Bscience 2 report
Transcript of Bscience 2 report
AMOS TAN CHI YI 0318330
TUTOR: AR. EDWIN
Contents:
1. Introduction
1.1 Objective
1.2 Introduction to Jalan Tuanku Abdul Rahman Community Library
1.3 Lighting strategies in the community library design
1.4 Site response strategies in the community library design
1.5 Daylighting strategies in the library design
2. Lighting analysis and execution
2.1 Community Library Drawings
2.2 Workshop
2.2.1 Daylight factor calculation
2.2.2 Artificial lighting calculation
2.2.3 PSALI
2.2.4 Conclusion
2.3 Cafe
2.3.1 Daylight factor calculation
2.3.2 Artificial lighting calculation
2.3.3 PSALI
2.3.4 Conclusion
3. References
1.0 Introduction
1.1 Objective
The objectives of this project are as follows:
1. To show understanding of artificial lighting and daylighting strategies (PSALI) in the final
design
2. To solve design problems in relation to sustainability issues (natural lighting, site analysis)
3. To design spaces incorporating artificial and daylighting (when necessary)
1.2 Introduction to the Jalan Tuanku Abdul Rahman Community Library
Figure 1: Library design strategies and intentions
The library, being a place for the birthplace of ideas,
does this by employing the existing human behaviour
in Jalan Tuanku Abdul Rahman of self-expression. As
such, the library does this by being open, providing
visual, auditory and physical platforms for the
expression of the street, collectives and the individual.
The library thus features a very open and permeable
design, allowing cross ventilation as well as deep
circulatory penetration into the internal spaces. As
such, this also results in the permeation of non-
physical elements as well, including but not limited to:
smells, sounds, and light.
1.3 Lighting strategies in the community library
design
The community library is designed to emulate the
informality and lawlessness of the backalleys, bazaars,
and night markets endemic throughout Jalan Tuanku
Abdul Rahman. To achieve this atmosphere, the
library uses daylighting to create and set the mood
using three methods.
Firstly, it uses the façade as a permeable shading
device. The double layered façade significantly cuts
down on the direct harsh late morning light entering
the building, while still allowing enough light so as not
to interfere with the activities going on within. The
façade is built with a grid of SHS, and with it being
powder coated white, actually might glow and reflect
some diffused light into the interior.
To supplement diffused light, a massive amphitheatre
that doubles as a lightwell is provided that allows
deep, focused light to penetrate into the harder to
reach interior spaces of the library. This is the 2nd
method, and it allows for a comprehensive lighting of
the interior while providing dramatic flair.
Finally, as typical of the target spaces, daylighting is
almost always never direct, and thus the library uses
the adjacent office complex Wisma Harwant as a
lighting diffuser, diffusing what would otherwise be
harsh daylight into the building.
Figure 2: lighting strategies.
1.4 Site response strategies in the community library design
Figure 3: Site plan featuring building shading at different times. NOTE: shading not taken on the
same day.
The library is located amidst many tall buildings, many of which create shade and strategic
points of the day. For example, the large Wisma Harwant building is able to shade nearly the
entirety of the library half of the time of the year for up to 4 hours a day. Nearby towering KWSP
building shades the backlane of the building from 2PM onwards, and the nearby buildings once
again also provide shade, providing a decent and comfortable experience for the library
throughout the day.
However, this shading is not comprehensive, and there exists spots of nearly direct sunlight, in
addition to the sidewalks and roads being able to reflect a limited amount of glare into the
building.
The above drawing is also a composite of the best
shading situations, but is not indicative of a typical
day. As the sun moves in a sinusoidal pattern
throughout the year, shading might not be as
comprehensive as shown. Regardless, this allows
various light penetration into the building, and thus in
no way does the library suffer from the lack of
daylighting.
1.5 Daylighting strategies in the library design
The diagram on the left describes how the library
responds to the sun path. Circumscribed with the
circles are the distinct parts of the design that are
already discussed in part 1.3.
Of note are the various forms of the building,
especially the frontage, amphitheatre cone and the
area above the stairwell, that are designed to respond
directly to the daylighting situation.
The amphitheatre structure’s top is cut at an angle to
capture the more comfortable and softer morning
light and permeate it into the building, while the area
above the stairwell is directly perpendicular to the sun,
allowing for optimum light penetration into the spaces
within.
The double facade frontage of the building is also
designed to be permeable to the very early morning
sun, while shutting it off as the day approaches the
late morning (11am and later).
