Buildingworkmethodstatement cm-ms-bw-001-141120013134-conversion-gate01(1)

Doc. Title Method Statement of Building Work TOA-TOYO JOINT VENTURE
Doc. No CM – MS – BW - 001 Rev. No. 0 Date July, 2010
Construction of Port Facilities and Buildings for Cai Mep International Container Terminal
CAI MEP INTERNATIONAL CONTAINER TERMINAL
METHOD STATEMENT OF BUILDING WORK
Page 1

TABLE OF CONTENS
1. Purpose Page 3
2. Work Scope Page 3
3. Reference Technical Specification Page 3
4. Reference Drawings Page 5
5. Construction Work Page 6
5.1 General Flow Chart Page 6
5.2 Construction Procedure Page 7
5.2.1 Preparation Page 7
5.2.2 Earth Work Page 7
5.2.3 Piling Work Page 9
5.2.4 Reinforcement Work Page 16
5.2.5 Formwork Page 17
5.2.6 Concrete Work Page 19
5.2.7 Masonry Work Page 22
5.2.8 Structural Steel & Roofing Work Page 23
5.2.9 Finishing Work Page 25
5.2.10 Mechanical & Electrical Work Page 26
5.2.11 Testing And Trial Run Page 28
6. Construction Schedule Page 28
7. Organizational Chart Page 29
8. Inspection And Quality Control Page 30
9. Safety Control Page 30
10. Environmental Control Page 31
11. Inspection And testing plan ( ITP )
12. Appendix
Page 2

1. PURPOSE
This Method Statement is prepared to ensure that construction of buildings for the project shall
comply on plans specifications and all relevant standard and code requirements in the
execution of different work activities to be performed in the construction of buildings and
other relevant structures associated with the project in general. In addition this will serve as a
tool to guide all technical personnel and layman execute proper construction procedures
complied with the quality and safety plans for the project.
2. SCOPE OF WORK
The scope of work cover for the construction of all Building and its utilities:
No. Building name Storey Structure
1 PMB Branch Office 2 R C Structure
2 Security Office 1 R C Structure
3 Operation Building 4 R C Structure
4 Amenity Block 2 R C Structure
5 Container Freight Station (CFS) 1 + M R C & Steel Structure
6 Maintenance Shop 1 + M R C & Steel Structure
7 Container Gate 1 R C & Steel Structure
8 Substation 1 R C Structure
9 Fuel Station 1 R C & Steel Structure
10 Pump Station 1 R C Structure
11 Miscellaneous structures 1 R C & Steel Structure
3. REFERENCE TECHNICAL SPECIFICATION
- Refer attachment as appendix – 1 - Applicable standards and code of practice VOLUME II
of the Technical Specifications (Part 1, Division 04, pp 2/14-14/14)
Page 3

4. REFERENCE DRAWINGS.
Refer attachment as appendix-2- Drawing list for Building Structure (PAC1-CM-BLD-GNR).
5. CONSTRUCTION WORK.
5.1 GENERAL FLOW CHART
Building work is depicted by the following flow-chart :
Page 4
Earth Work
Piling Work
Preparation
Roofing Work
Masonry Work
Reinforced Concrete Work
Finishing Work
Structural Steel Work
Testing & Trial Run
Completion
Metal Cladding Work
M & E Work
( HVAC )
(Plumbing)
(Electrical)

