Project DESIGN AND CONSTRUCTION OF 2000 LIVING UNITS AND PUBLIC BUILDINGS AL-KHOMS AL-MARQAB. Location District Building No

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1 Project Location District Building No DESIGN AND CONSTRUCTION OF 2000 LIVING UNITS AND PUBLIC BUILDINGS AL-KHOMS AL-MARQAB METHODOLOGY - SAMPLING & TESTING Revision History Rev # Description of Revision Submission Date By Approval Date Rev 0 Sampling & Testing 20 OCT 09 a. Rino DagDag/ b. Nasrulla Ahmad Rev 1 Sampling & Testing 10 JAN 10 a. Nasrullah Ahmad/ b. Rino Dagdag Rev 2 Sampling & Testing (List of frequency only) 14 JAN 10 Nasrullah Ahmad Table of Contents 1.0 General/Scope 2.0 Parameters 3.0 Applicable Codes and Standards 4.0 QC Lab. Organization Chart & Responsibilities 5.0 List of tests to be done by Makco 6.0 Procedures for Sampling and testing & attachments 7.0 List of Sampling & Testing Frequencies

2 1.0 GENERAL/ SCOPE This methodology shall be applied to the sampling and testing requirements of the project as a part of the Quality Management System. It applies only to the Quality Laboratory at the project site. 2.0 PARAMETERS 2.1 Name of the Project: Design and Construction of 2000 Living Units And Public buildings. 2.2 Location of the Project: AlKhoms, District Almarqab, Libya. 2.3 Land Area: 237 hectares. 2.4 Total Building Area: 414,400 square meters. Building Area (Residential) 370,000 m 2 Building Area (Public) 44,400 m APPLICABLE CODES AND STANDARDS The following codes shall, wherever relevant shall be followed for sampling and testing of materials and works done. a. BS 812 part 103 Standard Test Method for Determination of Particle Size Distribution. b. ASTM C127 Standard Test Method for Density, Relative Density (Specific Gravity), and Absorption for Coarse Aggregates. c. ASTM C128 Standard Test Method for Density, Relative Density (Specific Gravity), and Absorption for Fine Aggregates. d. ASTM C29 Standard Test Method for Bulk Density (Unit Weight) of Aggregates. e. ASTM C143 Standard Test Methods for Slump of Hydraulic Cement Concrete. f. ASTM C1064 Standard Test Method for Temperature of Freshly Mixed Portland Cement Concrete. g. BS 1881 part 108 Standard Test Method for Making Cube of Fresh Concrete. h. BS 1881 part 111 Standard Test Method for Normal Curing Test Specimen (20 ±2 C). i. BS 1881part 116 Standard Test Method for Determination of Compressive Strength of Concrete Cubes. j. ASTM C231 Standard Test Method for Air Content of Freshly Mixed Concrete by the Pressure Method. k. ASTM C140 Standard Test Methods for Sampling and Testing Concrete Units and Related

3 Units. l. ASTM D1557 Standard Test Methods for Laboratory Compaction Characteristics of Soil Using Modified Effort (2700 kn m/m³). m. ASTM D1556 Standard Density and Unit Weight in Place by the Sand Cone Method. 4.0 QC LAB. ORGANIZATION CHART & RESPONSIBILITIES

4 Quality Control Laboratory Organisation Chart QA/QC Manager Sohail Moughal Site Engineer Mohiuddin Ahmed QA/QC Inspector (Nasrullah) Lab. Technician (Arnold Galang) Lab.Technician (Rino Dagdag)

