Simulation And On-Site Measurement Methods To Study Thermal Performance Of Rural Mud Hut In Humid Sub-Tropical Climate: A Case-Study In Jharkhand, India

DOI : 10.17577/IJERTV2IS60565

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Simulation And On-Site Measurement Methods To Study Thermal Performance Of Rural Mud Hut In Humid Sub-Tropical Climate: A Case-Study In Jharkhand, India

Authors:

Janmejoy Gupta(1), Dr Manjari Chakraborty(2)

  1. Assistant Professor, Department of Architecture, Birla Institute of Technology, Mesra, Ranchi, Jharkhand. Pin: 835215.

  2. Professor & Head Of Department, Department of Architecture, Birla Institute of Technology, Mesra, Ranchi, Jharkhand, Pin: 835215.

Corresponding Author: Janmejoy Gupta

Abstract:

The existing realities of the mud house with respect to its ability to providing thermal comfort to occupants are studied. How the areas in which thermal performance is unsatisfactory and can be improved has been suggested. Various parameters have been considered in the study of the existing mud house like roof and wall insulation, direct and indirect heat gain, ventilation, and orientation. As a tool for studying the thermal comfort conditions inside the mud house and in order to simulate different thermal conditions, the software Autodesk Ecotect Analysis is used. The different sources of heat gain during summer and heat loss during winter are pinpointed through detailed analysis. On-site measurements are used to validate building simulation results and to draw some inferences about thermal behaviour of dwelling units.

Keywords: mud-house, thermal-performance, Simulation.

    1. Typical Existing Vernacular Mud Huts in Jharkhand in rural and suburban areas

    2. Size & Layout

      Since the Iron Age, Jharkhand has been a land of thirty different tribes on the Chotanagpur plateau. Before British colonization in 1870, Jharkhand had an agrarian society. Huts made of mud walls and thatched roofs were the standard construction. Along with a thermally- responsive construction, the architecture of Jharkhand also responded to interactive social life by creating community courtyards. (Das & Pushplata, 2005).

      An average hut measured approximately 5 to 6 meters (15 to 18 feet) long and 3 to 4 meters (10 to 12 feet) wide (Dhar, 1992). The huts vary in size. There are also a considerable number of larger huts that extend up to 12 to 14 meters in length and 8 to 9 meters in width. The walls are usually thick ranging between 450 mm-500 mm. (Figure 1)

      These huts are arranged in a linear pattern along the main street of a village, usually amidst a group of bamboo trees. The houses are normally surrounded by a fence made of bamboo,

      shrubs, or twigs that defined the boundary between the public street and the semi-public courtyard area in front and at the rear of the hut. This open-to-sky courtyard acts as a prime space for the house, especially during the day in winter and in the evenings in summer.

      The Cob method & Wattle and Daub method is the most commonly used in Jharkhand huts. The huts were made of local materials. Timber, bamboo, clay, straw, cow dung, and a special variety of grass were used to build houses (Dhar, 1992). The walls were made of a special type of mud obtained by souring earth by adding vegetable waste and leaving it to mature. The decaying waste produced tannic acid and other organic colloids, greatly improving the muds plasticity (Cooper & Dawson, 1998). This mud was then mixed with cow dung, chopped straw, and gravel or stones to make the raw material for the walls to improve its tensile strength. The pitched roofs are made of burnt clay tiles.

      In the Middle East fibrous ingredients like straw are used to improve tensile strength of mud bricks. Binici et al (2007) investigated the thermal isolation and mechanical properties of fibre reinforced mud bricks as wall materials. The fibre reinforced mud bricks fulfil the tensile strength, compressive strength and heat conductivity requirements of the ASTM (American Society for Testing & Materials) standards. Further, as per Binicis study, Mud bricks with plastic fibres showed a higher compressive strength than those with straw, polystyrene and without any fibres. Basaltic pumice as an ingredient was found to decrease the thermal conductivity coefficient of fibre reinforced mud bricks.

      Figure 1: Mud wall with wooden-posts of typical hut plan & detail (Reproduced from Dhar, 1992)

    3. Studied Hut

The studied hut is located in Mesra village, 16 kms from Ranchi, the capital of Jharkhand, a state in eastern India located on the Chota Nagpur plateau region. It is a state which is rich in its forest and mineral resources. In fact, the word Jharkhand in Sanskrit means the Land of Forest bushes. Ranchi has a Sub-Tropical Humid type of climate as per Koppens Classification of Indian Climates. (Figure 2)The external mud walls of the studied hut are 450 mm and the internal walls are 250 mm. The studied mud house has its longer side oriented along East-West Axis. The two doors are placed in the northern side. The two small void like openings are placed on the southern wall. It measures 14 meters in length by 8 meters in breadth. (Figures 3 & 4) Mesra, (near Ranchi) lies at latitude of 23.4 degrees north and the longitude passing through it measures 85.3 degrees east. Ranchi has a hot summer

(April, May, and June), monsoon with heavy rains (July-September), moderate autumn (October), moderate spring (March) and cold to very cold winter (November, December, January and February.)

