INTEGRITI
TERIMA AMANAH
Sesungguhnya kami (Allah) telah menawarkan amanat kepada langit, bumi dan gunung-ganang, maka semuanya enggan untuk memikul amanat itu dan mereka khuatir akan mengkhianatinya. Maka dipikullah (diterimalah) amanat itu oleh manusia. (Ingatlah) sesungguhnya tabiat manusia itu amat zalim dan amat bodoh (suka melakukan perkara yang tidak wajar). (Al-Ahzab: 72)
JANGAN KHIANAT
Wahai orang-orang yang beriman! Janganlah kamu mengkhianati (amanah) Allah dan RasulNya, dan (janganlah) kamu mengkhianati amanah-amanah kamu, sedang kamu mengetahui (salahnya). (Al-Anfaal: 27)
PERLU PROFESIONALISMA
Dari Abu Hurairah RA Berkata: Rasullullah SAW bersabda, "Jika amanat disia-siakan, maka tunggulah kehancuran. Sahabat bertanya "Bagaimana menyia-nyiakannya ya Rasullullah?. Jawab Rasulullah SAW:" Jika urusan diserahkan kepada orang yang bukan ahlinya (tidak mahir/ tidak kompeten/tidak profesional/ tidak pakar) maka tunggulah kehancurannya.
Tuesday, July 21, 2009
Monday, July 20, 2009
PILE TESTING
Malaysia Practice (JKR/SPJ/1988 )
The pile can then be tested by one of two static load tests:
1. Maintained load test
2. Constant Rate of Penetration (CRP) test.
The pile can then be tested by one of two static load tests:
1. Maintained load test
2. Constant Rate of Penetration (CRP) test.
Maintained Load Test
The Maintained Load Test shall be carried out as follows:-
- the full test load on pile shall be twice the design load noted on the Drawings and it shall be applied in twelve equal increments. At least two hours shall elapse between the addition of each load increment, i.e. until the rate of settlement is reduced to less than 0.25mm/hour and slowing down;
- the full test load shall be maintained on the pile for at least 48 hours and settlements shall be recorded at intervals of not more than 12 hours. The test pile shall then be unloaded in four equal increments at one hour intervals until the full load is removed. Settlement readings shall be made immediately after and before every load increment is applied or removed.
Constant Rate of Penetration (CRP) Test
For each pile load test, three cycles of pile loading test at a constant rate of penetration shall be carried out to a full test load equal to twice the design load.
The rate of loading shall be such that a constant rate of penetration is maintained throughout the rest insofar as is practicable. The rate of movement of each pile to be tested shall be agreed upon with the S.O prior to the start of the test. At least twelve readings of settlements and their corresponding loads shall be made in the loading process.
After attaining a test load equal to twice the design load, the load shall gradually be released and at least four readings of settlement and their corresponding loads shall be made during the unloading process. The settlement obtained when the load has been completely released shall also be recorded. An interval of at least 15 minutes shall elapse before the next CRP test is commenced.
Interpretation of Test Results
The S.O's interpretation and conclusions on the test results shall be final. Unless otherwise specified, the pile so tested shall be deemed to have failed if:-
- the residual settlement after removal of the test load exceeds 6.5mm; or
- the total settlement under the Working Load exceeds 12.50mm; or
- the total settlement under twice the Working Load exceeds 38.0mm. or 10% of pile diameter/width whichever is the lower value.
Hong Kong Practice
Maintained Load Test
At present, this is the most popular pile test used in Hong Kong. The equipment required for loading the pile is assembled across the top of the pile. The hydraulic jack and the load cell are placed on top of the pile. The ram of the jack is extended until the load cell touches the underside of the main RSJ of the loading frame. Equipment to measure pile settlement is then set up, and the zero reading s are noted.
Before carrying out the load test, the engineer will state the working load and the test load, and he will describe the different stages of loading in the test. Most specification give the test load as twice the working load. The test load is applied in increments of about 25 percent of the working load, until the working load is reached. Smaller increments are added thereafter until the specified limit is reached.
Loading tests are usually carried out in a cycle. Each stage of the loading test or increment of load is applied as smoothly and quickly as possible. Readings of load, time and settlement are taken when loading commences, and at intervals as the load increases. Each increment of load is allowed to remain until settlement has ceased. Similarly, unloading of each incremental load must not commence until recovery has ceased. In general, settlement or recovery is assumed to have ceased when the rate of movement is 0.25 mm per hour.
When the maximum test load is reached, the applied load is unload progressively to zero load. Measurements are recorded again during the unloading process.
Some specifications may require the load to be unloaded at intermediate stages, either progressively or in one operation. In such cases, the load is then re-applied either in increments or in one operation.
Most Hong Kong specifications require that after unloading, the maximum test load be applied again in one operation, and be maintained for a minimum period of 72 hours. It is the step unloaded to zero load.
Graphs of load against time, load against settlement, and settlement against time are then plotted. These graph s are used to determine if the pile has satisfied the requirements of the specification.
The pile is deemed to have failed the test if:
- the total pile settlement > Z + D/120 + 4 mm
- and residual pile settlement > D/120 + 4 mm
where D = diameter of circular or least lateral nominal dimension of other piles in mm.
Z = L (2P+Pt)/3AE mm
P = test load ( kN )
L = length of pile ( m )
A = cross-section of pile ( m² )
E = Young's modulus of elasticity of pile ( kN/m² ).
Pt = resistance at the tip of the pile
= 2APb( kN ) where
Pb =safe bearing capacity of sub-soil strata at the tip of the pile ( kN/m² ). This can be calculated from the appropriate soil parameters obtained by site investigation.
Constant Rate of Penetration (CRP) Test
The equipment used in the constant rate of penetration (CRP) test is the same as that used in the maintained load test. However, the method of loading is different.