5 4.1 QA/QC Manger/ Coordinator The QA/QC Manager/Coordinator shall have overall responsibility of the functions of the Quality Department on the site. He/ she shall ensure that sampling & testing methodology is prepared and is fully implemented, and specified standards are achieved according to the requirements of CM/CS. He ensures availability of all the equipment required for quality sampling and testing. He/She prepares schedules and monitor and resolves the problems regarding operations of the Quality Department. 4.2 Laboratory Technician Laboratory Technician shall organize on site sampling & testing as per schedules provided by the QA/ QC manager and requirement soft hr Construction Deptt.. He/ She shall be responsible for the collection of samples and perform the quality tests of all type soils, aggregates and concrete. He/ She shall conduct all quality tests according to project specification and report irregularities to QA/QC Manger/ Coordinator. 4.3 Quality Control Inspector The Quality Control Inspectors shall witness all tests being performed inside the lab or out on site as per designated areas, and be responsible of the daily inspection of workmanship and documentation of activities including: - Supervise all sampling & testing of materials on site quality laboratory. - Monitors the execution and provides advice to Site Engineer for any Non-conforming work. - Prepares and records and distributes all documentation of the quality department - Reports to QA/QC Manger/ Coordinator. 4.4 Site Engineer Site Engineer shall be responsible for planning, programming, organizing and monitoring progress of work of his designated area/ section. He will liaison with the site quality laboratory staff for necessary sampling & testing of material on site. He shall convey any new quality requirements from the client to the Quality Department. He shall convey all the irregularities to the Quality Department. 5.0 LIST OF TEST TO BE DONE BY MAKCO 5.1 Aggregate Grading Test BS Aggregate Relative Density ASTM C127 & ASTM C Aggregate Unit Weight ASTM C Concrete Slump Test ASTM C Concrete Temperature ASTM C Concrete Cube Making Test BS 1881 part Concrete Normal Curing Test BS 1881 part Concrete Cubes Compression Test BS 1881 part Concrete Air Content ASTM C Hollow Blocks Compressive Strength Test ASTM C140

6 5.11 Soil Laboratory Compaction Test ASTM D Soil Site Compaction Test ASTM D PROCEDURES FOR SAMPLING AND TESTING 6.1 BS 812 part 103 Standard Test Methods for Determination of Particle Size Distribution The Following apparatus shall be used: a. Sample Divider b. Ventilated Oven c. Balance Scale d. Test Sieves e. Trays f. Container g. Wheel Borrow The following preparation of test portion shall be followed: a. Reduce the field sample to the desired size using procedure of quartering or by the sample splitter. b. Place in an oven until the mass becomes constant at a temperature of 110 ± 5⁰C. c. Weigh & record the dry mass after cooling in a dessicator. (M1) The following procedure to conduct the test shall be followed: 1. For some materials, e.g all in aggregates or hoggin, the particle size distribution may result in excess mass on one or more sieves particularly on the finer sizes. a. Subdivide the test portion into two or more sub-portions. Determine the particle size distribution for each portion and combine the results for the purpose of reporting. b. Separate the test portion on an appropriate sieve. Weight the retained and passing fractions to determine the proportion of each present. 2. Washing and sieving method a. Preliminary separation. b. Wet both sides of a 75um test sieve. Mount the sieves in such a way that the suspension passing the test sieve can be run to waste or, when required, collected in suitable vessel. c. Place the weighed oven dried test portion in a container and add sufficient water to half fill the container. Agitate the contents so that particles smaller than 75um are completely separated from the coarser particles. d. Continue washing the coarse residue until the water passing the test sieve is clear and then wash all the residues from the container and sieves into the tray. Remove excess free water by careful decantation through the test sieve, avoiding transfer of solids. e. Dry the residue in the oven until the constant mass is achieved. Cool, weigh and record as (M2). f. Determine the mass of material passing the test sieve as (M1) (M2). 3. Sieving the dried residue a. Nest the clean and dry sieves on a fitting receiver in order of increase

7 aperture size from the bottom to top. b. Shake the sieves for a sufficient time to separate the test sample into the size fractions determined by the sieve apertures used. c. When sieving is done start with the coarsest sieve and shake each sieve separately over a clean tray. Do not force materials through the sieve by hand pressure but placing of particles is permitted. d. Record any extraneous material such as clay lumps and remove from the sieve for separate weighing. e. Do not apply pressure to the surface of the sieve to force through the mesh. Used light brush to clear the sieve openings. f. To prevent blinding of the sieve apertures by overloading followed the weighing sample masses. g. Weigh the material retained on each sieve, together with any material cleaned from the mesh, on completion of sieving on that sieve Calculation and expression of results: Calculate the mass retained on each sieve as a percentage of the original dry mass (M1). For the mass of material passing the finest sieve, add that passing during washing (M1-M2) to that found during the dry sieving. Calculate the mass passing each sieve as a cumulative percentage of the total sample pass Format attached