5.2 CONSTRUCTION PROCEDUCE
The work procedure is described as follows:
5.2.1 PREPARATION
Temporary yard such as stockpile and fabrication yard for building work shall be prepared
within the site after soil improvement. Location and plan shall be considered to avoid traffic
and congestions during mobilization of materials, machines and obstruction to construction
during the course of different activities in the site.
It is necessary to set up a fabrication yard in order to carry out the fabrication of
Reinforcing bars, form work, steel frames and so on. And also, those fabricated ,cast,
assembled products will be temporarily stocked at the Stock yard. The yards will be graded
flat at the designated area and with adequate drainage.
Joint survey with the Engineer’s representative shall be carried out to establish control
points and confirm the coordinates and elevation prior to the commencement of the
construction works.
After confirming the coordinates and elevations of all the building location, survey location
for piling and excavation shall be carried out each stage of the works.
5.2.2 EARTH WORK
5.2.2.1 Excavation work :
Excavation shall be done in a safe and sequential manner on the basis of the prepared plan
drawings and in accordance with the instructions by the Engineer.
The excavation method is either machine or manual cut, and care is to be taken not to
disturb the soil below the supporting ground. If deep trenching needs shoring, proper lateral
sheeting and struts shall be provided for safety.
During excavation, drainage ditch shall be provided and sloping down to sump pit to
prevent flooding within the work area in case rain occurs. Earth excavation with sloped roof
and surface drainage to avoid scouring off part of excavation pit.
Unsuitable material and waste matters shall be removed from site to the waste yard in
accordance with the specification requirements.
After excavation, the bottom surface of pit shall be compacted to not less than 95% of
maximum dry density by vibratory plate compactor and the slope shall be trimmed off to
avoid collapse of pit wall.
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5.2.2.2 Backfilling work
Approved suitable material should be used for backfilling. Compaction standard shall be
employed in the execution of this work. Fill materials shall be distributed evenly to the
backfill area to a specified thickness of compaction = 150 mm thick and compacted by
portable compactor to a specified compaction factor. Sprinkle water to the earth fill in
compliance with the allowable moisture contents specified before start compaction. Every
layer shall be tested for compaction to assure that this particular work is checked and
complied with the governing specification.
5.2.3 PILING WORK
5.2.3.1 General flow chart :
5.2.3.2 Piling Procedure :
5.2.3.2 General Piling Procedure
1. Pile Material
Page 6
Mobilization of Piling Machine
Delivery of RC Pile for Building structure
Lifting the lower segment RC pile by
Crane then mount Diesel Hammer
Driving the lower segment RC pile
Confirm the bearing capacity by
evaluating penetration during driving
Lifting the upper segment RC pile
and splicing
Driving the upper RC pile
Finish

- Pile Material :
PHC Spun Pile 600mm dia.
PHC Spun Pile 500mm dia.
RC Square Pile 400mm x 400mm
Piles will be plant fabricated and transported to the site by Barge and trailer truck. They will
be supported by bedding timbers placed directly under the positions of lifting hoops.
Piles will be stored carefully on flat ground within the temporary yard. Piles will be stacked
on top of one another to a maximum of three layer.
Material delivery dockets, receipts and inspection shall be conducted to every pile delivery
at site. Result of the inspection and delivery documents shall be submitted to the Engineer.
RC PILETIMBER
Storage of RC Pile
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TRUCK CRANE
TRAILER
RC PILE
Transportation of RC pile
- Piling Equipment :
The following equipment shall be used for the Piling work.
Hammer : Diesel Hammer 4.5 – 7 tons class, (KOBELKO K45/KB60)
Base Machine : HITACHI PD9 or equivalent
Service Crane : 35 ton class, crane truck
Others : Semi-automatic welding machine / Oxy Acetylene cutting outfit
2. Piling by diesel hammer : ( Refer attached drawing below )
The pile will be driven by diesel hammer and driving shall stop when the bearing capacity is
already reached and confirmed. All piles shall be driven to their specified bearing capacity
and location complying with technical specification and design drawings.
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CENTER LINE OF PILE
SURVEYER
TRANSIT/ PLUMB BOB
PILE DRIVER
SURVEYER
PILE UNDER DRIVING
DIESEL HAMMER
GNIVIRD
NOITCERID
TRANSIT/ PLUMB BOB
Pile Driving
a) Driving lower segment pile .
Crane will lift up the lower segment pile. After lifting , the pile shall be held along leader
of diesel hammer
The pile position shall be adjusted by moving the leader. The hammer with the cap is then
mounted on the pile top. Before starting driving, the verticality and position of the pile is
carefully checked by total station and theodolite and adjusted as required.
b) Driving upper segment pile .
When the lower segment had been driven the second segment will be positioned
concentric to the bottom segment held up and aligned vertically.
Prior to splicing area to be jointed must be free from rust, oil, water and other foreign
matter that would affect the quality of the welded joints. Splices will be by butt type joint
using arc welding. All welded joints will be inspected visually .
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Driving will be stopped when bearing capacity is already achieved, through the application
of Hiley’ s formula in calculating the bearing capacity. See PDA Test calculation .
If it is found that the bearing capacity is insufficient against design after the rebound
record, the pile will be extended and re-driven until the bearing capacity is attained.
Ru = 9.81 (Ef.MR.H) x MR + e2
.MP
S+0.5(C1+C2+C3) MR + MP
In which:
Ru : Ultimate Resistance, KN
MR : Weight of ram, Kg
H : Drop height of hammer, mm
Ef : Efficiency of fall of hammer
MP : Weight of pile + helmet , Kg
e : Coefficient of restitution
Page 10
PILE DRIVER
DIESEL HAMMER
HELMET
LOWER PILE
1) DRIVING OF LOWER PILE 2) CLEANING OF PILE HEAD 3) SPLICING 4) RESUMING OF DRIVING
FOR AREAS REQUIRING MORE THAN 1 PILE LENGTH TO OBTAIN DESIGN BEARING CAPACITY
UPPER PILE

