Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques
In Malaysia, there are abundant agricultural wastes generated from 15,000 hectares of pineapple plantation. The current study focuses on fully utilising the pineapple leaf fiber (PALF) extracted from the Yankee variant sourced from a plantation in Telok Panglima Garang as a reinforcement material...
| Main Author: | |
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| Format: | Thesis |
| Language: | English |
| Published: |
2022
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| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/103950/ http://psasir.upm.edu.my/id/eprint/103950/1/MUHAMMAD%20IMRAN%20BIN%20NAJEEB%20-%20IR3.pdf |
| _version_ | 1848864152122032128 |
|---|---|
| author | Najeeb, Muhammad Imran |
| author_facet | Najeeb, Muhammad Imran |
| author_sort | Najeeb, Muhammad Imran |
| building | UPM Institutional Repository |
| collection | Online Access |
| description | In Malaysia, there are abundant agricultural wastes generated from 15,000
hectares of pineapple plantation. The current study focuses on fully utilising the
pineapple leaf fiber (PALF) extracted from the Yankee variant sourced from a
plantation in Telok Panglima Garang as a reinforcement material in composite,
hence converting the agriculture waste into a potentially useful and sustainable
resource. The physical, chemical, thermal, as well as mechanical properties of
untreated and silane treated PALF were investigated in this study. Three types
of composites, pineapple leaf fiber composite (P), pineapple leaf fiber/glass
fiber composite (GPG), glass fiber composite (GGGG) were evaluated for low
velocity impact (LVI) properties. Visual inspection, computed tomography (CT)
scan, digital detector array (DDA) radiography and infrared (IR) thermography
techniques were applied to detect the damage evolution of the impacted
composites. The broad peaks at 1317.81 and 1100 cm-1 of the Attenuated
Total Reflectance (ATR) analytical graph indicate silane compound bonding
with PALF. In addition, there are no significant changes to the configuration of
the silane’s treated PALF due to its crystallinity. Treated PALF displays thermal
stability improvement by 5.9%, with degradation occurring at the temperature of
360°C. The surface area of the treated PALF displays broader peaks,
indicating greater surface roughness compared to untreated PALF. The tensile
strength test on single fiber shows PALF display highest tensile strength when
treated for three hours compared to one and five hours respectively. The
untreated PALF composite (UT-PALFC) possess 7.1% higher storage modulus
than treated PALF composite (T-PALFC), indicating untreated fiber attribute to
high dynamic property in composite. Meanwhile, the thermomechanical
analysis shows the sequence of linear coefficient of thermal expansion (CTE)
of the treated and untreated fiber composites as follows: T-PALFC > Neat
epoxy > UT-PALFC. On the other hand, the low impact analysis shows three
varying impact energy ranges at 1-2J, 2-9J and 9-12J for P, GPG, GGGG
respectively. The addition of glass fiber in GPG composites further delayed
damage initiation time and propagation throughout the sample by about 8.5%
compared to GGGG composite as shown in LVI. Visual inspections as
captured in photographic images show different damage modes in the
presence of woven fiberglass mat in GPG compared to P. CT-scan images
show significant cross-section cracks on impacted GPG and GGGG
composites compared to P. Compared to IR thermography technique that only
shows the general area of damage, the DDA radiography captures significant
surface damages on impacted P, GPG and GGGG composites. For example,
the DDA captures significant damage in GPG at 9J with an area of 84% less
than IR thermography. However, CT-scan, DDA radiography and IR
thermography failed to capture occurrence of surface delamination as observed
in visual inspection. This shows that the NDT techniques used in this research
need to be complimented with other tools for clearer interpretation of the extent
impacted damage in composite. Overall, the newly developed hybrid GPG
composite shows great potential in structural applications such as drone
because of its favourable impact resistance properties. |
| first_indexed | 2025-11-15T13:44:16Z |
| format | Thesis |
| id | upm-103950 |
| institution | Universiti Putra Malaysia |
| institution_category | Local University |
| language | English |
| last_indexed | 2025-11-15T13:44:16Z |
| publishDate | 2022 |
| recordtype | eprints |
| repository_type | Digital Repository |
