Feras Essam Balkhi by LESS Studio

INDOOR AIR QUALITY, MITIGATING CO2 CONCENTRATION IN CLASSROOMS USING ADJACENT CORRIDORS AND ATRIUMS FERAS ESSAM MOHAMMED BALKHI

Master of Architecture (Second semester) Supervisor: 1Dr. Mustafa Sabbagh, 2Dr-ing. Mohannad Bayoumi

Department of Architecture (KAUARCH) Faculty of Architecture and planning King Abdulaziz University

CONTENT 01. INTRODUCTION 1.1 Problem statement 1.2 Objective 1.3 Literature review 1.3.1 IAQ in classrooms 1.3.2 Standards for CO2 concentration 02. METODOLOGY 2.1 Study method 2.2 Field measurment 03. ANALYSIS 3.1 Maintaining Thermal Comfort study 3.2 CO2 study 3.2.1 Validation 04. MODELING 4.1 Occupants densities in the classroom 4.2 Simplifying the study case 4.3 Occupancy schedule 4.3.1 Results 4.4 Applying the air exchange 4.6 Comparing scenarios 05. CONCLUSION 5.1 Conclusion and Recommendations 06. REFERENCES 02

01. INTRODUCTION

1.1 Problem statement 1.2 Objective 1.3 Literature review 1.3.1 IAQ in classrooms 1.3.2 Standards for CO2 concentration

01. INTRODUCTION

1.1 Problem statement Indoor air quality (IAQ) is an essential factor that decides occupantsâ&#x20AC;&#x2122; level of satisfaction and performance. Classroom are more critical due to typically high occupancy density. The over-crowdedness of classroom is a serious and quite common issue.

Can be studying to find approach using the total air supply entering the building of Constant Air Volume (CAV) system, reducing CO2 concentration in classrooms, without affecting the thermal comfort ?

The larger the classroom, the greater the dilution of levels of carbon dioxide (CO2) and pollutants, and the longer good air quality can be maintained. In an average size classroom with a volume of 181 cubic meters, 30 occupants and no ventilation, the air quality becomes poor in just 30 minutes [1].

1.2 Objective

This paper aims to test the viability of air exchanging between the classrooms and other adjacent indoor spaces, to enhance the overall levels of CO2 concentration, as a quick solution for an overcrowded classrooms.

Ventilation can be the most important factor affecting IAQ, as confined air in closed space without renewal can be contaminated by several pollutants, including: Radon, CO2, carbon dioxide, bacteria and other volatile chemical particles [3]. Occupants are the main indoor source of CO2. The CO2 is easy to measure as a surrogate for indoor pollutants. Indoor CO2 levels are a good indicator of ventilation efficiency witch directly indicate to the quality of the indoor air [3].

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 01. INTRODUCTION

01. INTRODUCTION 1.3 Literature review

1.3.1 IAQ in classrooms

Classrooms has a large occupancy density. Where classroom occupants, on daily bases spend most of there active day within it. This space creating an interactive and educational environment that must be reviewed and assessed by the IAQ conditions. In particular, the greater number of occupants with one unchanged space, which leads to the classroom spaces.

Thermal comfort affecting CO2 concentration in classrooms

Several studies indicated CO2 as a factor of evaluation for air quality in space. Maintaining the temperature and relative humidity as effects of CO2 concentration. The correlated with relevant environmental parameters is humidity, radiant temperature, air velocity. CO2 concentrations and temperatures are important factors within buildings, it's affecting the occupant performance and particularly cognitive performance regarding all mental activities such as thinking, reasoning, and remembering [4]. The evaluating of CO2 concentrations as indicator of air quality, maintaining temperature, and relative humidity are the common and related factors that affect the IAQ in the classrooms.

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 01. INTRODUCTION

01. INTRODUCTION 1.3 Literature review

1.3.1 IAQ in classrooms Bad IAQ influences on occupants in classrooms

IAQ in schools is often very low. and the indoor air pollutants have an impact on occupants' health, comfort, and productivity [5].

Building-related symptoms were significantly and positively associated with the concentration of colony-forming units of molds in floor dust: eye irritation, throat irritation, headache, concentration problems, and dizziness [7]. Investigations have proven the effectiveness of evaluating and improving IAQ may enhance the educational space and the Comprehension of students. Decreasing classrooms’ temperature from 25°C to 23°C, and also increasing temperature from 20°C to 23°C whilst decreasing CO2 levels from 1800 ppm and/or 1000 ppm to 600 ppm significantly improved the performance of adult students in a memory and attention tasks [4].