C1 : Elastic deformation of pile , mm
C2 : Elastic deformation of ground , mm
C3 : Elastic deformation of pile head cushion , mm (here C3 = 2 mm).
S : average penetration, in mm per blow for at least the last 10 blows
(Use rebound record)
The result of Pile driving and bearing capacity shall be confirmed by Engineer. The records
of pile installation shall be submitted to the Engineer.
In case the pile tip can not reach the design level due to unforeseen hard layer, these matter
will be reported to Engineer.
If piles can not be driven to the design level but has already attained the required bearing,
the driving shall be stopped to avoid buckling or cracking in accordance with Specification
and Engineer Instruction.
Pile head treatment shall be done after getting the Engineers’ Approval.
5.2.3.3 Pile Record
Before final setting of the piles, the rebound shall be recorded.
The pile driving is deemed completed after confirmation of the sufficient bearing capacity
against design. Bearing capacity for all piles will be calculated with formulas .
5.2.3.4 Test Pile - (Test pile position refer to figure on page 9, pile driving)
Before piling, Pile Dynamic Analysis will be conducted to confirm the pile capacities and to
decide the correction factor of Hiley’s formula. PDA test provides more information, about
Skin resistance distribution, Toe resistance, simulated static load-settlement relationship,
pile integrity, stresses in the pile during the blow.
The detail procedure shall be submitted in separate document.
5.2.3.5 Quality Control
a)Inspection of pile .
Pile material such as concrete , rebar and wire strands or tendons ( for pre – stress type )
shall be inspected on factory before fabrication and the finished product shall be inspected
before delivery.
The inspection report shall be received before arrival of piles on site.
Upon arrival on site, piles shall be inspected as to dimensions, quantity, and physical
condition and reported to the Engineer.
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b) Inspection prior to Welding Work.
Prior to the welding, the grooved face and its adjacent areas shall be completely free from
oil, paint, oxides , water and all other foreign materials.
When two lengths of pile are jointed, the end plates shall bear even in all areas, The
welding must be carried out according to the manufacture’s instruction and must be
checked before driving resumes.
During driving, the pile head will be protected by helmet of cast steel or mild steel fitted
closely around the pile. Packing (cushion) timber, covering the head of pile, will be
placed on the pile and will be replaced as often as necessary to prevent damage to the
piles.
c) Driving record.
• Program and progress
• The date and time of pile driving
• Position of the pile number and size of pile
• Type and size of hammer and for drop or single acting hammer , details of
release mechanism ,the length of the drop or stroke, for diesel hammer the length of stroke
and the blows per minute ; for double acting hammers the number of blows per minute and
for automatic hydraulic drop hammers the recorded average energy per blow during an
increment of penetration.
• Deviation from tolerance and the line and level shown on the drawings.
• R.L of toe of pile with hammer in place before driving.
• R.L. of toe of pile on completion of driving.
• Length of the completed pile and level of splices.
• Driving Log (Depth , blow counts per 200mm for whole of penetration , with
times of interruption of breaks in driving ).
• The record of temporary compression for each of the last ten blows.
• Dolly and packing type and condition before and after driving.
• Details, date and time of any re-driving or testing.
5.2.4 REINFORCEMENT WORK
Manufacturer of reinforcing bar shall be proposed to the Engineer for accreditation and
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approval. No deliveries shall be accepted for use without decision by the engineer.
Every delivery of reinforcing bar supply for construction, the quantity and physical
properties shall be checked by the Contractor. The quality shall be confirmed by checking
mill certificate issued by the manufacturer through the comparison of the laboratory test