8 SITE LABORATORY TEST REPORT FOR SIEVE ANALYSIS FOR FINE AGGREGATES - BS 812 Client HIB Name of Project Design and Construction of 2000 Living Units & Public Buildings Location Alkhoms Project No Kinds of Materials Date Tested : Original Source Lab. Ref. No.: Sampling Date: Original Weight, gm. 530 Oven Dry Weight, gm Washed Oven Dry Weight, gm. 471 Additional Limits for Grading Fine Fineness Modulus 1.48 Sieve Size Cummulative Wt. Retained, gm mm Wt. Passing, gm % Retained % Passing Specification Pan Remarks Percent Passing Sieve Size (mm) CM/CS Remarks: Witnessed by: Tested by:

9 6.2 ASTM C127 Standard Test Methods for Density, Relative Density (Specific Gravity) and Absorption of Coarse Aggregates The Following apparatus shall be used: a. Weighing Balance b. Sieves c. Ventilated Oven d. sample Container e. Water Tank The following procedure to conduct the test shall be followed: a. Dry the test to constant mass at a temperature of 100 ±5⁰C, cool in air at room temperature for 1 to 3 hr for test samples. b. Subsequently immerse the aggregate in water at room temperature for a period of 24± 4 hr. c. Remove the test sample in water and roll it in a large absorbent cloth until all visible films of water are removed. Wipe the large particles individually. d. Determine the mass of the test sample in the saturated surface-dry condition. Record this and all subsequent masses to the nearest 0.5 g or 0.05% of the sample mass, whichever is greater. e. After determining the mass in air, immediately placed the SSD test sample in the sample container and determine its apparent mass in water at 23 ± 2⁰C. f. Dry the test sample to constant mass at a temperature of 110 ± 5⁰C, cool in air at room temperature 1 to 3 hr, and determine the mass The following calculation shall be followed: a. Relative Density (Specific Gravity Dry), SG dry SG dry = A/(B-C) b. Relative Density (Specific Gravity SSD), SG SSD SG SSD = B/(B-C) c. Apparent Relative Density (Apparent Specific Gravity), ASG ASG = A/(A-C) d. Absorption (%) Absorption = [(B-A)/A] x100 Where: A mass of oven dry test sample in air, g B mass of saturated-surface-dry (SSD) test sample in air, g C mass of saturated test sample in water, g Format attached

10 SITE LABORATORY TEST REPORT FOR SPECIFIC GRAVITY & WATER ABSORPTION FOR COARSE AGGREGATE ASTM C127 Client : HIB Name of Project : Design and Construction of 2000 Living Units & Public Buildings Location : Alkhoms Project No. : Lab. Ref No. : Sampled at : Kind of Sample : Sampled by : Date Tested : Sample Trial 1 Trial 2 Average 1 Weight of Basket in Air, gm 2 Weight of Basket in Water, gm 3 Weight of Basket + SSD Sample in Air, gm 4 Weig ht of SSD Sample in Air, gm A 5 Weight of Basket + Sample in Water, gm 6 Weight of Sampled in Water, gm C 7 Weight of Oven Dry, gm B 8 Bulk Specific Gravity, (SSD) A/A-C 9 Bulk Specific Gravity, (DRY) B/A-C 10 Apparent Specific Gravity B/B-C 11 Absorption % [(A-B)/B]x100 CM/CS Remarks: Witnessed by: Tested by:

11 6.3 ASTM C128 Standard Test Methods for Density, Relative Density (Specific Gravity) and Absorption of Fine Aggregates The Following apparatus shall be used: a. Weighing Balance b. Mold and Tamper for Surface Moisture Test c. Pycnometer d. Oven The following procedure to conduct the test shall be followed: a. Partially fill the pycnometer with water. Introduce into the pycnometer 500±10g of saturated surface dry fine aggregate, and fill with additional water to approximately 90% of capacity. b. Manually roll, invert, and agitate the pycnometer to eliminate all air bubbles (note: About 15 to 20 min are normally required to eliminate the air bubbles by manual method). c. After eliminating the air bubbles, adjust the temperature of the pycnometer and its contents to 23 ±2 ⁰C if necessary by partial immersion in circulating water, and bring the water level in the pycnometer to its calibrated capacity. Determine the total mass of the pycnometer, specimen, and water. d. Remove the fine aggregate from the pycnometer, dry to constant at temperature of 110 ± 5⁰C, cool in air at room temperature for 1± ½ hr., and determine the mass. e. Determine the mass of the pycnometer filled to its calibrated capacity with water at 23 ± 2⁰C The following calculation shall be followed: a. Relative Density (Specific Gravity Dry), SG dry SG dry = A/(B+S-C) b. Relative Density (Specific Gravity SSD), SG SSD SG SSD = S/(B+S -C) c. Apparent Relative Density (Apparent Specific Gravity), ASG ASG = A/(B+A-C) d. Absorption (%) Absorption = [(S-A)/A] x100 Where: A mass of oven dry specimen, g B mass of pycnometer filled with water, to calibration mark, C mass of pycnometer filled with specimen and water to calibration mark, g S Mass of saturated surface dry specimen, g Format attached