Cold, hot and warm sensations can negatively affect mental performance for memory and attention tasks while mild cooling sensation can improve mental alertness [4]. Low rates of ventilation in classrooms significantly reduce pupils’ attention and vigilance, and negatively affect memory and concentration and the physical environment. Therefore, affects teaching and learning [6].

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 01. INTRODUCTION

01. INTRODUCTION 1.3 Literature review

1.3.1 IAQ in classrooms Importance of ventilation affecting CO2

Classrooms have a higher level above 1000 ppm. A. S. Hassan Abdallah found the reason of this problem was because teachers close the doors and depend on mechanical fans and single side ventilation from windows for ventilation without continuous airflow of fresh air. Also found CO2 level decreases during the school break in 30 minutes due to the opening door without student occupation [8]. In study showed that the energy demand in school buildings was reduced by 38% for a CO2-DCV compared with an CAV system. [9] In study, the DCV system was able to deliver and maintain a good IAQ, even at reduced air flow rates. The VAV dampers or extract fans respond well to predefined set points of CO2 concentration and temperature. Even at low air flow rates, it was noticed that the ventilation efficiency was not affected. This shows that demand controlled ventilation is effective in distributing the air even at reduced air flow rates. [10]

1.3.1 Standards for CO2 concentration

CO2 levels and potential health problems are indicated below: Table 1 [11].

Concentration (ppm)

Effects

400-1000

Typical level found in occupied spaces with good air exchange

1000-2000

Complaints of drowsiness and poor air

2000-5000

Headaches, sleepiness and stagnant, poor concentration, loss of attention

5000

Workplace exposure limit (as 8-hour TWA) in most jurisdictions

40000

May lead to serious oxygen deprivation resulting in permanent brain damage, even death

Table 1, Influences of CO2 concentrations FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 01. INTRODUCTION

02. METODOLOGY

2.1 Study method 2.2 Study structure 2.3 Field measurment

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 02. METHODOLOGY

02. METHODOLOGY 2.1 Study method

This study investigates a prototype classroom building in Jeddah, as case study. The study involved maintaining the thermal comfort and evaluating CO2 concentration. The case windows condition is not designed with natural ventilation systems (no opining windows). In set of mechanically air-conditioned space using CAV system. Study simulating a combined approach by exchanging the air-conditioned adjacent common spaces (i.e. corridors and atriums) with the classrooms. Also, should not ignore the over crowdedness issue of classrooms, by reconsidering the occupancy schedule and number of occupants, which causes a high level of CO2 concentration. The reason of high CO2 concentrations was the low intensity of ventilation and a high number of occupants during the lecture time in one closed space [7].

Selecting and study one classroom as a case sample. Using the field measurement devices will set up the device in the middle of the classroom with a height of 1.1m for the level of the occupants breathe, to evaluate the IAQ of the space. The measuring device used to evaluate the relative humidity and temperature of the study sample to calculate the thermal comfort effect. Validate using the collected data. Field observations such as space dimensions and occupantsâ&#x20AC;&#x2122; number of the space to get the full current condition of the case sample. Maintaining thermal comfort. Then, simulating CO2 as an indicator of air quality, occupancy density, and mechanical system type, using software (IDA ICE). Reviewing the occupants densities and typical scheduling of the classrooms. Studying and applying the occupancy scheduling of adjacent spaces to simulate the study case. Discussing influences of any change may cause by one classroom to reach a quick solution of space efficiency with the lowest potential losses of change space. Then comparing the scenarios and results. aiming to upgrade the IAQ of space in Saudi Arabia classrooms to confirm the findings and scale the problem size which may lead to new policy and refurbishment of schools.

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 02. METHODOLOGY

02. METHODOLOGY 2.2 Study structure

Evaluate CO2

Validation

Classroom Occupants

Applying

Schedule Results

Selecting sample

Current condition

Modeling and siumaltion

Suggested solution Scenarios

Measurement

Maintaining thermal comfort

Research sample

Simplifying

Conclusion and Recommendations

Schedule

Corridors and atriums

Comparing

Analyze

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 02. METHODOLOGY

Findings

02. METHODOLOGY

2.3 Field measurment Installing CO2 sensors as a parameter of the IAQ condition in the classroom. Also, promoted conscious ventilation in each classroom by involving the teachers to manage the manual airing and suggests frequent and short periods of window openings [9]. Measurements devices were installed in one of the buildings of the current preparatory year in educational classroom to measure the IAQ using (HOBO onset data logger U10-003) Specific for measure CO2 concentration in air, temperature and relative humidity of these enclosed spaces as shown in the drawing. The designed occupation capacity of the classroom is 40 occupants (Figure 1). Monitoring in more than one period depending on the space condition in terms of use. Install accurate measuring devices that detect and record measurements of temperature and relative humidity within the case sample (Figure 2,3,4).