result of specimen taken from the different kinds of diameter in the delivered product.
5.2.4.1 Material
Round bar & deformed bar shall be 2100 Kg/cm²- ( Yield strength ) .
5.2.4.2 Reinforcement storage before fabrication
− Reinforcement will be stored in a warehouse area at site with adequate protection from
getting rusty, or protected from any element that would affect its quality condition as
specified.
− Storing will be organized by category, type, grade and diameter. As a rule, the end of
each bar had been painted to differentiate the different grades.
− Reinforcing steel that are rejected have to be stored in a separate place away from where
it was accepted, before sending back to the supplier.
5.2.4.3 Reinforcement fabrication process
1. Reinforcement fabrication and storage.
− Workers will fabricate the bar according to the information mentioned on the label, and
fabricated bars will be stored systematically according to their structural usage per work
unit mentioned on their label (Work Unit, structure, drawing, category, type, diameter,
grade…).
− All precautions will be taken to avoid damage and bending the steel bars during storage,
loading and transportation to the site. The bars should be protected from the rust by
storage on wooden platform, crates or elevated trestles.
2. Installation at site.
− The reinforcement installation will be in accordance with the drawings, the General
Technical Specifications, and the Owner requirements (cover, spacer blocks,
reinforcement continuity and tolerances).
− Before any pouring, all the reinforcement shall be inspected and accepted by the
Engineer or the owner’s representative.
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The foreman on site will correct any deviation out of tolerances immediately upon notice
before filling the inspection request.
5.2.5 FORMWORK
5.2.5.1 Formwork Set-Up :
Blinding concrete shall be installed prior to placing formwork.
Form made of plywood or steel shall be cleaned on all its surfaces in contact with concrete
shall be treated or painted with oil prior to the installation. Installation shall be made
precisely on the lines and grades using string, spirit level, survey instrument etc.
Forms shall be kept firmly in position by putting tie rods or external support. Tie rods
support shall be so arranged and distributed and strong enough to withstand the pressure
during casting concrete.
5.2.5.2 Construction method
− Foundations shall be constructed first and then columns to the tripod beam bottom
level. In the Workshop building, sub-columns and sub-beams system on wall, beam
surface form will be done after the installation of steel framework.
− Establish accurate centerline axis and level for the layout of foundations, columns,
beams, and floors, before installing forms.
− Form should be adequately supported or braced to avoid movements or displacement
during casting concrete. Bolt connector or any acceptable pre fabricated support
system is essential.
− Check the alignment of formwork by stretching a cord along edges of installed forms
− For additional supports, Iron and tension cable can be used as supports in the
installation of forms of column footings. Check the establish centerline for accuracy
to avoid deviations.
− Staging and scaffolding support system is to be utilized for beams and slab forms, and
they are installed at the same time. During installation regular checking of lines and
grades shall be made to ensure the evenness and straightness of slabs and beams
during construction .
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− position Steel and wood joist supports and bracings is utilized for forms of concrete
structures. Jacks are installed at top and base of supports for adjusting height or length, all bases of
support should be propped by a piece of wooden material to prevent settlement.
− All supporting columns and bracings should be anchored, hold and connect together to
become stable frame system to secure structures during concreting.
5.2.6 CONCRETE WORK
5.2.6.1 Material
- The class of concrete for each section of the works shall comply with Specification, JIS and
ASTM Standards.