12 SITE LABORATORY TEST REPORT FOR SPECIFIC GRAVITY & WATER ABSORPTION FOR FINE AGGREGATE ASTM C128 Client : HIB Name of Project : Design and Construction of 2000 Living Units & Public Buildings Location : Alkhoms Project No. : Lab. Ref No. : Sampled at : Kind of Sample : Sampled by : Date Tested : Sample Trial 1 Trial 2 Average 1 Weight of Saturated Surface Dry Sample, gm A 2 Weight of Pycnometer Filled with Water, gm B 3 Weight of Pycnometer + Water + SSD Sample, gm C 4 Weight of Oven Dry, gm D 5 Bulk Specific Gravity, (SSD) D/(B+A-C) 6 Bulk Specific Gravity, (DRY) A/(B+A-C) 7 Apparent Specific Gravity D/(B+D-C) 8 Absorption % (A-D)/D*100 CM/CS Remarks: Witnessed by: Tested by:

13 6.4 ASTM C29 Standard Test Methods for Bulk Density (Unit Weight) of Aggregates The Following apparatus shall be used: a. Weighing Balance b. Tamping Rod c. Shovel and Scoop d. Measure The following procedure to conduct the test shall be followed: Shoveling Procedure for loose bulk density. a. Fill the measure to overflowing by means of shovel or scoop; discharge the aggregate from a height not to exceed 2 above the top of measure. b. Level the surface with straight edge. c. Determine the mass of measure plus its contents and measure alone Rodding Procedure a. Fill the measure one third full and level the surface. Rod the layer with 25 strokes of tamping rod evenly distributed. Do not allow the rod to strike the bottom of the measure. b. Fill the second third and level again and rod as above. Prevent the tamping rod to penetrate the previous layer. c. Fill the measure to over flowing and rod again as mentioned above. d. Level the surface of the aggregate with straightedge. e. Determined the mass of the measure plus its content and measure alone The following calculation shall be followed: Bulk Density (G T) M = V Where: M bulk density of aggregate, kg/m³ G mass of aggregate plus the measure, kg T mass of measure, kg V volume of measure m³ Format attached

14 SITE LABORATORY TEST REPORT FOR UNIT WEIGHT OF AGGREGATE TESTING ASTM C 29 Client : HIB Name of Project : Design and Construction of 2000 Living Units & Public Buildings Location Alkhoms Project No. : Lab. Ref. No. : Sampled at : Kind of Sample: Sampled by : Date Tested : Description Weight of sample + weight of mold 2. Weight of mold 3. Weight of sample, gm 4. Volume of mold, cc 5. Unit weight og sample 6. Average CM/CS Remarks: Witnessed by: Tested by:

15 6.5 ASTM C143 - Standard Test Methods for Slump of Hydraulic Cement Concrete The Following apparatus shall be used: a. Concrete Thermometer b. Slump Cone c. Slump Plate d. Tamping Rod e. Measuring Tape f. Scope g. Wheel Borrow The following procedure to conduct the test shall be followed: a. Mixed a fresh concrete sample in a wheel barrow Format attached b. Dampen the slump cone and place on the flat slump plate, filled the cone in 3 layers approximately one third the volume of the slump cone. 25 strokes with the tamping rod for each layer. c. Clean the surface of the slump cone & slump plate then release the slump cone at least 5 ±2 second. d. Immediately measured the slump by determining the vertical difference between the top of the cone and the displaced original center of the top surface of the specimen.