Figure 2: Climatic Zones of India by Koppen (Source: www.ijlct.oxfordjournals.org)

Days are hot, and nights are cool in summer; heavy rains occur during monsoon; and in winter, both days and nights are cold.

According to Brown and DeKay (2001), the main strategies to create comfort in this climate include:

Summers:

Use evaporative cooling.

Protect against summer heat gain.

Keep the sun out in summers to reduce heat gain and glare.

Flatten day-to-night temperature swings to reduce cooling in summers. Use vegetative cover to prevent reflected radiation and glare.

Expand use of outdoor spaces during the night. Night time flush ventilation to cool thermal mass.

Winter:

Let the winter sun in to reduce heating needs. Protect from cool winter winds to reduce heating. Expand use of outdoor spaces during the day.

Spring:

Use natural ventilation to cool in spring.

view

N

N

Figure 3: Studied Hut (clockwise from top left: front elevation, view, plan, side elevation & wire-frame model)

Figure 4: Photographs of the studied hut (Photographs by Author)

The Model House under study has been divided into two zones the north-zone (ZONE 2) and the south zone (ZONE 1) for more specific study. Also, for further detailed study, one room in the south zone, which is used as a sleeping room at night, is subjected to further detailed study to analyse its thermal behaviour. (Figure 5)

* blue region shows south zone room.

Figure 5: Demarcating south and north zones.

    1. On-site measurements

      The on-site temperatures inside the mud house are taken, on one of the hottest days, one of the coldest days and one of the windiest days. This is done to validate simulation results and to study the thermal conditions inside the dwelling unit.

      The room chosen for taking temperatures is the sleeping room in the south zone of the hut.

      Fig 6a Fig 6b

      Figure 6a: Raytek Gun. (Source: www.lasertools.com.au/images/raytekmt6.jpg)

      Figure 6b: Magnetic Compass

    2. Raytek handheld infrared thermometer :

      A Raytekthermometer (see Figure 6a) was used to record temperature instantaneously on different surfaces.

    3. Magnetic compass:

      Orientation of the house under investigation was identified. A magnetic compass corrected for declination was used to determine the orientation of the building. (Figure 6b)

    4. Temperatures taken during one of the hottest days of the year:

      In South Zone Room. (inside hottest period)

      Table 1: Hourly Inside and OutsideTemperatures measured in south zone room,29th May

      ANALYSIS: In summer, inside remains cooler than outside during day-time, after 8 AM in the morning. This can be attributed to thermal time-lag of heat-conductivity of mud. The mud stores the heat gained during day-time and dissipates it gradually after 8 PM at night, after getting heated from 7 AM to 5 PM in summer (with peak heat gain during 10 AM in the morning to 4 PM in late afternoon), thereby demonstrating a thermal lag of more than 8 hours.

      Inside Temperature is less than outside temperature from 8 AM in the morning to 7 PM at night during summer.

      KEY OBSERVATIONS: Mean temperature inside the hut during summer which remains at constant between 34.7 to 34.9 degrees Celsius needs to be decreased for better thermal comfort inside.

      The above data taken matches with the simulation results derived from Ecotect Software for the same room on 29th May.

      NOTE:

      Values sh

      own are e

      nvironm

      ent tempe

      ratures, n

      ot air te

      mperature

      s.

      NOTE:

      Values sh

      own are e

      nvironm

      ent tempe

      ratures, n

      ot air te

      mperature

      s.

      C HOURLY TEMPERATURES – ïIP)È ð Âu ¡¾uìK Tuesday 29th May (149) – Ranchi Jh IND, WMO#=ISHRAE W/ m2

      40 2.0k

      30 1.6k

      20 1.2k

      10 0.8k

      0 0.4k

      -10 0.0k

      0 2 4 6 8 10 12 14 16 18 20 22

      Outside Temp. Beam Solar Diffuse Solar Wind Speed Zone Temp. Selected Zone

      Table 2: Ecotect simulation result : hourly temperatures : south zone room, 29th May

      HOURLY TEMPERATURES – Tuesday 29th May.

    5. Temperatures taken during one of the coldest days of the year. (in the coldest period)

      Table 3: Hourly Inside and OutsideTemperatures measured in south zone room, 4th January

      OBSERVATIONS: As seen in the summer-time case constant inside temperatures inside the room are maintained in spite of fluctuating outside temperatures. The heat stored during day is released at night in winter which offsets the dip in night temperatures outside to some extent. This is again due to the thermal lag in the conduction of heat gained in daytime by the mud walls.

      However, the temperatures inside should ideally be increased by a small amount to ensure better thermal comfort for the inhabitants of the hut.

      The above data taken matches with the simulation results derived from Ecotect Software for the same room on 4th January 2012.

      NOTE:

      Values sh

      own are e

      nvironm

      ent tempe

      ratures, n

      ot air te

      mperature

      s.

      NOTE:

      Values sh

      own are e

      nvironm

      ent tempe

      ratures, n

      ot air te

      mperature

      s.

