PARAMETER TUNING OF CLOTHING SURFACE TEMPERATURE IN THE PROCESS OF ADAPTING PREDICTED MEAN VOTE (PMV) METHOD INTO A THERMAL COMFORT ANALYSIS ALGORITHM FOR A CLASSROOM IN SBM ITB'S FREEPORT BUILDING
It is necessary to ensure that the use of air conditioning continues responsibly and efficiently. One way to do it is to utilize thermal comfort analysis. The PMV method developed by Fanger is a thermal comfort analysis tool that uses various physical quantities as input. In this research, a Puyt...
Saved in:
| Main Author: | |
|---|---|
| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/79383 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | It is necessary to ensure that the use of air conditioning continues responsibly and
efficiently. One way to do it is to utilize thermal comfort analysis. The PMV method
developed by Fanger is a thermal comfort analysis tool that uses various physical
quantities as input. In this research, a Puython-based algorithm has been developed
specifically to calculate PMV for Classroom 2303 located in SBM ITB’s Freeport
Building, with PMV obtained from calculations by CBE Thermal Comfort Tool, an
online PMV calculator, as its reference. This PMV algorithm was designed to
receive four input variables i.e. metabolic rate, clothing insulation, air flow speed,
and temperature readings from a sensor installed inside Classroom 2303.
Initial results show that there is a significant error between PMV calculated by the
code developed from the aforementioned algorithm and PMV obtained by the online
calculator. Since nearly every factor of PMV in said algorithm has been written as
functions of one or more input variables whose values are fixed, errors are
suspected to occur in the iterative process of clothing surface temperature or tcl.
The unpredictable end result of an iteration process and how the stages of iteration
may vary from one algorithm to another make this parameter the most probable of
causing errors in the code calculations of PMV. To test this hypothesis, a test-run
for tcl was carried out to see the relationship that exists between clothing surface
temperature and PMV. The results show that tcl and PMV have an inverse
relationship which can be attributed to the thermoregulation mechanisms in the
human body.
The values of clothing surface temperature are then adjusted until PMV values
obtained through code calculation successfully approach the reference values. The
relationship that emerges between initial and revised clothing surface temperatures
turns out to be too complex to be expressed as a single function. The plot between
the two tends to form a linear line, but the distribution of the data shows that there
are other factors affecting its relationship. The relationship between the two is then
plotted for different variants of the input variables. The obtained results show that
revised clothing surface temperature value can be expressed as a function of its
initial value and metabolic rate. When the function for revising the clothing surface
temperature parameter values was entered into the PMV calculation algorithm, the
PMV calculation results obtained were proven to be significantly better, with the
average absolute error decreasing by 87.189% from the initial absolute error.
|
|---|