16 SITE LABORATORY Client HIB Project Title Design and Construction of 2000 Living Units & Public Buildings Location Alkhoms Project No C40 CONCRETE SLUMP MONITORING RECORD CONCRETE DETAILS LOCATION DETAILS Sampling Date CDD Conc Time Time Time Total Concrete Ambient Slump Reqd Pass/ Building Grade Arrive Start Finish CUM Temp. Temp. (mm) Slump Fail Name Structure / Location 14 Sep 09 CDD ⁰C 37⁰C 75 mm +/ 25 R4STA 12 Roof Slab FF Roof Beam R5STB 34 Columns on GL2, A, B, C 14 Sep 09 CDD ⁰C 36⁰C 85 mm CM/CS Remarks:

17 6.6 ASTM C1064 Standard Test Method for Temperature of Freshly Mixed Portland Cement Concrete The Following apparatus shall be used: a. Container b. Temperature Measuring Device The following procedure to conduct the test shall be followed: a. Place the temperature measuring device in the freshly mixed concrete so that the temperature sensing portion submerged a minimum of 3 inches. b. Leave the temperature measuring device in the freshly mixed concrete for a minimum period of 2 minutes or until the temperature reading stabilizes, then read and record the temperature. 6.7 BS 1881 Part 108 Standard Test Method for Making Cube of Fresh Concrete The Following apparatus shall be used: a. Cube Mould b. Compacting Bar c. Steel Float d. Tamping Rod e. Scoop The following procedure to conduct the test shall be followed: a. Mould should be thinly coated with oil or grease to prevent loss of water. b. Fill the mould with concrete in 3 layers, the number of strokes per layer for 150 mm are 35. c. Compacting each layer should be in a uniform manner. The compacting bar should not penetrate any previous layer. d. After the top layer has been compacted, smooth and level the top of the mould. e. Cover the sample with plastic or burlap and put a fly wood on top of it. f. During the initial 24 ±8 hours after demoulding the temperature immediately adjacent to the specimen shall be maintained in the range of ⁰C, loss of moisture from the specimen shall be prevented Format attached

18 SITE LABORATORY CONCRETE CUBE TEST MONITORING Client HIB Project Title Design and Construction of 2000 Living Units & Public Buildings Project Location Alkhoms Project No Date CDD Building No. of Test Results Structure/Location Date Tested Name Cubes 7 Days 28 Days Mixed Grade (Mpa) R4STA 12 Roof Slab ff a c Roof Beam b d Sep 09 CDD 12 R5STB 34 Columns on GL2, A, B, C 2 12 Oct 09 ave ave Mpa Remarks: Remarks: R2STB 13 Blinding Failed a 5.1 c Passed b 6.7 d 14 Sep 09 CDD Sep 09 ave Mpa Remarks: Remarks: Failed

19 6.8 BS 1881 Part 111 Standard Test Method for Normal Curing Test Specimen (20 ±2 C) The Following apparatus shall be used: a. Curing Tank b. Curing Thermometer The following procedure to conduct the test shall be followed: a. Mark each specimen clearly with an identification number or code. b. Submerged the specimen in the curing tank until they reach the age of test, 7 days and 28 days. c. Maintain the water temperature 20 ±2 o C 6.9 BS 1881 Part116 Standard Test Method for Determination of Compressive Strength of Concrete Cubes The Following apparatus shall be used: a. Compression Testing Machine. b. Auxiliary Platens The following procedure to conduct the test shall be followed: a. Place the cube in the testing machine. Ensure that the testing machine bearing surface are wiped clean and that any loose grit or other extraneous material is removed from the surfaces of the cube which will be in contact with the platens. b. Carefully center the cube on the lower platen and ensure that the load will be applied to two opposite cast faces of the cube. c. Loading. Without shock, apply and increase the load continuously at a nominal rate within the range 0.2N/(mm2.s) to 0.4N(mm2.s) until no greater load can be sustained. d. Record the maximum load applied to the cube Calculation and expression of results: a. Calculate the cross-sectional area of the cube from the nominal dimensions if both lie not more than 1% above or below the nominal cube size. b. If the cube is to be tested between the machine platens and one or both dimensions is or are oversize or undersize by more than 1% of the nominal cube size, calculate the cross-sectional. c. If the cube is to be tested between the auxiliary platens and one or both dimensions is or are oversize by more than 1% of the nominal cube size, calculate the cross-sectional area from the nominal dimensions. d. Calculation of Strength. Calculate the compressive strength of each cube by dividing the maximum load applied to it by the cross-sectional area. Express the results to the nearest 0.5 N/mm² Format attached