      C HOURLY TEMPERATURES – ïIP)È ð Âu ¡¾uìK Thursday 4th January (4) – Ranchi Jh IND, WMO#=ISHRAE W/ m2

      40 2.0k

      30 1.6k

      20 1.2k

      10 0.8k

      0 0.4k

      -10 0.0k

      0 2 4 6 8 10 12 14 16 18 20 22

      Outside Temp. Beam Solar Diffuse Solar Wind Speed Zone Temp. Selected Zone

      Table 4: Ecotect Simulation Result: hourly temperatures, south zone room, 4th January.

    6. Temperature measurements taken during one of the windiest days of the year (in windiest period of the year as per past 10 years data)

HOURLY TEMPERATURES – Friday 27th July

Avg. Temperature: 24.7 C

Table 5: Hourly Inside and OutsideTemperatures measured in south zone room, 27th July

ANALYSIS & OBSERVATIONS: On data collected during the windiest day, wind speed reduces exterior temperature but not internal temperature to that extent, which remains at a

constant of near about 25 degree Celsius, about 1 degree to 2 degrees more than the outside temperature.

For ideal thermal comfort the temperature can be reduced by 1 to 2 degrees more by allowing more amount of air into the house in windy periods, which is not happening now.

Thus more of the exterior wind needs to be channelled in to the interior, necessitating more ventilation. Venturi Effect can be utilized during these high wind velocity times and otherwise too when wind velocity is average through small openings, keeping the openings closed during periods when wind movement is absent or negligible.

The typical rural huts of Jharkhand, as has been mentioned earlier incorporate cluster type of planning, so these clusters can be slightly modified to allow each individual dwelling unit to catch as much wind as possible, which can bring down summer temperatures to more comfortable levels. (Figures 7, 8, 9, 10 & 11) An air speed of 0.5m per second equates to a 3 degree drop in temperature at relative humidity of 50 per cent and a maximum DBT of 40 degree Celsius.

Figure 7: Courtyard type planning in clusters in studied hut.

Figure 8: Probable arrangement of huts in a slight variation of the already existing courtyard type planning to channelize cooling breezes in summer.

Figure 9: Venturi Effect to facilitate wind circulation inside hut. Small inlet opening, large outlet.

Figure 10: Recessed porch provides ventilation for inner area of house

Figure 11: increased airflow through the home is possible by substituting the simple box design for one with more corners in it. This will allow greater airflow through the home.

NOTE: V

alues sh

own are e

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nt tempe

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ot air te

mperature

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NOTE: V

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nt tempe

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mperature

s.

C HOURLY TEMPERATURES – ïIP)È ð Âu ¡¾uìK Friday 27th July (208) – Ranchi Jh IND, WMO#=ISHRAE W/ m2

40 2.0k

30 1.6k

20 1.2k

10 0.8k

0 0.4k

-100.0k

0 2 4 6 8 10 12 14 16 18 20 22

Outside Temp. Beam Solar Diffuse Solar Wind Speed Zone Temp. Selected Zone

Table 6: Ecotect Simulation Result: hourly temperatures, south zone room, 27th July

The above measurements taken matches with the simulation results derived from Ecotect Software for the same room on 27th July2012.

Now that on-site measurements have been taken and the results tallied with those which have resulted out of software simulation results, we need to investigate as to what exact reasons are causing the summer temperature to remain high inside, above the comfort level and what is causing the winter temperatures to remain slightly lower than the desired comfort level. Answers as to where are the exact areas where heat is been undesirably gained and lost are sought through Ecotect Software Simulation Analysis.

    1. Ecotect Software Simulation Analysis

      We begin with inter-zonal heat gains and losses. Inter-zonal heat gains and losses, refers to the heat exchange considering the inside of the dwelling unit as a zone and the outside atmospheric surroundings of the dwelling unit as another zone. A study of the inter-zonal heat gain/loss in both Zone 1 (Southern Zone) and Zone 2 (North Zone) shows the following results.

    2. Hourly Gains, Zone 1, i.e. South Zone.

      3.1.1 PEAK SUMMER CONDITION

      W HOURLY GAINS – Zone 1 Tuesday 29th May (149) – Ranchi Jh IND, WMO#=ISHRAE

      2400

      1800

      1200

      600

      0

      600

      1200

      1800

      2400

      3000

      0 2 4 6 8 10 12 14 16 18 20 22

      HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

      Table 7: Different sources of hourly heat gains,South Zone, 29th May-Ecotect Simulation

      Inter-zonal heat gain is most during 4:00 PM in late afternoon to 9 PM at night, resulting in increased temperature inside the hut, ranging from 1063 watt to a maximum of 1711 watts (at 7 PM in the evening). This needs to be rectified and roof and wall insulation improved.

      Heat gains through ventilation are another cause of substantial heat gain.