PROPERTY CONCRETE TYPE
1. Concrete Class D E G
2. Application Over 2 Story
Buildings
1 Story Buildings Lean
Concrete
3. Cement Type-1 PCB40 PCB40 PCB40
4. Water Cement Ratio 0.475 0.5 .76
5. Minimum Cement
Content (kg/m3)
350 330 220
6. Max Aggregate Size 19 19 38
7. Concrete Cylinder
Strength at 28 days–
Fc’ (Mpa)
30Mpa 25Mpa 14Mpa
Design mix shall be submitted and approved by the engineer and trial mix shall be conducted to
confirm the compression strength and satisfy the specification.
In general, concrete must be casted within 60 minutes from mixing to placing. The concrete
temperature shall be below 35⁰C as specified at the point of pouring. Other measures to keep the
concrete temperature low is to keep the aggregates and water cool, or arrange early morning
pouring to avoid casting daytime which has high humidity condition.
5.2.6.2 Construction method :
+ Concrete Pouring and Treatment requirements:
- Do not change position, bend shape of reinforcement, position of formwork and thickness
of concrete cover.
- Do not use vibrator to displace horizontally the concrete mix
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- Concrete shall be poured continuously up to finish grade or construction joints indicated
on the drawing shall be followed when there is a tendency to stop pouring.
- Tremie pipe shall be utilized when pouring concrete beyond manual reach or above
ground to avoid segregation of the ready mix concrete during pouring and maximum
falling height be 1.5m.
- Use concrete spacer between formwork and reinforcement to avoid displacement of
reinforcement during concrete placement.
- Concrete shall be continuously poured until one component is finished to avoid cold
joints.
- Structural components such as column, wall which is higher than 1.5m shall be provided
with openings at 1.5m maximum vertical spacing to avoid concrete from segregation
during pouring and to abide by the standard height of pour of 1.5 meters .
- Use concrete vibrator to compact mix, vibration time shall be from 20 to 30 seconds. Use
trowel to level the concrete surface.
- If the concreting is too large in quantity that one time pouring is impossible, the
contractor shall provide proper construction joints in accordance with the specification.
These joints shall be located at places that have minimum effect of moment and shear,
usually located at 1/3 or 2/3 points of the span of the structure or refer to the
specifications on construction joints. Before casting the remaining portion roughened
surface to ensure bonding with new concrete.
- Concrete shall be poured in layers from 20-30cm then vibrate in accordance with the
specified time. Number of vibrator depends on the concreting area, at least 3 stand-by
vibrators in every concreting location as back up for conked out units .
- Concrete for slab shall be leveled right after pouring. Pre cast concrete pieces for level
control points shall be provided and removed before casted concrete gets hard.
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Concrete Pouring for Foundation
Concrete Pouring for Superstructure
+ Concrete Curing: 24 hours after Casting.
All concrete shall be cured by either spraying water directly or spraying water on a mat
placed on the concrete surface.
Water curing by sprinkling process, shall be repeated whenever the water dries up and
maintain the concrete wet for a period of 7 days.
+Concrete Finishing: Upon removing formworks, concrete surface shall be finished,
repaired of any defects to ensure evenness and uniformity in color. All concrete surfaces
shall be free from any irregularities. A waterproofing coat may also be applied to a
selected location as specified.
5.2.6.3 Testing and Check for Acceptance:
Concrete specimens for strength test shall be obtained in every 20 m³ batch group, and
taken at the same time and place. Test sample standard dimensions are Ø=150mm x h=
300mm cylinder .
5.2.7 MASONRY WORK
Material Sample and technical data’s of hollow brick shall be submitted to the Engineer for
approval.
Bricks between column and lintel supports shall be arranged in accordance with the
specification and drawings.
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P U M P C A R