Figure 4: Light penetration diagram
2. Lighting analysis and execution
2.1 Community Library Drawings
Figure 5: First Floor Plan, NTS
Figure 6: Section A-A, NTS
The two spaces that are analyzed here are the Café and the Workshop, both of which are located on the
1st floor of the community library. These two spaces will both be daylighted and lighted by artificial
means, as the library is meant to be open also at night.
Café, 100m2
Cafe
2.2 Workshop
The workshop is located the 1st floor of the community library, and is a standard room with a large
window opening towards the street. Specifically, it is a textile workshop where the users will be able to
learn the interesting and traditional trade of textile making from the masters present on Jalan Tuanku
Abdul Rahman.
The workshop is well lighted during the day as it is opened towards the a well shaded area, and is
augmented by PSALI lighting. The interior artificial lighting must be in accordance to MS1525 and JKR
guidelines to ensure safety while operating the various machinery within.
2.2.1 Daylight factor calculation
For the academic purposes of this project, I have
used two methods to determine the daylight factor
of workshop.
The first method is to do a lighting contour
simulation of the workshop space, find the average
illuminance level and compare that with the daylight
illuminance in order to find the resultant Daylight
factor percentage.
Figure 8: Light contour simulation of initial workshop design. Note poor internal light penetration and
major illumination issues.
Figure 9: MS1525 Daylight factor distribution and description
Using a grid, the average lux is determined to be 2600 lux.
According to a study conducted by UiTM, the average Malaysian outdoor illuminance is a whopping
30,000 lux.
The resultant daylight factor is the following:
(2600lx /30000lx) x 100 = 8.6%
The result of 8.6% is a major concern, as it shows the space as having thermal and glare issues. To
counter this, the workshop thus has incorporated two distinct passive daylighting solutions: louvres and
lightshelves.
In addition, in order to improve light penetration, PSALI is incorporated to help balance the internal
lighting situation.
Figure 10: Louvres (left) and Lightshelves (right) incorporated into the design of the workshop
Due to technical difficulties, it was impossible to conduct a lighting contour study, and as a result to
calculate the daylight factor, the 2nd method was used.
Figure 11: Daylight factor calculation with accounting for shaded areas
Figure 12: Daylight factor calculation result
With a daylight factor of 5.76%, it falls under MS1525’s regulations as being “good”. This is important as
the workshop is filled with potentially dangerous machines, and thus having adequate daylighting is
paramount to ensure the safety of its users.
2.2.2 Artificial lighting calculation
As the library is also meant to be open during the
night, an appropriate artificial lighting strategy is also
employed.
A luminaire called the LUCCI LEDLux is used, with it
having a luminous flux of 3000 lumens and as well as a
cool white colour temperature. This slightly blue
tinted light helps to promote concentration in the
users of the workshop, and thus minimize accidental
incidents with the machines.
This luminaire, in addition to its aesthetic beauty, is
thus suitable to be used in the workshop.
Figure 13: Luminaire information
To calculate the number of luminaires needed, it is first necessary to know what is the required
illumination level. As set by IES and the JKR department, the recommended illumination level is 400 lux.
Using the lumen method, the required number of luminaires can be determined. After that, the room
index is determined and utilization factor is derived from a referenced table.
The room’s materials are as follows:
Figure 14: Room material along with its associated reflectance values.
Figure 15: Room index calculation and result.
Figure 16: Referenced table for utilization factor.
Figure 14: Lumen method calculation and result
It is thus determined that, in order to reach the recommended illuminance of 400 lux, it is necessary to
have a minimum of 14 luminaires of the type described above. The distance between these luminaires is
thus calculated using:
Figure 18: Luminaire maximum distance between each other.
In conclusion, it is calculated that 14 luminaires of the type LUCCI LEDlux has to be arranged with a
maximum distance of 4.2m from each other in order to achieve a illuminance set by MS1525 of 400 lux.
Figure 19: The resultant workshop ceiling plan with the luminaires laid in accordance to the calculations,
and wired for PSALI.
Figure 20: Light contour of artificial lighting arrangement which has provided even lighting.
2.2.3 PSALI
As aforementioned, the pure daylighting approach had left much to be desired, and thus PSALI was
implemented in order to provide a more even distribution of light. In addition, shades and lightshelves
were installed, and the resultant daylighting simulation is as follows:
Figure 21: Light contour after application of shades and PSALI lighting wiring.
The PSALI has greatly helped to evenly distribute lighting, especially towards the interior. Another
calculation with PSALI and shading use also resulted in a greatly improved daylight factor:
Thus, the workshop now has a sectional profile as follows:
Figure 22: Diagrammatic section showing the lighting strategies employed in the workshop.