      3.1.2 AFTER ROOF INSULATION: In simulation taken after providing insulation to the roof with gyproc/glasswool/rockwool, Peak Hour Heat Gain reduces from 1711 Watts to 1187 Watts. Total heat Gain in summer reduces from 16640 Watts to 12565 Watts.

      W HOURLY GAINS – Zone 1 Tuesday 29th May (149) – Ranchi Jh IND, WMO#=ISHRAE

      1600

      1200

      800

      400

      0

      400

      800

      1200

      1600

      2000

      0 2 4 6 8 10 12 14 16 18 20 22

      HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

      Table 8: Different sources of hourly heat gains,South Zone, 27th May-Ecotect Simulation- after roof insulation.

      3.1.3 PEAK WINTER CONDITION

      W HOURLY GAINS – Zone 1 Wednesday 3rd January (3) – Ranchi Jh IND, WMO#=ISHRAE

      720

      540

      360

      180

      0

      180

      360

      540

      720

      900

      0 2 4 6 8 10 12 14 16 18 20 22

      HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

      Table 9: Hourly heat gain/loss during peak of winter-South Zone-Ecotect Simulation

      In winter, heat is lost between 1 AM at night to 2 PM in the afternoon, and a maximum heat- loss of 270 watts at 11 AM in morning.

      Ventilation heat loss is another major reason of heat loss in winter.

      1. AFTER ROOF INSULATION:

        W HOURLY GAINS – Zone 1 Thursday 4th January (4) – Ranchi Jh IND, WMO#=ISHRAE

        720

        540

        360

        180

        0

        180

        360

        540

        720

        900

        0 2 4 6 8 10 12 14 16 18 20 22

        HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

        Table 10: Hourly heat gain/loss during peak of winter after roof insulation-South Zone- Ecotect Simulation

        Heat loss in winter reduces from peak hour heat loss of 270 Watts to a maximum peak hour loss of 79 Watts.

    3. HourlyHeat Gain, Zone 2, i.e. North Zone.

      3.2.1 PEAK SUMMER CONDITION

      W HOURLY GAINS – Zone 2 Tuesday 29th May (149) – Ranchi Jh IND, WMO#=ISHRAE

      800

      600

      400

      200

      0

      200

      400

      600

      800

      1000

      0 2 4 6 8 10 12 14 16 18 20 22

      HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

      Table 11: Hourly Heat Gains-North Zone, 29th May-Ecotect Simulation

      Main sources of heat gain in north zone on a typical day in peak summer are through ventilation heat gains, building fabric/skin heat gain and inter-zonal heat gain.

      Other than roof-insulation, building skin also requires further insulation to reduce heat gain through building fabric.

      3.2.2 AFTER ROOF INSULATION:

      W HOURLY GAINS – Zone 2 Tuesday 29th May (149) – Ranchi Jh IND, WMO#=ISHRAE

      560

      420

      280

      140

      0

      140

      280

      420

      560

      700

      0 2 4 6 8 10 12 14 16 18 20 22

      HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

      Table 12: Hourly Heat Gains after roof insulation-North Zone, 29th May-Ecotect Simulation

      After Roof insulation with rockwool/glasswool/gyprock, peak hour inter-zonal heat gain comes down from 900 Watts to 481 Watts in summer on the hottest summer day (peak summer temperature day) and total diurnal heat gain through inter-zonal gains comes down from 5451 Watts to 2856 Watts.

      3.2.3 PEAK WINTER CONDITION

      W HOURLY GAINS – Zone 2 Wednesday 3rd January (3) – Ranchi Jh IND, WMO#=ISHRAE

      400

      300

      200

      100

      0

      100

      200

      300

      400

      500

      0 2 4 6 8 10 12 14 16 18 20 22

      HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

      Table 13: Hourly Heat Gains/losses -North Zone, Peak Winter-Ecotect Simulation

      Main sources of heat loss in winter are, in descending order: ventilation heat loss, inter-zonal heat loss and heat loss through building fabric/skin.

      Other than roof-insulation, building skin also requires insulation to reduce heat loss through building fabric.

      1. AFTER ROOF INSULATION –

        W HOURLY GAINS – Zone 2 Monday 1st January (1) – Ranchi Jh IND, WMO#=ISHRAE

        400

        300

        200

        100

        0

        100

        200

        300

        400

        500

        0 2 4 6 8 10 12 14 16 18 20 22

        HVAC Load Conduction SolAir Direct Solar Ventilation Internal Inter-Zonal

        Table 14: Hourly Heat Gains/losses after roof insulation -North Zone, Peak Winter-Ecotect Simulation

        Amount of Heat loss on peak winter day decreases considerably. (From peak hour heat loss of about 348 Watts to 160 Watts). (Figure 12)

        Figure 12: Probable insulation using gypsum/gyprock/glasswool in clay tiled pitched roof.