The mortar composition is the mixture of cement, sand and water by correct proportion
specified. For volume 3 : 5 : 1, for reinforced block work and elsewhere. The mixing and
kneading is to be done by manual mixing or a small a portable mixer. Adequate and
sufficient application of mortar for horizontal joints shall be applied, and bricks shall be
wetted before laying. The mortar for vertical joints shall be filled up by trowel during block
laying and the ends of the brick must be “buttered” to enhance firm connection. Excess
mortar that came out on the surface shall be scrape out with a trowel. All horizontal and
vertical joints shall have full mortar coverage. The mortar squeezed from the joints shall be
flushed with the the adjoining installed bricks. Finish joints to face work after mortar has
begun to stiffen by square raking. Follow specified standard for the maximum layer of
bricks installation per day.
5.2.7.1 Work preparation:
 After removing formwork of slab, floor cleaning shall be done for marking.
 Survey group shall re-establish center line, ink marks shall be applied to a re-located
margin lines of brick walls on columns and slabs.
 Adjust deviated anchor bars that will connect to brick walls .
 Mobilize bricks, cement, mortar, water, scaffolding to construction area.
5.2.7.2 Construction order:
 Brick work shall be constructed from bottom to top process, main walls shall be laid
first followed by partition walls.
 Boundary walls shall be built first followed by partition wall.
5.2.7.3 Checking:
 Check regularly the verticality and straightness during brick laying by ruler and
plumb.
 Stretched cord to both ends to ensure brick laying course are in straight line.
5.2.8 STRUCTURAL STEEL & ROOFING WORK
5.2.8.1 . Structural Steel :
1. Material and Receiving
Manufacturer of steel materials shall be proposed to the engineer for approval prior to
procurement and delivery. All steel materials delivered to the fabrication shop, shall be
inspected and checked by the recipient. Delivery dockets, mill certificates , quantity and
physical property checking of the material shall be performed before unloading. Inferior
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and sub standard materials are rejected and prevented from unloading. The material
technical data’s from the mill certificate shall be confirmed by conducting laboratory test
on sample taken from the delivered materials. Usage of the material depends on the test
result for the specified stress requirements.
2. Shop Fabrication
Prior to fabrication, shop drawings shall be submitted to the engineer for approval.
Bended steel members shall conform to the approved shop drawing. In order to maintain
quality and minimise the installation and assembly period, painting must be done in the
fabrication yard.
3. Erection work
Detailed erection sequence for each structure approved by the Engineer shall be
acquired prior to erection. Mobile cranes will be used for the erection. Temporary
bracings shall be prepared before column erection in order to maintain the verticality and
alignment. After checking proper alignment, fasten these steel members by connectors of
high strength bolt and tighten it according to its specified torque moment requirement by
using torque wrench or special tightening hand tool. Touch up paint will be applied to all
scratched surfaces to restore its required texture surfaces.
Erection of Steel Structure
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4. Metal Roofing and Cladding Work
The material for metal roofing and cladding, including shop drawing requirement for this
work shall be submitted to Engineer for approval. The material shall be fabricated based
on the approved shop drawings submitted to the manufacturer.
Basic Steps for installation of metal roofing and cladding is explained below.
Step 1: Establish the grids and elevations based on the standard procedure in executing
this work item or relevant acceptable method through markings using stretched string or
wire along its grid or elevation.
Step 2: Fixing metal sheets onto purlin and girt using self-tapping screws.
Step 3: Sealant shall be applied at proper wrapped portion based on the manufacturer’s
shop drawing
Step 4: Fix flashings, trims, gutters, down spout pipes and louvers.
5.2.8.2 . Roofing Work :
Roofing material and shop drawing for this type of work shall be submitted to the engineer
for approval.
Installation procedure shall conform to manufacturer’s product technical specification on
installation. Precautions against accident shall be well considered for its sensitiveness in
executing this work.
Before placing waterproofing membrane, the surface shall be thoroughly cleaned and
primer paint shall be applied in dry condition. Apply waterproofing membrane on primer
coated surface, by pre heating to adhere firmly. Overlapping portion of waterproofing
membrane shall be carefully bonded with each other to avoid water leakage.
5.2.8.3 . Occupational Health And Safety Control for Steel Structure Work.
Everybody who will carry out the works shall use all the necessary protective or safety
gears and abide by the occupational health and safety control plan of the project to avoid the
occurrence of accident and minimize the potential cause of hazard. Working areas shall be
provided with warning devices signage’s or barriers , and frequently checked by Safety
Engineer during work time.
Ensure all vehicles and equipment is safe and fully efficient, guarded and equipped with
safety devices and has been subjected to necessary test.
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Make sure that operators, drivers and attendants will only concern themselves on the
equipment for which they have been thoroughly trained. Check working efficiency of
equipment for its intended purpose, and its valid registration and calibration certificates.
Safety lifelines shall be provided to all elevated work areas to enhance connection point
safety harness or belts used by workers, especially to a location where scaffolding
