilitation

Building 19 – Pre & Post Rehabilitation R-values

Pre Rehabilitation Post Rehabilitation Building #19 Pre and Post R-value

Improvement Assembly Description R-value Assembly Description R-value

Walls (52% of enclosure):

Steel Stud w/ R-14 fiberglass.

Slab edges un-insulated,

balconies 3.9

Walls:

Exterior insulated, R-9.5 mineral

wool between steel z-girts. No

stud cavity insulation. Slab

edge insulated, balconies

uninsulated.

5.3

Windows ( 27% of enclosure,

34% of wall area):

Non-thermally broken

aluminum frames. Clear glass,

air filled IGUs with aluminum

spacers

1.37

Windows:

High performance thermally

broken aluminum frames. Soft-

coat low-e, air filled IGUs with

aluminum spacers

2.16

Roof (21% of enclosure):

Inverted assemblies with 3”

extruded polystyrene

14.3

Roof:

Inverted assemblies with 4”

extruded polystyrene.

18.3

Overall Building 2.92 Overall Building 4.26

Rehabilitation improved R-value by 46% (31% reduction in U-value)

Rehabilitation Resulted in a Space-Heat Savings of Approximately 10%

Building 62 – Pre and Post-Rehabiliation R-values

Pre Rehabilitation Post Rehabilitation Building #62 Pre and Post R-value

Improvement Assembly Description R-value Assembly Description R-value

Walls (47% of enclosure):

Steel Stud w/ R-12 fiberglass.

Exposed concrete. Slab edges

un-insulated, balconies 3.5

Walls:

Exterior insulated, R-9.5 mineral

wool between steel z-girts. No

stud cavity insulation. Slab

edge insulated, balconies

uninsulated.

4.6

Windows ( 46% of enclosure,

50% of wall area):

Non-thermally broken

aluminum frames. Clear glass,

air filled, IGUs with aluminum

spacers

1.35

Windows:

High performance thermally

broken aluminum frames. Clear

glass, air filled IGUs with

aluminum spacers

1.67

Roof (7% of enclosure):

Inverted assemblies with 1.5”

to 2” XPS

8.2

Roof:

Inverted assemblies with 3 to

3.5” XPS. Improved detailing

12.5

Overall Building 2.07 Overall Building 2.60

Rehabilitation improved R-value by 26% (20% reduction in U-value)

Rehabilitation Resulted in a Space-Heat Savings of Approximately 22%

Building 32 – Pre- and Post-Rehabilitation R-values

Pre Rehabilitation Post Rehabilitation Building #32 & 33 Pre and Post R-

value Improvement Assembly Description R-value Assembly Description R-value

Walls (47% of enclosure):

Steel Stud w/ R-12 fiberglass.

Portions of exposed concrete.

Slab edges un-insulated,

balconies

3.8

Walls:

Exterior insulated, R-13 mineral

wool between steel z-girts. No

stud cavity insulation. 3” EIFS

over exposed concrete, slab

edges insulated, balconies

uninsulated.

7.1

Windows ( 42% of enclosure,

47% of wall area):

Non-thermally broken

aluminum frames. Clear glass,

air filled, IGUs with aluminum

spacers

1.34

Windows:

High performance thermally

broken aluminum frames. Soft-

coat low-e, air filled IGUs with

aluminum spacers

2.02

Roof (12% of enclosure):

Uninsulated sloped

assemblies, flat Inverted

assemblies with 2” XPS

10.9

Roof:

Insulated sloped assembles,

flat Inverted assemblies with 2”

XPS. Improved detailing

12.8

Overall Building 2.26 Overall Building 3.56

Rehabilitation improved R-value by 58% (37% reduction in U-value)

Rehabilitation Resulted in a Space-Heat Savings of approximately 17% to 22%

Energy Savings from Enclosure Upgrades

Space-Heat energy savings have typically been observed in billing data

Suite electricity typically reduced by a few % up to 30%In a few case, gas for MAU seemingly reduced as well

Models using DOE 2.1 code do have difficulty in predicting MURB energy consumption

Monthly Bill Calibration is required to fine-tune MAU gas and electric baseboard heatUn-calibrated models seem to be over-estimating the real energy savings… several ramifications for MURB modelingOn-going research into this

• Occupant behaviour? In-situ air-leakage rates?