Figure 1, Field measurment

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 02. METHODOLOGY

02. METHODOLOGY 2.3 Study tools

MEASUREMENT

SIMULATION

HOBO onset data logger U10-003

IDA ICE

Specific for measure CO2 concentration in air, temperature and relative humidity

Measurements devices were installed in one of the buildings of the current preparatory year (No.535) in educational classroom to measure the quality determinants of these enclosed spaces as shown in the drawings. The variables were monitored in more than one period depending on the space condition in terms of use.

IDA Indoor Climate and Energy (IDA ICE) is a Building performance simulation (BPS) software. IDA ICE is a simulation application for the multi-zonal and dynamic study of indoor climate phenomenas as well as energy use. The implemented models are state of the art, many studies show that simulation results and measured data compare well.

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 02. METHODOLOGY

02. METHODOLOGY

2.3 Field measurment

1.06 m

9.14 m

1.06 m

7.50 m

Figure 3, Classroom plan MEASUREMENT TOOL SPOT HEIGHT 1.10 m

3.00 m

Figure 2, Case sample (classroom) Space volume: 205.5 m3

Figure 4, Classroom section

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 02. METHODOLOGY

03. ANALYSIS

3.1 Thermal Comfort study 3.2 CO2 study 3.2.1 Validation

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 03. ANALYSIS

03. ANALYSIS

3.1 Thermal comfort study The two most important variables affecting the thermal comfort in the classroom is temperature and relative humidity. The data average readings were shown on the Psychrometric chart to determine whether the results were within the range of thermal comfort zone or not. As shown in the diagram (Figure 5), data average is placed in the comfort zone.

Relativ e humidity (%)100

Absolute humidity (kg/kg) 50 40

0.0550

0.0500

40 0.0450

Data average

0.0400

Temperature: 22.25 C Relative humidity: 66.5% o

0.0350 20

Data taken at 2019.Oct.13

0.0300

Dry bulb temperature Absolute humidity Relative humidity Wet bulb temperature Comfort zone

COMFORT ZONE

0.0250

DATA AVERAGE

0.0200

25 10

0.0150 20

0.0100

15 10

0.0050

5 0

Wet bulb temperature (Â°C) -10 -40 -35 -30 Dry bulb temperature (Â°C)

-25

-20

-15

-10

-5 -5

0.0000

Figure 5, Psychrometric chart of the classroom

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 03. ANALYSIS

03. ANALYSIS

3.1 Maintaining thermal comfort study

1.06 m

9.14 m

1.06 m

7.50 m

Figure 7, Classroom exterior edge plan

Figure 6, Classroom exterior edge

Because of the hot climate of Jeddah, the exterior edge facade of the classroom is exposed to high temperatures that may affect the indoor thermal comfort (Figure 6,7) The study trying to find a quick solution without effecting the thermal comfort in classrooms. Considering this condition rate maintained and not negatively affected, as it is related to CO2, which may affect the study solutions.

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 03. ANALYSIS

03. ANALYSIS

3.2 CO2 Study

CO2 monitored in two different days, one on a day off and the other due workday where occupants are in the classroom. According to the typical scheduling of the classroom, it is divided into two periods. The first period has the general studying subjects, which contains a larger number of occupancy and almost getting to the full capacity of the classroom. And its starting from 8:00 a.m. until 12:00 p.m. The chart shows a high increase in CO2 concentrations in the lecture due to the classroom. Consequently, CO2 emissions due to studentâ&#x20AC;&#x2122;s congestion increase to a concentration level of 1270 ppm (Table 2), which is above the standard. Although the accumulation of CO2 in the last few hours, the second period comes after one hour of lunch break with no occupancy inside the classroom. Therefore, the chart showing a drop in CO2 concentration. Continuously, Starting the second period at 13:00 p.m., until 16:00 p.m. This period has specialized subject courses, which contains less number of occupancy than the morning period. Clearly, the chart showing a good continuous result of the evening period. Because of the low number occupancy which often being less than the space half design capacity (Figure 4).

MAX

AVG

MED

MIN

1270

855

890

434

Table 2, CO2 Measurements data due workday

Starting PEAK 9:50 am. 1270 ppm 10:30 am.

1400

End 12:00 am.