impossible. All workers working higher than 1.5 meters must wear a safety harness or belt.
The safety line manufacturer's recommendations for use shall be strictly followed.
5.2.9 FINISHING WORK
5.2.9.1 Door & Window works
Doors, louvers and windows shall be of the approved ones and in compliance with the
specification. Installations shall be made in accordance with the schedule to keep finishing
work in sequence and to avoid lapping of activities that cause delay or damage impact to
other finishing work. Installed doors, louvers and windows shall be keep protected to avoid
damages caused by other ongoing finishing works and other parties.
5.2.9.1 Plastering
The thickness and mix proportion of mortar for plastering or rendering shall be in accordance
with the specification and the mixing and kneading process is to be done manually or by
portable mixer. Cement shall be of the standard ordinary Portland cement and sand, sourced
out from land or river and shall be approved by the Engineer.
5.2.9.2 Tiling
Tile material and shop drawing for tile layout or arrangement shall be submitted to engineer
for approval. Prior to tile laying concrete surface where tile is laid shall be cleaned, free from
dust, oil, grease and other elements that would affect quality of tile bed mortar. Bed mortar of
specified mix proportion (1:3) is placed and spread evenly with a minimum thickness of
10mm over the area to be tiled. Tiles are then laid over the evenly applied bed mortar until it
adhere firmly inplace.Tile gaps shall be filled up with grout of approved type or as specified
in the plan. After grouting tiled area shall be cleaned from excess grout to keep the work
clean as specified.
5.2.9.3 Painting
Paint material shall be of the approved one in accordance with specification. Surface
preparation before painting shall conform to the manufacturer’s instruction to each kind of
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paint material. Number of coat, dry film thickness shall comply with the approved paint
schedule. Where required, final coat shall be carried out, after or almost all of the work
nearby is completed to minimize damage.
5.2.9.4 Ceiling Work
The material for ceiling shall be submitted to the engineer for approval. Shop drawing for
ceiling layout and arrangement plan shall be approved by the Engineer. And proper
coordination to M/E works shall be made to avoid lapping of works that cause delay in
executing the work.
Hangers shall be installed, fastened and fixed properly under the concrete slab or steel
structural members. Then thin gauge and light steel frame is installed to enhance level
adjustments’ required. M&E works above ceiling shall be completed before installing the
ceiling frame.
Deflections or damage on the T-runner frame shall be repaired prior to installation of the
gypsum board.
5.2.10 MECHANICAL & ELECTRICAL WORK
5.2.10.1 Air Conditioning and Ventilation Work
Manufacturer and Equipment of Air Conditioning and Ventilation system including shop
drawing plans and all schematic layouts for these works shall be submitted to the Engineer
for approval. All slots in exterior walls intended for pipe crossing shall be made impervious.
Shop drawings of ceilings and walls shall reflect location of air conditioner, ventilator and
ducts, to account for the balance distribution of other equipment. Installation of air
conditioner, ventilator, air inlet and outlet, including pipes, ducts and other related fittings
shall conform as indicated in the shop drawings. Exhaust pipe/duct shall sloped downward
from inside to outside.
5.2.10.2 Plumbing Work
Material and equipment for Plumbing work and shop drawings shall be submitted to the
engineer for approval.
Excavation and trenching of soil, preparation of sleeves on floor, wall and beam where there
are necessary in structures shall be well considered.
Before being installed, all pipes shall be thoroughly cleaned, free from any scales, burrs,
rusts and obstructions.
Prefabrication, installation and jointing of pipes (including fittings) with adhesive for PVC
material, including valves, strainers, and flexible joints shall be done carefully.
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Adequate pipe supports, hanging steel bars and anchorage shall be provided.
Sealing of pipe sleeves shall be done properly.
Pressure test for water supply pipes and flushing test for drainage pipes shall be performed.
Back-fill and compaction of soil for underground piping shall be done carefully.
5.2.10.3 Electrical Work
Material and equipment for Electrical work and shop drawings shall be submitted to the
Engineer for approval.
Preparation for efficient wire or cable laying such as confirmation of the exact locations
where they are to be laid, cleaning the trenches or ducts, scraping/brushing inside of the
duct bank, pipes or conduits and so on shall be done.
All cable connections shall be made inside distribution board; pull box and outlet box etc.
and the connection shall never be exposed or inside of conduits.
Cable alignment, binding, fixing, wall penetration sealing, cable marking, cable penetration
into conduits between cable trays, ducts and Job-site junction boxes and similar shall be
made properly.
Adequate press-save coupling, wire connector or press combine terminal etc. will be used as
a principle for the connection of wires and/or cables.
In the case of line pipe exceeding 30m for one section or where leading in is difficult, pull
box shall be used.
Fixing method of distribution boards etc. shall be specified on the construction drawing, and
shall be fixed accordingly.
The position of lighting apparatus shall be indicated on ceiling allotted sketch in advance,
taking balance with other facilities apparatus.
Fixing height of switch and socket outlet shall be shown on the shop drawing securing the
approval of the consultant and shall be fixed accordingly.
5.2.11 TESTING AND TRIAL RUN
After installation of Mechanical and Electrical equipment, test and inspection including
their record reports will be done. Trial operation shall be proceeded to adjust and check the
function of equipment.
Page 23