The equipment used in the constant rate of penetration (CRP) test is the same as that used in the maintained load test. However, the method of loading is different.
In the CRP test, the pile is made to penetrate the soil at a constant speed. This is achieved by increasing the applied force. The force applied to the head of the pile to maintain this constant rate of penetration varies and is measured continuously. As a result of the pile movement, the soil is stressed progressively until it fails in shear. When this occurs, the ultimate bearing capacity of the pile is reached.
Before the test is begun, the hydraulic jack and the load cell are inserted between the pile head and the reaction system. The jack is then operated to cause the pile to penetrate the soil at a uniform speed. Readings of time, penetrate rate and jacking force are made at convenient intervals. A penetration rate of about 0.75 mm/min. is a suitable choice for friction piles in clay, while a penetration rate of about 1.5 mm/min. is a suitable choice for end bearing piles in sand or gravel. However, the actual rate may vary depending on the pumping equipment available.
The test usually proceeds very rapidly and requires the services of several observers to take simultaneous readings.
As the test proceeds, a graph of force against penetration is made to determine when the ultimate bearing capacity is reached. Typical graphs for a friction pile and an end bearing pile are shown in the Fig. pt.9. and pt. 10. For a predominantly friction pile, the value of the force at the point A in Fig. pt. 9 represents the ultimate bearing capacity.
For a predominantly end bearing pile, the ultimate bearing capacity in most cases is taken as the force at which the penetration is equal to 10 percent of the base diameter of the pile. However, two factors that should be borne in mind are:
- for a very long pile, the elastic shortening of the pile during the test may reach 10 percent of the base diameter: and
- for a large pile, there may be difficulty in loading the pile to a settlement as great as 10 percent of its base diameter.
When either of the above two cases is encountered, the ultimate bearing capacity is usually estimated roughly from the load settlement curve.
Tuesday, July 7, 2009
Engineering Term
1. Buttress
Noun
i. a construction, usually of brick or stone, built to support a wall
ii. any support or prop
Verb
i. to support (a wall) with a buttress
ii. to support or sustain
2. Fatigue
Noun
the weakening of a material caused by repeated stress or movement
3. Borrow Pit
Noun
a pit created to provide earth that can be used as fill at another site
RC Deep Beam
What is RC Deep Beam ?
Deep beams are structural elements loaded as beams in which a significant amount of the load is transferred to the supports by a compression thrust joining the load and the reaction. As a result, the strain distribution is no longer considered linear, and the shear deformations become significant when compared to pure flexure.
Floor slabs under horizontal load, short span beams carrying heavy loads, and transfer girders are examples of deep beams.
RC deep beams have many useful applications in building structures such as transfer girders, wall footings, foundation pile caps, floor diaphragms, and shear walls.
EXAMPLE
RC deep beams, which fail with shear compression, are the structural members having a shear span (orange line(a)) to effective depth (black line(d)) ratio, a/d, not exceeding 1.
Sunday, July 5, 2009
Balanced Cantilever
(Info From BBR Holdings)
With the cantilevering method, the superstructure of bridges is usually built from one or more piers by means of formwork carriers. Normally the structure advances from a short stub on top of a pier symmetrically in segments of about 3 m to 5 m length to the mid span or to an abutment, respectively (load balancing method).
The prestressing tendons are arranged according to the moment diagram of a cantilever, with a high concentration above the pier. Towards the mid span or the abutment the number of tendons gradually decreases.
The use of the cantilevering construction method, for medium and long span concrete bridges, is recommended especially where a scaffolding is difficult or impossible to erect as e.g., over deep valleys, wide rivers, traffic yards or in case of expensive foundation conditions for scaffolds.
Incremental Launching
(Info From BBR Holdings )
The incremental launching method is particularly suited for the construction of continuous post-tensioned multi-span bridges. It consists of casting 15 m to 30 m long sections of the bridge superstructure in a stationary formwork behind an abutment to push a completed section forward with jacks along the bridge axis.
The sections are cast contiguously, one after another and are then stressed together. The superstructure, growing section by section is launched over temporary sliding bearings on the piers until the bridge is completed. In order to keep the bending moment low in the superstructure during the extrusion phases, a launching nose made of steel is attached to the front of the bridge deck. The launching nose is dismantled after the superstructure has reached the opposite abutment.
However, the spans should not exceed 60m approx. and the bridge sections must be constant. Furthermore the superstructure of the bridge has to be continuous over the whole length and straight or have a constant curvature in plan and elevation.
Space Frame Design
Rules of Thumb for Space Frame Design
It is important for the architect to work side by side with the engineer when considering a space frame system. While the engineer normally sizes up the structural members after the architect has designed the structure, his/ her role must be more interactive to ensure that each design decision takes full advantage of a space frame system while managing costs. Simply changing the modular sizes of the space frame components could have a huge impact on material costs.
Typically, space frames are not as economical for spanning systems under 7-10 metre in length.
For determining depth of space frame;
a. Use ratio of 1:12 depth to span for a 1-way space frame.
b. Use ratio of 1:15 depth to span for a 2-way space frame.
c. Use ratio of 1:18 depth to span for a 3-way space frame.
It is important for the architect to work side by side with the engineer when considering a space frame system. While the engineer normally sizes up the structural members after the architect has designed the structure, his/ her role must be more interactive to ensure that each design decision takes full advantage of a space frame system while managing costs. Simply changing the modular sizes of the space frame components could have a huge impact on material costs.
Typically, space frames are not as economical for spanning systems under 7-10 metre in length.
For determining depth of space frame;
a. Use ratio of 1:12 depth to span for a 1-way space frame.
b. Use ratio of 1:15 depth to span for a 2-way space frame.
c. Use ratio of 1:18 depth to span for a 3-way space frame.
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