        3.2.5 Time during which Inter-zonal Heat Gain happens in South Zone

        Inter-zonal Gains – Qz – Zone 1 Ranchi Jh IND, WMO#=ISHRAE

        Hr 22

        20

        18

        16

        14

        12

        10

        08

        06

        04

        02

        Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

        Watts 1800

        1440

        1080

        720

        360

        0

        -360

        -720

        -1080

        -1440

        -1800

        Table 15: Winter-time effective inter-zonal heat gain in Zone 1, viz. South Zone

        In South Zone, peak amount of heat gain that occurs in winter is actually desirable.

        3.2.6 Time during which Inter-zonal Heat Gain occurs in Northern Zone

        700

        560

        420

        280

        140

        0

        -140

        -280

        -420

        -560

        -700

        700

        560

        420

        280

        140

        0

        -140

        -280

        -420

        -560

        -700

        Inter-zonal Gains – Qz – Zone 2 Ranchi Jh IND, WMO#=ISHRAE

        Hr 22

        20

        18

        16

        14

        12

        10

        08

        06

        04

        02

        Watts

        Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

        Table 16: Time during which Inter-Zonal heat gain occurs in Zone 2, viz. Northern Zone

        In the Northern Zone, this graph shows that inter-zonal heat gains occur at the worst possible time, afternoon and late afternoon, especially pronounced in April and May. Steps should be taken to reduce this.

        3.3 Ventilation Gains: South Zone

        Ventilation Gains – Qv – Zone 1 Ranchi Jh IND, WMO#=ISHRAE

        Hr 22

        20

        18

        16

        14

        12

        10

        08

        06

        04

        02

        Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

        Watts 390

        312

        234

        156

        78

        0

        -78

        -156

        -234

        -312

        -390

        Table 17: Ventilation Gains: South Zone

        Ventilation heat gains in South Zone are mainly from 10 AM in the morning to 5 PM in the evening from April to June. Thus, external windows need to be kept closed during this duration in the peak summer months of April, May to June.

    4. Ventilation Gains: North Zone

      Ventilation Gains – Qv – Zone 2 Ranchi Jh IND, WMO#=ISHRAE

      Hr 22

      20

      18

      16

      14

      12

      10

      08

      06

      04

      02

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

      Watts 390

      312

      234

      156

      78

      0

      -78

      -156

      -234

      -312

      -390

      Table 18: Ventilation Gains: North Zone

      Primarily in April, May and June heat gain is maximum, in between 10 AM in the morning to 4 PM in the afternoon. Windows to be closed during that time.

    5. Building Fabric Heat Gains: South Zone

      In South Zone Sleeping Room, the heat gains through building fabric are as follows:

      Fabric Gains – Qc + Qs – ïIP)È ð Âu ¡¾uìK Ranchi Jh IND, WMO#=ISHRAE

      Hr 22

      20

      18

      16

      14

      12

      10

      08

      06

      04

      02

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

      Watts 440

      352

      264

      176

      88

      0

      -88

      -176

      -264

      -352

      -440

      Table 19: Building Fabric Heat Gains: South Zone

      This shows that heat gains from the building fabric, due to both external temperatures and incident solar radiation; occur mainly from about 10 PM at night to 4 AM in morning in winter. It also shows that summer gains occur from about 10 PM at night to 3 AM in the morning in a pronounced way and throughout the day from 4 AM to 10 PM at night in a less pronounced way. This is mainly because the sun rises earlier in summer and spends longer time heating up the east wall and due to the thermal time-lag factor of mud.

    6. Indirect solar Gain: South Zone

      600

      480

      360

      240

      120

      0

      -120

      -240

      -360

      -480

      -600

      600

      480

      360

      240

      120

      0

      -120

      -240

      -360

      -480

      -600

      Indirect Solar Gains – Qs – Zone 1 Ranchi Jh IND, WMO#=ISHRAE

      Hr 22

      20

      18

      16

      14

      12

      10

      08

      06

      04

      02

      Watts

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

      Table 20: Indirect solar Gain: South Zone

      The above suggests that some form of temporary summer-time shading on the east side is required, but something that doesn't adversely affect morning winter gains. (Figure 13) Indirect solar gains can be controlled by shading the east and west walls, or by using a white colour external finish on facade.

    7. Indirect solar Gain: North Zone

      Indirect Solar Gains – Qs – Zone 2 Ranchi Jh IND, WMO#=ISHRAE

      Hr 22

      20

      18

      16

      14

      12

      10

      08

      06

      04

      02

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

      Watts 310

      248

      186

      124

      62

      0

      -62

      -124

      -186

      -248

      -310

      Table 21: Indirect solar Gain: North Zone

    8. direct solar Gain: South Zone

      110

      88

      66

      44

      22

      0

      -22

      -44

      -66

      -88

      -110

      110

      88

      66

      44

      22

      0

      -22

      -44

      -66

      -88

      -110

      Direct Solar Gains – Qg – Zone 1 Ranchi Jh IND, WMO#=ISHRAE

      Hr 22

      20

      18

      16

      14

      12

      10

      08

      06

      04

      02

      Watts

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec

      Table 22: Direct solar Gain: South Zone

      No shading on Southern walls needed. Only shading of south window with sun shade is required. South wall is contributing to winter time heating.