Air Leakage in MURBs

MURB Airflows & Air-Leakage Difficult to predictCan measure shell air-tightness, but $$ and timelyBuilding Pressures over the course of a year difficult to determine for a suiteWhat about occupant behaviour?

Air intermittently

exhausted OUT using

bathroom/kitchen fans

Air leakage IN/OUT through

elevator and stairwell shafts

Ventilation Air IN

(Mechanical + Pressure)

Natural Air-Leakage

IN/OUT through

Enclosure

Air flow IN/OUT

through open

windowsWind Pressure

Stack Effect

Buoyancy

Pressure

Interior Air-

Leakage between

suites/common

areas/floors

Air flow IN/OUT

through entry

Impact of Whole Building Air-tightness

Air-tightness Rates from current literature provide an expected range of air-tightness rates for MURBSAdditionally, select MURBs in study were air-leakage tested post-rehabilitationCan significantly influence Space-Heat Loss

Impact of Open Windows on Effective Air-Tightness

Open windows drastically change effective air-tightness, pressure, and air-flow regimesWindows are opened to improve ventilation, reduce condensation, for fresh airBuilding 33, Enclosure Air-tightness = 0.066 cfm/ft2 (2.73 in2/100 ft2)

Enclosure Area 73,000 ft2

Equivalent hole size of 2,000 in2

One open window = 1,000 in2

One window open per floor (low estimate), 20,000 in2 (10x higher than enclosure tightness)

How does this affect energy modeling?

Key Findings

Energy Consumption of High-rise residential buildings has apparently not improved in the past 30 years Space heat energy is the most largest driver in energy consumption and hence efficiencyPrimarily gas space-heat is being used in MURBs

Somewhat surprising considering buildings are designed primarily for electric heatHeat from ventilation air is poorly distributed

• Significant energy consumed for ventilation• MAU efficiency, flow rate and distribution is important

Gas fireplaces are very inefficient and are a considerable driver in the less efficient buildings

An enclosure R-value of R-2 to R-5 is not energy efficient

Towards Energy Efficiency in MURBs

Improve Building Enclosure & address mechanical issuesThermally Efficient & “R-value Balanced” Enclosure

First Consideration = Windows• Reasonable glazing percentages • Larger the glazing area, the better the windows must be• High Performance window R-values of R-4 to R-6. Non-conductive

frames and low-e/argon double to triple IGUs

Second Consideration = Walls• Consider effective R-values of assembly choices• Minimize thermal bridging, slab edges, girts, shelf angles etc

Compliance with ASHRAE 90.1 or other energy codes

Air-tight EnclosureSuite Compartmentalization

Towards Energy Efficiency in MURBs

Effective & energy efficient ventilation strategyVentilate for health, not for heatConsider alternate ventilation methods, directly to suites (where needed instead of through corridors)Reconsider rooftop gas-fired MAU units Have already seen this successfully done in Portland MURBs…\Heat Recovery makes a lot of sense

Efficient in-suite heating, hydronic or electricAvoid gas fireplaces (unless user pays)Individual Metering and Smart controls Necessary

Bill occupants for more of what they useTurn off heat when windows open

A Few Final Thoughts

Why do we continue to design and build poor performing buildings?

Lack of consideration of end users & how they operate buildings?Lack of integration between disciplines?Inadequate minimum building code requirements?Inadequate maintenance and renewals?Value engineering?

City of Vancouver Mandate to reduce energy consumption of all buildings by 50% by 2020. Net Zero is on horizon

This should mean <100 kWh/m2/yr MURBS in 10 yearsSignificant changes in design will be required