6. CONSTRUCTION SCHEDULE :
See Attach- Appendix-3
7. ORGANIZATIONAL CHART
Page 24

Page 25
Safety/Environment
Manager
Mr. Quan
Site
Building Chief
(Mr. Tien – Mr.Jun)
QA/QC
Chief
Mr. Rolly
Survey
Engineer
Site
Engineer
Sub- Contractor
Project Manager
Mr. Fukushima
Construction
Manager
Mr. Asai
TTJV
Site
Engineer
Site
Engineer

8. INSPECTION & QUALITY CONTROL
8.1 General
The Contractor shall submit the name and appropriate details of any independent testing
organization to the engineer for approval before any construction work for Building
commence.
8.2 Materials Testing
Materials testing is to be carried out before delivery of materials into the site and quality
certificate shall be submitted.
9. SAFETY CONTROL
The project Safety Plan is established for the Construction of CAI MEP INTERNATIONAL
CONTAINER TERMINAL in Vietnam based on Occupational Health and Safety and
Rehabilitation Management Manual of TTJV.
The safety control of works shall be maintained and ensure its compliance through-out the
completion period so that works can be executed smoothly without unnecessary interruption.
Importance shall be placed on the prevention of any accident such as personal injury ,
damage to structures and work itself.
In general, safety rules and regulations stipulated by the governing authorities of Vietnam as
well as by the client shall be observed.
10. ENVIRONMENT CONTROL
The Project Environmental Management Plan (EMP) addresses the requirements for
Environmental Management , outlining how the scope , as described by the Conditions of
Contract , will be implemented to achieve the key objectives for CAI MEP
INTERNATIONAL CONTAINER TERMINAL PROJECT , and has been designed to
comply with the intent of OHSAS 18001 and ISO 14001.
Page 26

Built into this operating system will be CAI MEP INTERNATIONAL CONTAINER
TERMINAL PROJECT Specification requirements ,as defined in the contract. This
Environmental Management Plan will incorporate work method statements, inspections, test
plans , and check sheets are developed to cover the particular requirements of this project.
This Plan is established based on the Environmental Management Manual of TTJV.
11.Appendix :
1. – Applicable Codes and Standards
2. – Drawing List for Building
3. - Building Construction Schedule
4. – Inspection and Test Plan
Page 27

Appendix - 1
Applicable Codes and Standards
Page 28

Appendix - 2
Drawing List for Building
Page 29

Appendix - 3
Building Construction Schedule
Page 30

Appendix - 4
Inspection and Test Plan
Page 31

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