      Figure 13: Probable removable in winter shading options on east wall.

    9. Discomfort degree hours-measurement in terms of thermal comfort Zone 1 and Zone 2.

      kDegHr DISCOMFORT DEGREE HOURS – Zone 1 Ranchi Jh IND, WMO#=ISHRAE

      4.80

      3.60

      2.40

      1.20

      0.00

      1.20

      2.40

      3.60

      4.80

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Too Hot Too Cool

      Table 23:Discomfort degree hours-measurement in terms of thermal comfort ,Zone 1

      kDegHr DISCOMFORT DEGREE HOURS – Zone 2 Ranchi Jh IND, WMO#=ISHRAE

      4.80

      3.60

      2.40

      1.20

      0.00

      1.20

      2.40

      3.60

      4.80

      Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Too Hot Too Cool

      Table 24:Discomfort degree hours-measurement in terms of thermal comfort ,Zone 2

      Observations: Discomfort Degree Hours is more in South Zone (Zone 1) in winter than that in the North Zone, whereas discomfort degree hours is slightly more in North Zone(Zone 2) in summer than that in the South Zone. Thus it necessiates more winter heating through passive design methods in the Southern side in winter and more shading in the northern side in summer.

    10. Heat Gains Breakdown – Zone 1(summer time)

FROM: 1st April to 30th September

Wh/ m2 GAINS BREAKDOWN – Zone 1

1st April – 30th September %

47200

35.3%

35400

23600

11800

0

12.9%

14.9%

19.9%

16.9%

11800

23600

35400

100.0%

47200

59000

Apr

7th 14th 21st 28th

May

7th 14th 21st 28th

Jun

7th 14th 21st 28th

Jul

7th 14th 21st 28th

Aug

7th 14th 21st 28th

Sep

Overall Gains/ Losses

Overall Gains/ Losses

7th 14th 21st 28th

Conduction Sol-Air Direct Solar Ventilation Internal Inter-Zonal

Table 25 a: Heat Gains Breakdown South Zone, 1st April to 30th September Dwelling Unit Heat Gain:

CATEGORY GAINS

FABRIC

16.9%

SOL-AIR

19.9%

VENTILATION

14.9%

INTERNAL

12.9%

INTER-ZONAL

35.3%

Table 25 b: Heat Gains Breakdown – 1st April to 30th September (South Zone)

The above table summarizes the main causes of heat gain in summer time, out of which inter- zonal heat gain is the major heat gain. Sol-Air heat gain, heat gain through external building walls and heat gain through ventilation are other major sources of heat gain.

3.10 Heat Gains/Losses Breakdown – Zone 1(winter time)

Wh/ m2 GAINS BREAKDOWN – Zone 1

1st November – 1st March %

20800

52.4%

15600

10400

20.5%

5200

0

25.9%

5200

47.7%

Overall Gains/ Losses

Overall Gains/ Losses

10400

15600

29.0%

20800

26000

Nov

7th 14th 21st 28th

Dec

7th 14th 21st 28th

Jan

7th 14th 21st 28th

Feb

7th 14th 21st 28th

Mar

23.3%

Conduction Sol-Air Direct Solar Ventilation Internal Inter-Zonal

Table 26a: Heat Gains/Losses Breakdown- South Zone-1st November to 1st March GAINS & LOSSES BREAKDOWN – Zone 1(winter time)

FROM: 1st November to 1st March

CATEGORY

LOSSES

GAINS

FABRIC

47.7%

0.6%

SOL-AIR

0.0%

25.9%

SOLAR

0.0%

0.0%

VENTILATION

29.0%

0.6%

INTERNAL

0.0%

20.5%

INTER-ZONAL

23.3%

52.4%

Table 26b: Heat Gains/Losses Breakdown- South Zone-1st November to 1st March

In winter, Inter-Zonal Heat Gain is the primary cause of heat gain. Whereas, with respect to heat loss during winter, main heat loss is through building fabric, that is building skin. Thus to minimize winter time heat loss, it is required to properly insulate building external walls.

    1. Simulations showing the existing temperature levels in the south side sleeping room at different times.

      Figure 14a: 6 am on 5 January 14-16 degree Celsius (south side sleeping room)

      Figure 14b: 5 Jan. 12 noon 16-18 degree Celsius.

      Figure 14c: 11:45 PM, near midnight, 5 Jan- 12 degree Celsius

      Figure 14d: 17 April 12 Midnight 24-26 degrees celsius

      Figure 14e: 15 May 10 PM-32 degrees celsius

      1

      Figure 14f: July 12 Noon-32 degree Celsius

      Figure 14g: 1 oct 12 noon- 24 to 26 degree Celsius

    2. Thermal dissatisfaction percentages

Figure 15a: Thermal dissatisfaction percentages, 7 AM, 3rd January

Figure 15b: Thermal dissatisfaction percentages, 7 AM, 31ST May

Observations: In peak winter southern zone of dwelling unit more comfortable than northern zone at 7 AM in the morning.