2.2.4 Conclusion
With PSALI, shades and lightshelf: 6% DF
Without PSALI, with shades and lightshelf: 5.76%
Without PSALI, without shades and lightshelf: 8.6%
The workshop has an adequate lighting solution that provides adequate illuminance for the safe and
efficient conductance of the activities within.
2.3 Café
The café is a 100m2 common space located also on the 1st floor of the community library. Unlike the
Workshop, the café does not have a direct opening for daylight. Instead, the café uses the adjacent
exterior staircase’s stairwell to provide diffused light into the interior. In addition, the adjacent
amphitheatre has perforations that allow it to act as a lightwell, providing more dramatic, spotlight-like
lighting.
The cafe is the place where its users have a place to unwind after a day’s work, to sit back with coffee in
one hand and a magazine in other. As such, this place should be bright enough for easy reading as well
as safe navigation. By JKR guidelines, it should be 300lx in illuminance.
Figure 23: Table showing recommended illuminance level of the café, here set as 300 lux.
2.3.1 Daylight factor calculation
As the café features an unorthodox lighting solution, the only method to determine its daylight factor is
by creating a lighting contour simulation.
Figure 24: Lighting contour for the café. Note extremely poor illumination performance.
Despite its unorthodox lighting arrangement, as it stands it has major lighting issues. The daylight factor
calculation further highlights this fact.
With the average illuminance at a measly 500 lux:
(500lx /30000lx) x 100 = 1.67%
Poor lighting will make the café unsuitable for any reasonable reading or even eating activity. As such,
PSALI intervention is required.
2.3.2 Artificial Lighting Calculation
As aforementioned, the library is also
meant to be open at night, and thus
an artificial lighting solution must also
be designed.
The selected luminaire is an LED tube.
LEDs have a very high efficiency,
allowing it to minimize heat waste
while saving on electricity. The high
luminous flux is needed to greatly
brighten up the dark interior.
The 2700K colour temperature is
warmer than the one found in the
workshop, and thus provides the
more intimate, relaxed and informal
atmosphere of the café.
Figure 25: Lighting specifications
The café’s surfaces are as follows:
Figure 26: Room material along with its reflectance values.
While the materials are different, being more industrial and rough in nature, their associated reflectance
values are quite similar to the ones found in the workshop.
Figure 27: Room index calculation
The utilization factor thus is determined using the referenced table.
Figure 28: Utilization factor determined to be exactly the same as the one in the workshop.
With these values, the number of luminaires can now be established using the following equation.
Figure 29: Lumen method equation for determining number of luminaires.
Following MS1525, the recommended illuminance is set at 300 lux.
Figure 30: Number of luminaires determined with the lumen method.
In addition, to determine the distance between the lights:
Figure 31: Distance between lights
Thus, a total of 23 luminaires of the type HOMELI with a distance of X from each other is needed to
adequately illuminate the café to an illuminance level of 300 lux.
Figure 32: The resulting lighting arrangement, with PSALI wiring.
Figure 33: Artificial lighting contour, showing even and adequate illuminance throughout the café.
2.3.3 PSALI:
PSALI is required for the actual use of the space as without it, the space is just too dark. With PSALI, the
spaces are now adequately lit.
Figure 34: PSALI lighting contour
With PSALI, the average illuminance has risen significantly. Redoing the daylight factor calculation gives
us the much improved result:
Figure 35: Daylight factor calculation. A far improved result. A 5% DF is considered “good”.
Figure 36: Diagrammatic section showing the lighting strategy employed
2.3.4 Conclusion:
With PSALI: 5% daylight factor
Without PSALI: 1.67% daylight factor
By using PSALI, the quality of the interior has risen dramatically. The café now has the illuminance
needed for the safe usage by its users.
References:
ROOM ILLUMINATION LEVEL (2016). Retrieved 12 July 2017 from
http://www.pioneerlighting.com/new.pdfs/IESLuxLevel.pdf
Ander, G. (2003). Daylighting performance and design. Hoboken, N.J.: John Wiley & Sons
Department of Standards Malaysia (2007). CODE OF PRACTICE ON ENERGY EFFICIENCY AND USE OF
RENEWABLE ENERGY FOR NON-RESIDENTIAL BUILDINGS (FIRST REVISION). N.p, Department of
Standards Malaysia, Retrieved from www.msonline.gov.my
Izdihar, I.A. (2013). MS1525(2013/2014) 2nd Revision. Retrieved 10 July 2017 from
http://www.eria.org/events/6.%20UBBL%202012#20Amendments%20on%20EE%
Kim G.C., Farid A., Chee M.Y., Eng C.K., (2012) Techno-economic Analysis of LED Lighting: A Case Study in
UTeM’s Faculty Building, Perlis, Malaysia. Elsevier Ltd.