Questions & Discussion

gfinch@rdhbe.com

Energy Unit Conversions

1 kWh/m2 = 3.155 kBtu/ft2

1 GJ = 9.48 Therms

1 GJ = 277.78 kWh

1 GJ = 0.947 mmBtu

1 kWh = 3.12 kBtu

1 kWh = 0.034 Therms

1 kBtu/ft2 = 0.317 kWh/m2

1 Therm = 0.105 GJ

1 kWh = 0.0036 kWh

1 mmBtu = 1.055 GJ

1 kBtu = 0.321 kWh

1 Therm = 29.3 kWh

Metric units from Imperial Imperial Units from Metric

Understanding Energy Use in MURBs

Parking Garage

Exhaust Fans

Parking Garage

Common Areas

PoolGas Boiler to

heat pool &

hot-tubs

Suites

Ele

vato

r S

haft

Com

mon

Hallw

ay

C

orr

idors

Sta

irw

ell

Sh

aft

Electric Baseboard

Heaters in all

Suites

Gas fireplaces in

some Suites

Air exhausted using

bathroom/ kitchen fans

& windows

Air leakage of heated

ventilation air through

elevator and stairwell shafts Ventilation air is heated

using gas-fired make-up

air unit (MUA)

Heate

d v

enti

lati

on a

ir s

up

plied

to e

ach

flo

or co

mm

on c

orr

idor (p

ressuri

zed

)

Heated

Ventilation air

from corridor

Domestic Hot

Water is heated

using Gas

Some Gas & Electric

Heat at Common Areas

Typically Unheated

Leakage o

f h

eate

d

venti

lati

on a

ir into

sh

aft

s

Rec. Areas

Building Energy Distribution

Gas

- To heat ventilation air

for make-up air supply

- To heat domestic hot water

- To heat pool/ hot-tubs

- Suite fireplaces (if equipped)

- Pilot lights for above

Electricity

Common Areas

- Interior lighting

- Elevators

- Ventilation fans and motors

- Parking garage exhaust fans

- Water distribution pumps

- Baseboard heaters

- Recreation areas/ pool pumps

- Exterior lighting

- Communication

- Controls

Suites

- Baseboard heaters

- Lighting

- Appliances

- Miscellaneous Electric Loads

- Plug loads

- Exhaust fans

Enclosure air-

leakage

Air flow through

open windows

Elevator pumping

Effect of Window Area on Overall Building R-value

Monthly Energy Consumption Comparison

0

20,000

40,000

60,000

80,000

100,000

120,000

140,000

160,000

180,000

200,000

Aug-9

8

Dec-

98

Apr-

99

Aug-9

9

Dec-

99

Apr-

00

Aug-0

0

Dec-

00

Apr-

01

Aug-0

1

Dec-

01

Apr-

02

Aug-0

2

Dec-

02

Apr-

03

Aug-0

3

Dec-

03

Apr-

04

Aug-0

4

Dec-

04

Apr-

05

Aug-0

5

Dec-

05

Apr-

06

En

erg

y C

on

su

mp

tio

n -

kw

hr/

mo

nth

Gas

Electricity - Suites

Electricity - Common

Total

Rehabilitation –Ignore Data

Gas-Data missing, ignore years data

We typically see reduced gas/increased electricity

Pre-Upgrade Post-Upgrade

Data Analysis

Typical Monthly Consumption – Typical Building

Mont hl y Ener gy Consumpt ion Compar ison

0

20,000

40,000

60,000

80,000

100,000

120,000

140,000

160,000

180,000

Au

g-0

2

Sep-0

2

Oct-0

2

No

v-0

2

Dec-0

2

Jan

-03

Feb

-03

Mar-0

3

Apr-0

3

May-0

3

Jun

-03

Jul-

03

Au

g-0

3

Sep-0

3

Oct-0

3

No

v-0

3

Dec-0

3

Jan

-04

Feb

-04

Mar-0

4

Apr-0

4

May-0

4

Jun

-04

Jul-

04

En

erg

y C

on

su

mptio

n -

kw

hr/m

on

th

Gas

El ect r icit y - Suit es

El ect r icit y - Common

Baseline Gas – No Space Heat

Baseline Suite Electricity – No Space Heat

Estimate Space heat from monthly minus baseline

value

Thermal Anatomy 101 – Multi-Family High-rise

R-12 Insulation in steel-stud wallsR-5 accounting for steel studs

R-20 Roof InsulationR-1.8 Windows, 60% Wall Area

Aluminum window wall, hard-coat low-e, air fill

U-overall = 1/5 * 0.38 + 1/20 * 0.06 + 1/1.8 * 0.56

= 0.39 --> R-overall =2.6 80% Heat Loss through windows

240 suites, 180,000 sq.ft.Envelope area = 38% walls, 6% roof, 56% windows