Also, in extreme summer both parts of the house is equally uncomfortable at 7 AM in the morning.

    1. Some other general parameters based on which comfort conditions inside hut can be improved are listed below other than the specific factors identified in studied hut:

      Figure 16: Ideal orientation in Indian conditions

    2. Ideal Orientation: Ideal orientation in Indian conditions for sub-tropical /composite climatic conditions for least summer heat gain and maximum winter heat gain, along with proper ventilation is as shown in the figure with longer side aligned along north-west, south- east making an angle of 45 degrees with the east-west axis. (Figures 16 & 18)

      TEMPERATURE INSIDE= 36 DEGREE CELSIUS

      Figure 17: Ecotect software analysis of simulated study-hut Mean radiant temperature (Thermal Comfort) inside mud hut at 12 Noon, 1st June. East-West Orientation of house.

      TEMPERATURE INSIDE = 34 DEGREE CELSIUS (2 degree Celsius lesser than when oriented in East-est direction as studied hut is oriented)

      Figure 18: Ecotect software analysis of simulated study-hut Mean radiant temperature (Thermal Comfort) inside mud hut at 12 Noon, 1st June longer side orientated along NW-SE direction, at an angle of 45 degrees to the East-West Axis.

    3. Low Surface Area to Volume Ratio: In composite or sub-tropical humid type climate the S/V ratio should be as low as possible as this would minimize heat gain.

      The Surface Area to Volume Ratio can be reduced by using a domical or vaulted roof over a circular plan. A domical roof and vaulted roof would further reduce direct heat gain. A vault roof mud-house with roof made of stabilized mud blocks (composition: soil, sand, lime/cement and water) would be very helpful in creating better thermal comfort. The vault would also induce better convective air movement thereby cooling the internal space. Square building forms also result in lower Surface Area to Volume Ratio.

      The annual heating and cooling energy saving potential of a vault roof mud-house was determined as 1481 kW h/year and 1813 kW h/year respectively for New Delhi composite climate. The total mitigation of CO2 emissions due to both heating and cooling energy saving potential was determined as 5.2 metric tons/year. A vaulted roof would also increase the attic area, which can act as a thermal buffer and help in thermal insulation both during summer and winter.

      Figure 19: Improved thermal comfort in vaulted roof building with circular plan made of stabilized mud blocks (composition: soil, sand, lime/cement and water)

      Figure 20: Vaulted roof building made of stabilized mud blocks

      Source: Arvind Chel,G.N.Tiwari(2009), Case study of vault roof mud-house in India, Thermal performance and embodied energy analysis of a passive house, Energy, Volume 86, Issue 10, October.

      Figure 21: Square building forms also result in lower Surface Area to Volume Ratio.

    4. Ventilation: The portion through which cool air at night could come in at the top portion of the roof and through which warm air can go out by convective process has been blocked in this particular hut due to rain water coming inside the hut during rains. This causes lack of ventilation in summer and convective air flow at evening and night. A probable

      solution is to let the openings remain and cover them by bamboo mesh like surface to stop rain water coming in monsoons. (Figure 22 and 23)

      Figure 22: Extended Eave projection & bamboo meshing to prevent rain ingress & allow ventilation

      Figure 23: Suggested modifications for causing internal air flow

    5. Building Materials: The building material for the walls is mud and the roof material is Mangalore Tiles. The U value for mud is 3.44 W/sq m K & the U value for Mangalore Tiles is 3.1 W/sq m K.

Analysis: Though U value of Mangalore/Clay Tiles and khapra used is not that high, the insulating property of thatch is much more, as its U value is even lesser. So in summer, it keeps the inside of the hut even cooler than clay tiles do. The disadvantages associated with thatch use can be mitigated with modern day industrially improved thatch use.

Modern day thatch treated and improved industrially can also be used for mass use in rural areas, being low cost and having very good thermal properties. Thatch is a natural reed and grass which, when properly cut, dried, and installed, forms a waterproof roof. The most durable thatching material is water reed which can last up to 60 years. A water reed thatched roof, 12 inches thick at a pitch angle of 45 degrees meets the most modern insulation standards. The U-value of a properly thatched roof is 0.35 W/sq m K, which is equivalent to 4 inches of fibreglass insulation between the joists. Only in the last decade have building codes begun to demand this level of roof insulation. Yet, thatch has been providing insulation since much longer.

5.0 OUTCOMES

The Mud house studied reinforced the fact that mud as a building envelope keeps the inside of the hut cooler in summer than outside and warmer than outside in winter. However the cooling effect of these traditional mud houses can be further improved and thermal comfort conditions inside the huts improved by proper design considerations. The study brings out the following facts:

  1. Arrangement of huts in a slight variation of the already existing courtyard type planning to channelize cooling breezes in summer is required. To encourage air circulation inside the dwelling unit through venturi effect it is desirable to have small inlet opening and bigger outlet opening.