| spelling | upm-1039502023-06-19T23:38:11Z http://psasir.upm.edu.my/id/eprint/103950/ Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques Najeeb, Muhammad Imran In Malaysia, there are abundant agricultural wastes generated from 15,000 hectares of pineapple plantation. The current study focuses on fully utilising the pineapple leaf fiber (PALF) extracted from the Yankee variant sourced from a plantation in Telok Panglima Garang as a reinforcement material in composite, hence converting the agriculture waste into a potentially useful and sustainable resource. The physical, chemical, thermal, as well as mechanical properties of untreated and silane treated PALF were investigated in this study. Three types of composites, pineapple leaf fiber composite (P), pineapple leaf fiber/glass fiber composite (GPG), glass fiber composite (GGGG) were evaluated for low velocity impact (LVI) properties. Visual inspection, computed tomography (CT) scan, digital detector array (DDA) radiography and infrared (IR) thermography techniques were applied to detect the damage evolution of the impacted composites. The broad peaks at 1317.81 and 1100 cm-1 of the Attenuated Total Reflectance (ATR) analytical graph indicate silane compound bonding with PALF. In addition, there are no significant changes to the configuration of the silane’s treated PALF due to its crystallinity. Treated PALF displays thermal stability improvement by 5.9%, with degradation occurring at the temperature of 360°C. The surface area of the treated PALF displays broader peaks, indicating greater surface roughness compared to untreated PALF. The tensile strength test on single fiber shows PALF display highest tensile strength when treated for three hours compared to one and five hours respectively. The untreated PALF composite (UT-PALFC) possess 7.1% higher storage modulus than treated PALF composite (T-PALFC), indicating untreated fiber attribute to high dynamic property in composite. Meanwhile, the thermomechanical analysis shows the sequence of linear coefficient of thermal expansion (CTE) of the treated and untreated fiber composites as follows: T-PALFC > Neat epoxy > UT-PALFC. On the other hand, the low impact analysis shows three varying impact energy ranges at 1-2J, 2-9J and 9-12J for P, GPG, GGGG respectively. The addition of glass fiber in GPG composites further delayed damage initiation time and propagation throughout the sample by about 8.5% compared to GGGG composite as shown in LVI. Visual inspections as captured in photographic images show different damage modes in the presence of woven fiberglass mat in GPG compared to P. CT-scan images show significant cross-section cracks on impacted GPG and GGGG composites compared to P. Compared to IR thermography technique that only shows the general area of damage, the DDA radiography captures significant surface damages on impacted P, GPG and GGGG composites. For example, the DDA captures significant damage in GPG at 9J with an area of 84% less than IR thermography. However, CT-scan, DDA radiography and IR thermography failed to capture occurrence of surface delamination as observed in visual inspection. This shows that the NDT techniques used in this research need to be complimented with other tools for clearer interpretation of the extent impacted damage in composite. Overall, the newly developed hybrid GPG composite shows great potential in structural applications such as drone because of its favourable impact resistance properties. 2022-04 Thesis NonPeerReviewed text en http://psasir.upm.edu.my/id/eprint/103950/1/MUHAMMAD%20IMRAN%20BIN%20NAJEEB%20-%20IR3.pdf Najeeb, Muhammad Imran (2022) Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques. Doctoral thesis, Universiti Putra Malaysia. Plant fiber - Malaysia Nondestructive testing Pineapple |
| spellingShingle | Plant fiber - Malaysia Nondestructive testing Pineapple Najeeb, Muhammad Imran Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques |
| title | Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques |
| title_full | Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques |
| title_fullStr | Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques |
| title_full_unstemmed | Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques |
| title_short | Malaysian pineapple (Yankee) leaf fiber composites damage investigation using non-destructive techniques |
| title_sort | malaysian pineapple (yankee) leaf fiber composites damage investigation using non-destructive techniques |
| topic | Plant fiber - Malaysia Nondestructive testing Pineapple |
| url | http://psasir.upm.edu.my/id/eprint/103950/ http://psasir.upm.edu.my/id/eprint/103950/1/MUHAMMAD%20IMRAN%20BIN%20NAJEEB%20-%20IR3.pdf |