CO2 CONCENTRATION (ppm)

ppm

1200 ppm

1000 ppm

800 ppm

600 ppm

400 ppm

200 ppm

:0 0

ppm

DAY TIME CLASS OFF

CO2 STANDARD

WORKDAY CO2 LEVEL

DAYOFF CO2 LEVEL

Figure 8, CO2 Concentration FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 03. ANALYSIS

03. ANALYSIS

3.2.1 Validation Depending on the typical schedule of the classroom and using the lowest point as zero occupancies, it found that the line reaches the peak point with an of 34 occupancies. Also, the evening period is getting in between 23-26 occupants in the classroom. caused by a lower number of occupancy than the designed space capacity. It leads to the designed space capacity that does not match 40 occupants per classroom as it designed. Taking the measurements and comparing them with the simulation result measurements from the simulation program while entering the same values of the timing and duration of the break times and the number of occupants. A slight difference in the results of the measurements does not exceed -2.75% or +2.75% as a margin of error between the reality and the simulations (Figure 9). 1800 ppm 1600 ppm 1400 ppm 1200 ppm 1000 ppm 800 ppm 600 ppm 400 ppm 200 ppm

Field measurment

Validation

Figure 9, Validation FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 03. ANALYSIS

04. MODELING

4.1 Occupants densities in the classroom 4.2 Simplifying the study case 4.3 Occupancy schedule 4.3.1 Results 4.4 Evaluating the current condition CO2 concentrations 4.5 Applying the air exchange 4.6 Comparing scenarios

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 04. MODELING

04. MODELING

4.1 Occupants densities in the classroom

9.14 m

4.1 A

1.06 m

7.50 m

According to the standard, in the simulation the occupants number was reduced to 30 occupants in the classroom to fits the designed space. A good decrease in the CO2 concentration level by 12.5% can make a good help to reduce the CO2 concentration in classroom. (Figure 11)

1.06 m

CO2 concentration can be reduced by reducing the number of occupants in the classroom. The large number of occupants in one closed space such as the classroom, increases the rates of CO2 concentration. This classroom contains a high number of occupants above the standard by 40 occupancies for 68.5m2 with furniture in rows and freely arranged. Each occupant needs a space of 1.8 - 2.0 m2 in the classroom [12]. (Figure 10)

Students: 30 - Area: 68.5

Figure 11, Occupants in classroom

1600 ppm

1400 ppm

1200 ppm

1000 ppm

800 ppm

600 ppm

400 ppm

200 ppm

Current condition (40 Occupants)

Proposed solution (30 Occupants)

Figure 10, Comparing occupants densities FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 04. MODELING

04. MODELING

Atrium zone Space volume: 5,484.8 m3

4.2 Simplifying the study case 4.2 A

Corridors zone Space volume: 1346 m3

Using Simulation to simplify the study case, sizing down the space proportionality of the corridor and atrium to the classroom. By allocating a space volume form corridor and atrium for each classroom (Figure 12,13,15). The classroom space was filled with the same number of occupants of this space under the real circumstances and opining all the three spaces classroom, corridor and, atrium to each other. As a result, the simulation shows the decrease in the concentration of CO2 reaches 946.23 ppm at its highest point (Figure 14). In this case, it is a priority to reconsider the proportionality between these areas by increasing the classroom space or reducing the adjacent spaces. That is a costly solution that may lead to a redesign of the built spaces or to find another quick solution.

Figure 12, Space volume allocating 01

Classroom zone Space volume: 205.5 m3

Classroom zone Space volume: 210 m3

PEAK 946.23 ppm 10:20 am.

1400 1200

Atrium zone Space volume: 52.67 m3

1000 800

Corridors zone Space volume: 51.77 m3

600 400 200

CO2 standard

Field measurment

SimpliďŹ ed the study case

Figure 14, CO2 Concentration in allocated classroom

Figure 13, Space volume allocating 02

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 04. MODELING

04. MODELING

4.2 Simplifying the study case 4.2 B

PEAK 946.23 ppm 10:20 am.

1400

03 Atrium

Classroom open to atrium Classroom open to corridor

PEAK 793.50 ppm 15:00 am.

1200 1000 800

Corridor

600 400 200

CO2 standard

Field measurment

Classroom open to atrium

Figure 15, Floor spaces allocating

Classroom open to corridor

Figure 14, CO2 Concentration in allocated classroom

FERAS ESSAM BALKHI - IAQ, Mitigating CO2 concentration in classrooms using adjacent corridors and atriums - 04. MODELING

04. MODELING

4.3 Occupancy schedule

CURRENT CONDETION

4.3 B

First semester 2020 - Student classes schedule

A. Classroom schedule

According to the typical scheduling of the classroom (Figure 16), it is divided into two periods. The first period has the general studying subjects, which contains a larger number of occupancy and almost getting to the full capacity of the classroom. And its starting from 8:00 a.m. until 12:00 p.m. The last few hours, the second period comes after one hour of lunch break with no occupancy inside the classroom. (Figure 17)

Figure 16, Typical classroom schedule

Occupancy time Without occupancies

Classrooms schedule 10 min. break DURING WORKDAY

60Min.

50Min.

OFF