  2. Recessed porch provides ventilation for inner area of house.

  3. Increased airflow through the home is possible by substituting the simple box design for one with more corners in it. This will allow greater airflow through the home. But at the same time, care must be taken to ensure that surface-volume ratio remains relatively less. Square with corners cut in cruciform shape will work well.

  4. Proper insulation of roof causes marked decrease in heat gain in summer and heat loss in winter. Roof can be insulated using gyprock, glasswool or gypsum in clay tiled pitched roof.

  5. Shading west and east walls will reduce heat gain in summer to a large extent. Temporary summer time shading of east wall will be beneficial.

  6. No shading on Southern walls needed. Only shading of south window with sun shade is required as South wall is contributing to winter time heating.

  7. South side window opening needs to be closed in between 12 Noon and 4 PM in the afternoon during summer to reduce heat gain through ventilation as illustrated by Ecotect Simulations.

  8. Indirect solar gains can be controlled by shading the east and west walls, or by using a white colour external finish on facade.

  9. More winter heating through passive design methods in the Southern side of the dwelling unit is necessary in winter and more shading in the northern side in summer is necessary.

  10. To minimize winter time heat loss, it is required to properly insulate building external walls.

  11. Improved thermal comfort is possible in vaulted roof building with circular plan made of stabilized mud blocks (composition: soil, sand, lime/cement and water) as per Ecotect Simulation Analysis.

  12. Mean radiant temperature inside mud hut at 12 Noon on 1st June with longer side orientated along NW-SE direction, at an angle of 45 degrees to the East-West Axis is 2 degree lesser than same dwelling unit oriented along east-west axis under similar conditions as per Ecotect Simulation Analysis.

6.0 ACKNOWLEDGEMENTS

The authors wish to acknowledge help of Mr Dipon Bose (third year B.Arch student, BIT, Mesra, Ranchi) for helping carrying out measurements in mud-house.

7.0 REFERENCES

Books and Reports:

  1. Krishan Arvind, Baker Nick, Yannas Simos, Szokolay S.V. (2001), Climate Responsive Architecture A Design Handbook for Energy Efficient Buildings, Tata McGraw-Hill Publishing Company Limited, New Delhi.

  2. Olgyay Victor (1963), Design With Climate- Bioclimatic Approach to Architectural Regionalism, Van Nostrand Reinhold, New York.

  3. Majumdar Mili.(2001), Energy-Efficient Buildings In India, Tata Energy Research Institute, Ministry of Non-Conventional Energy Sources.

  4. Uthaipattrakul, Dh. (2004). Mud-house construction technique. Building the house with mud. Suan-ngarn-mena Press, Bangkok, 27-50.

  5. Final Report On Low Cost Housing Using Stabilised Mud Blocks, Submitted by: Dr. L. Dinachandra Singh, Shri Ch. Sarat Singh, Manipur Science & Technology Council, Central Jail Road, Imphal-795001.)

  6. Satish Chandra Agarwala, 1998,Architecture & Town Planning, Dhanpat Rai & Co.

  7. Shaviv, E., Yezioro, A., & Capeluto, I. G. (2001). Thermal ass and night ventilation as passive cooling design strategy. Renewable Energy, 24(3-4), 445-452.

  8. Brown, G. Z., & DeKay, M. (2001). Sun, wind & light: Architectural design strategies (2nd ed.). Ney York: John Wiley & Sons Inc.

Journal articles:

  1. Arvind Chel,G.N.Tiwari(2009), Case study of vault roof mud-house in India, Thermal performance and embodied energy analysis of a passive house , Energy, Volume 86, Issue 10, October. (An original research article) Pages 1956-1969.

  2. Garg H.P, Sawhney R.L (1989), A case study of passive houses built for three climatic conditions of India, Solar & Wind Technology, Volume 6, Issue 4.

  3. Hanifi Binici , Orhan Aksogan , Mehmet Nuri Bodur , Erhan Akca , Selim Kapur (2007)Thermal isolation and mechanical properties of fibre reinforced mud bricks as wall materials, Elseviers Science Direct, Construction And Building Materials, Volume 21, Pgs 901-906.

  4. Hanifi Binici , Orhan Aksogan , Tahir Shah (2005) Investigation of fibre reinforced mud brick as a building material, Elseviers Science Direct, Construction And Building Materials, Volume 19, Pgs 313-318.

Conference Proceedings:

  1. Janmejoy Gupta, Manjari Chakraborty (2012), Thermal Performance of Rural Architecture in Jharkhand : Case-Study of a Typical Mud House, National Conference on Emerging Trends of Energy Conservation in Buildings, CSIR-Central Building Research Institute, Uttarakhand. Pages 126-135.

  2. Das, P. & Pushplata.(2005) Tribal Architecture of Hazaribagh. Paper presented at the International Conference on Art and Architecture of East India and Bangladesh, Birla Institute of Technology, Mesra, Ranchi, India.

Student Research Dissertation:

1. Gautam Avinash(2008), Climate Responsive Vernacular Architecture: Jharkhand, India, Masters Of Science Thesis, Department of Architecture, Kansas State University, Manhattan, Kansas.

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