20 SITE LABORATORY Client Project Title Project Location HIB CONCRETE STRENGTH TEST RESULTS BS 1881: Part 116 Design and Construction of 2000 Living Units & Public Buildings Alkhoms Project No Date of Test Type of Structure Specimen type Specimen size Lab. Ref. No. Desired Strength Cube 150mm x 150mm x 150mm Specimen # Casting Specimen Density Crushing Compressive Strength Date Weight (kg) (Kg/m³) Load (kn) 7 days 28 days Average Remarks CM/CS Remarks: Test Performed by Test witnessed by 7 days 28 days 7 days 28 days Name & Signature Name & Signature Name & Signature Name & Signature

21 6.10 ASTM C231 Standard Test Methods for Air Content of Freshly Mixed, Concrete by the Pressure Method The Following apparatus shall be used: a. Air Meter Type B b. Measuring Bowl c. Cover Assembly d. Calibration Vessel e. Coil Spring f. Spray Tube g. Trowel h. Tamping Rod i. Mallet j. Strike off Bar k. Strike of Plate l. Funnel m. Measure of Water n. Sieves The following procedure for preparation of test samples shall be followed: a. If the concrete contains coarse aggregate particles that would be retained on a 2-in. (50-mm) sieve, wet-sieve a sufficient amount of the representative sample over a 1-1/2-in. (37.5-mm) sieve. b. Carry out the wet-sieving operation with the minimum practicable disturbance of the mortar. Make no attempt to wipe adhering mortar from coarse aggregate particles retained on the sieve The following procedure to conduct the test shall be followed: a. Placement and Consolidation of Sample Dampen the interior of the measuring bowl and place it on a flat, level, firm surface. b. Place the concrete in the measuring bowl in three layers of approximately equal volume. c. Consolidate each layer of concrete by 25 strokes of the tamping rod evenly distributed over the cross section. d. After each layer is rodded, tap the sides of the measure smartly 10 to 15 times with the mallet to close any voids left by the tamping rod and to release any large bubbles of air that may have been. e. Rod the bottom layer throughout its depth, but the rod shall not forcibly strike the bottom of the measure. f. In rodding the second and final layers, use only enough force to cause the rod to penetrate the surface of the previous layer about 1 in. g. Add the final layer of concrete in a manner to avoid excessive overfilling. h. Strike off the top surface by sliding the strike-bar across the top flange or rim of the measuring bowl with a sawing motion until the bowl is just level full i. Thoroughly clean the flanges or rims of the bowl and the cover assembly so that when the cover is clamped in place a pressure-tight seal will be obtained. j. Closed the air valve between the air chamber and the measuring bowl

22 and open the petcocks on the holes through the cover. k. Using a rubber syringe, inject water through one petcock until water emerges from the opposite petcock. l. Close the air bleeder valve on the air chamber and pump air into the air chamber until the gage hand is on the initial pressure line. m. Stabilize the gage hand at the initial pressure line by pumping or bleeding off air as necessary. n. Close both petcocks on the holes through the cover. Open the air valve between the air chamber and the measuring bowl. o. Lightly tap the pressure gage by hand to stabilize the gage hand. p. Record the percentage of air on the dial of the pressure gauge ASTM C140 Standard Test Methods for Sampling and Testing Concrete Masonry Units and Related Units The following apparatus shall be used: a. Testing Machine b. Steel Scale c. Weigh Scale d. Caliper e. Top and Bottom Bearing Plates The following measurements shall be followed: a. Width mid length, across top & bottom bearing surfaces. b. Length mid height of each faces. c. Height- mid length of each faces The procedure to conduct the test shall be followed: a. Testing machine shall have an accuracy of ±1.0% over the anticipated load range. b. The upper platen shall be a spherically seated, hardened metal block firmly attached at the center of the upper head of the machine. The center of the sphere shall lie at the center of the surface held in its spherical seat but shall be free to run in any direction. c. A hardened metal bearing plate may be used beneath the specimen to minimize wear of the lower platen of the machine. d. When the bearing area of the upper or lower platen is not sufficient to cover the area of the specimen, a single steel bearing plate with a thickness equal to at least the distance from the edge of the platen to the most distant corner of the specimen shall be placed between the platen and capped specimen. e. Test specimen with the centroid of their bearing surfaces aligned vertically with the center of thrust of the spherically seated steel bearing block of the testing machine. f. Apply the load up to one half of the expected maximum load at any convenient rate, after which adjust the controls of the machine as required to give a uniform rate travel of the moving head such that the remaining load is applied in not less than 1 not more than 2 min. g. Record the maximum load Calculation and expression of results:

23 Gross Area Compressive Strength, psi (MPa) = Pmax / Ag Where: Pmax = maximum compressive load, lb(n) Ag = gross area of specimen, in.² (mm²) Format attached

24 SITE LABORATORY TEST REPORT FOR COMPRESSION TEST OF CONCRETE HOLLOW BLOCKS ASTM C140 Client : HIB Name of Project : Design and Construction of 2000 Living Units & Public Buildings Location : Alkhoms Project No. : Lab. Ref. No. : Sampled at : Kind of Sample : Sampled by : Date Tested : Required Strength : Sampled Date : Sample Identification Dimension Gross Fractured Compressive Equivalent Length Width Area Load Strength (cm) (cm) (cm²) (kn) Kgf Kg/cm² Mpa Remarks CM/CS Remarks: Witnessed by: Tested by:

25 6.12 ASTM D1557 Standard test Methods for Laboratory Compaction Characteristics of Soil Using Modified Effort (2700 kn- m/m 3 ) The following apparatus shall be used: a. Molds b. Sieve c. Rammer d. Pan e. Weighing Scale f. Drying Oven The following procedure to conduct the test shall be followed: a. Procedure Approx. mass uses of procedure A 25kg 20% less wt. retained on sieve #4 B 25kg 20% less wt. retained on sieve 3/8 C 45kg More than 20% wt retained on 3/8 and Less than 30% wt ret. on ¾ Format attached b. Procedure A B C Material passing no.4 3/8 ¾ Mold Dia. (inch) Rammer 4.54kg 4.54kg 4.54kg Layer Blows c. Prepare the equipment and tools to be used, record the mass and volume of the compaction mold with base plate but without collar. d. Attached the collar to the mold. e. Pour moist soil in to the mold in 5 equal layers, no. of blows depend which procedure is required for the materials sample. Removed the collar of the mold then clean and weigh the samples and molds. Record data you get. f. Extrude the soil sample from the mold, slice the sample and take at least 500 grams of soil for moisture content determination. g. Repeat the procedure until the weight of the materials reach the maximum dry density. h. Gather the data we ve got, graph data so that we can calculate the maximum dry density and the optimum moisture content.

26 SITE LABORATORY Client Name of project SOIL - LABORATORY COMPACTION TEST ASTM D-1557 : HIB Location : Alkhoms Project No. : : Design and Construction of 2000 Living Units & Public Buildings Kinds of Materials : Date Tested Original Source : Lab. No. Tested by : MOISTURE CONTENT Determination No Container I.D P-2 P-9 P-5 P-6 Container+wet soil,gm Container+dry soil,gm Weight of water, gm Weight of container, gm Weight of dry soil, gm Moisture content DENSITY Determination No Weight of soil+m olds, gm Weight of soil, gm Wet Density, gm./ cc Dry Density, gm./ cc ASTM D Method used Weight of rammer 5kg No. of layer 5 Blows D per layer 56 Weight of mold, gm 6160 y nsit De Volume of mold, cc 2098 Maximum dry density MDD Dry Optimum moisture content OMC MDD OM C Moisture Content % CM/CS Remarks:

27 6.13 ASTM D1556 Standard test Methods for Density and Unit Weight of Soil in Place by the Sand-Cone Method The following apparatus shall be used: a. Chisel b. Sand Cone & Plate c. Hammer d. Weighing Scale e. Plastic bag f. Drying Oven The following procedure to conduct the test shall be followed: a. Determine first the density of a dry sand (calibrated sand) Format attached b. Select a location that is representative of the area to be tested and determine the density of soil. c. Put the sand cone plate, dig the test hole through the center hole in the base plate, being careful to avoid disturbing the soil that will bound the hole. d. Invert the sand cone apparatus and seat the sand cone funnel into the flanged hole. Open the valve and allow the sand to fill the hole. When the sand stops flowing, closed the valve. e. Determine the mass of the apparatus with the remaining sand, record, and calculate the mass of sand in used. f. Determine and record the mass of the moist material that was removed from the test hole. g. From the materials taken from hole get sample for the moisture content. h. Calculate the wet unit weight by dividing materials taken from hole from the volume of hole. i. Calculate the dry unit weight by dividing the wet unit weight over moisture content. j. Then we can get the percent compaction by dividing the actual dry density over maximum dry density from test method ASTM D-1557.

28 SITE LABORATORY SOIL SITE COMPACTION TEST (ASTM D 1556) Client : HIB Name of Project : Design and Construction of 2000 Living Units & Public Buildings Location : Alkhoms Project No. : Date Tested : Kind of Materials : Lab. Ref No. : Representing : Sample Location: UNIT WEIGHT OF AIR DRY SAND 1 Unit weight of dry Sand, g/cc (calibrated) MASS OF SAND TO FILL FUNNEL 2 Mass of Jar + Sand (before pouring), g 3 Mass of Jar + Sand (after pouring), g 4 Sand of Funnel,g ACTUAL MOISTURE CONTENT HOLE Container I.D 6. Container + wet soil, g 7. Container + dry soil, g 8. Moisture Loss, g 9. Weight Container, g 10. Weight of dry soil, g 11. Moisture Content % 12. Average Actual M.C. % ( By Speedy Moisture Tester) FIELD DENSITY 13. Total materials taken from hole 14. Mass of Jar + sand (before pouring), g 15. Mass of Jar + sand (after pouring), g 16. Sand to fill hole, g 17.Volume of hole, g 18. Wet unit weight 19. Dry unit weight 20. Data from compaction test under Lab. No. a. Maximum dry density, g/cc b. Optimum moisture content % 21. % Compaction 22. % Required Compaction CM/CS Remarks: Witnessed by: Tested by:

29 7.0 LIST OF SAMPLING AND TESTING FREQUENCIES 7.1 List attached

30 Project : Design and Construction of 2000 Living Units & Public Buildings Location: Alkhoms District : Almarqab LIST OF QUALITY LABORATORY TESTS WITH THEIR FREQUENCY S# Test Type of test Done by MAKCO (UK LTD) Done by THRID PARTY Method Frequency Remarks Tensile Strength yes 1 Steel reinforcement Bending yes Physical yes 2 Ordinary cement analysis Chemical yes 3 Clay of aggregate, silt and dust yes 4 Organic impurities of aggregate yes BS 4449 / ASTM A615 BS 4449 / ASTM A615 BS 12 / ASTM C114/c150 BS 12 / ASTM C114/C150 BS 882 / ASTM C33 BS 882 / ASTM C40 3 mos./new source 3 mos./new source Every 1250 tons Every 1250 tons 3 mos./new source 3 mos./new source 3 pcs one meter long of every dia. used 3 pcs one meter long of every dia. used 1 bag cement 1 bag cement 5 Chloride content of aggregate yes BS mos./new source 6 Sulphate content of aggregate yes BS mos./new source 7 Potential alkali reactivity yes ASTM C289 3 mos./new source 8 Aggregate grading yes BS 812 / ASTM C136 3 mos./new source 9 Aggregate shape Flakiness index yes BS mos./new source Elongation index yes BS mos./new source 10 Aggregate relative density Water absorption yes BS 812/ASTM C mos./new source Specific gravity yes BS 812/ASTM C mos./new source 11 Aggregate soundnes of sulphate resistance yes ASTM C 88 3 mos./new source 12 Aggregate mechanical properties, 10% fines value or Los Angeles 13 Hollow blocks - Compressive Strength yes 14 Hollow blocks - Fractured Load yes BS 812 / ASTM C131 or ASTM C535 BS / ASTM C 140 BS / ASTM C Concrete sampling yes BS Concrete cubes - Compression test yes BS 1881 Every pcs./new source Every pcs./new source 115 Cu-m /grade ASTM C94 7 and 28 days 17 Concrete - Slump Test yes ASTM C143 every truck load yes 3 mos./new source 3 pcs. per size 3 pcs. per size 9 cubes sample 3 cubes for 7 days 3 cubes for 28 days 18 Concrete - Air Content yes ASTM C231 every trial mix 19 Soil - Laboratory compaction test yes ASTM D 1557 every types of soil 20 Soil - Site Compaction test yes ASTM D 1556 each layer depend on area CM/CS REMARKS: