Standard Test Procedures Manual

Similar documents
Standard Test Procedures Manual

Standard Test Procedures Manual

Standard Test 1. SCOPE Description of Test

Standard Test Procedures Manual

Stress Strain Relationships

Objectives. Experimentally determine the yield strength, tensile strength, and modules of elasticity and ductility of given materials.

Tensile Testing Laboratory

Standard Test Procedures Manual

METU DEPARTMENT OF METALLURGICAL AND MATERIALS ENGINEERING

SHORE A DUROMETER AND ENGINEERING PROPERTIES

Apr 17, 2000 LAB MANUAL

15. MODULUS OF ELASTICITY

Precision Miniature Load Cell. Models 8431, 8432 with Overload Protection

Treatment of a surface or structure to resist the passage of water in the absence of hydrostatic pressure. presence of hydrostatic pressure.

Tensile Testing of Steel

Long term performance of polymers

Solution for Homework #1

LABORATORY EXPERIMENTS TESTING OF MATERIALS

PENETRATION OF BITUMINOUS MATERIALS

Solid Mechanics. Stress. What you ll learn: Motivation

PROPERTIES OF MATERIALS

3. Test Methods for Evaluation of ESCR of Plastics

σ y ( ε f, σ f ) ( ε f

Testing and appraisal of Lucobit polymer effect as an additive on asphalt mixture performance

INJECTION MOLDING COOLING TIME REDUCTION AND THERMAL STRESS ANALYSIS

HAMBURG WHEEL-TRACKING TEST

DIGITAL DISPLACEMENT RISING STEP LOAD LRA/RSL TEST EQUIPMENT

Mechanical Properties of Metals Mechanical Properties refers to the behavior of material when external forces are applied

Material property tests of Smooth-on Vytaflex60 liquid rubber

Numerical Analysis of Independent Wire Strand Core (IWSC) Wire Rope

COMPACTING BITUMINOUS SPECIMENS USING THE SUPERPAVE GYRATORY COMPACTOR (SGC)

Hardened Concrete. Lecture No. 14

CEEN Geotechnical Engineering Laboratory Session 7 - Direct Shear and Unconfined Compression Tests

Chapter Outline. Mechanical Properties of Metals How do metals respond to external loads?

Introduction to Mechanical Behavior of Biological Materials

T A B L E T 1 T E S T S A N D I N S P E C T I O N C A B L E P C U T A N D P C U T - A

Objective To conduct Charpy V-notch impact test and determine the ductile-brittle transition temperature of steels.

Description of mechanical properties

Problem Set 1 Solutions to ME problems Fall 2013

Physical Properties of a Pure Substance, Water

Physics 3 Summer 1989 Lab 7 - Elasticity

EDEXCEL NATIONAL CERTIFICATE/DIPLOMA MECHANICAL PRINCIPLES OUTCOME 2 ENGINEERING COMPONENTS TUTORIAL 1 STRUCTURAL MEMBERS

A H M 531 Penetration & Ring & Ball & Ductility & Flash & Fire point By: Mu'men Al-Otoom

Naue GmbH&Co.KG. Quality Control and. Quality Assurance. Manual. For Geomembranes

ADHESIVE BONDING PERFORMANCE OF GA COATED 590 MPa TENSILE STRENGTH STEELS

LABORATORY DETERMINATION OF CALIFORNIA BEARING RATIO

CHAPTER 6 WEAR TESTING MEASUREMENT

ANALYTICAL AND EXPERIMENTAL EVALUATION OF SPRING BACK EFFECTS IN A TYPICAL COLD ROLLED SHEET

In-situ Load Testing to Evaluate New Repair Techniques

M n = (DP)m = (25,000)( g/mol) = 2.60! 10 6 g/mol

GENERAL SCIENCE LABORATORY 1110L Lab Experiment 5 THE SPRING CONSTANT

Environmental Stress Crack Resistance of Polyethylene Pipe Materials

MCE380: Measurements and Instrumentation Lab. Chapter 9: Force, Torque and Strain Measurements

Mechanical Properties and Fracture Analysis of Glass. David Dutt Chromaglass, Inc.

STUDY OF THE BEHAVIOUR OF BITUMINOUS MIXTURES RESISTANT TO FUEL

STANDARD REQUIREMENTS FOR BONDING OR MECHANICAL ATTACHMENT OF INSULATION PANELS AND MECHANICAL ATTACHMENT OF ANCHOR AND/OR BASE SHEETS TO SUBSTRATES

THE IMPACT OF YIELD STRENGTH OF THE INTERCONNECTOR ON THE INTERNAL STRESS OF THE SOLAR CELL WITHIN A MODULE

ME 612 Metal Forming and Theory of Plasticity. 3. Work Hardening Models

The atomic packing factor is defined as the ratio of sphere volume to the total unit cell volume, or APF = V S V C. = 2(sphere volume) = 2 = V C = 4R

Structural Integrity Analysis

STRESS AND DEFORMATION ANALYSIS OF LINEAR ELASTIC BARS IN TENSION

EDEXCEL NATIONAL CERTIFICATE/DIPLOMA MECHANICAL PRINCIPLES AND APPLICATIONS NQF LEVEL 3 OUTCOME 1 - LOADING SYSTEMS TUTORIAL 3 LOADED COMPONENTS

SIEVE ANALYSIS OF FINE AND COARSE AGGREGATES

50 C (122 F) Settlement, 5 days, % Storage Stability Test, 24 hours, % (2) 1 max. 1 max. 1 max. 1 max.

ENGINEERING COUNCIL CERTIFICATE LEVEL

Sheet metal operations - Bending and related processes

SOIL-LIME TESTING. Test Procedure for. TxDOT Designation: Tex-121-E 1. SCOPE 2. APPARATUS 3. MATERIALS TXDOT DESIGNATION: TEX-121-E

NOTCHES AND THEIR EFFECTS. Ali Fatemi - University of Toledo All Rights Reserved Chapter 7 Notches and Their Effects 1

STRAIN-LIFE (e -N) APPROACH

A Study of Durability Analysis Methodology for Engine Valve Considering Head Thermal Deformation and Dynamic Behavior

Bending, Forming and Flexing Printed Circuits

VOLUME AND SURFACE AREAS OF SOLIDS

Appendix H Interscience Communications. Reprinted with permission.

Activity 2.3b Engineering Problem Solving Answer Key

MECHANICS OF MATERIALS

MECHANICAL PRINCIPLES HNC/D PRELIMINARY LEVEL TUTORIAL 1 BASIC STUDIES OF STRESS AND STRAIN

Force measurement. Forces VECTORIAL ISSUES ACTION ET RÉACTION ISOSTATISM

DETERMINING DENSITY OF COMPACTED BITUMINOUS MIXTURES

ASTM D 1599 Standard Test Method for Resistance to Short-Time Hydraulic Pressure of Plastic Pipe, Tubing, and Fittings

Lab for Deflection and Moment of Inertia

Standard Test Procedures Manual

RESIDENTIAL ROOFING & RE-ROOFING, ROOF VENTILATION AND ROOF SHEATHING REQUIREMENTS MICHIGAN RESIDENTIAL CODE 2000

Weight Measurement Technology

SPECIFIC GRAVITY OF COARSE AGGREGATE AASHTO T 85

ANALYSIS OF GASKETED FLANGES WITH ORDINARY ELEMENTS USING APDL CONTROL

Subminiature Load Cell Model 8417

9. TIME DEPENDENT BEHAVIOUR: CYCLIC FATIGUE

Apr 17, 2000 LAB MANUAL PARTICLE SIZE ANALYSIS OF SOILS AASHTO Designation T 88 (Mn/DOT Modified)

Impact testing ACTIVITY BRIEF

Torsion Tests. Subjects of interest

CH 6: Fatigue Failure Resulting from Variable Loading

4 Thermomechanical Analysis (TMA)

Chemistry 212 VAPOR PRESSURE OF WATER LEARNING OBJECTIVES

Laboratory Evaluation of Asphalt Rubber Mixtures Using the Dynamic Modulus (E*) Test

Bending Stress in Beams

TIE-31: Mechanical and thermal properties of optical glass

HW 10. = 3.3 GPa (483,000 psi)

ROOFING APPLICATION STANDARD (RAS) No. 150 PRESCRIPTIVE BUR REQUIREMENTS

TECHNICAL DATA SHEET

Lap Fillet Weld Calculations and FEA Techniques

Transcription:

STP 203-19 Standard Test Procedures Manual Section: 1. SCOPE 1.1. Description of Test The Force Ductility test is a measure of the tensile properties of the polymer modified asphalt cement residue of a polymer modified emulsified asphalt. 1.2. Unit of Measure The force ductility is measured by determining the load/time relationship for a test specimen, then evaluating this relationship to determine the force required to maintain a specific elongation rate of a test sample, at a certain elongation, at a specific temperature. 2. APPARATUS AND MATERIALS 2.1. Equipment A water bath and thermometers conforming to the specifications described in ASTM Designation D113-86. Molds for the test specimen conforming to the specifications described in ASTM Designation D113-86 except that it is necessary to use molds with straight sides to produce a test specimen of constant cross section. A testing machine as described in ASTM Designation D113-86 including force cells that are to be placed in direct line with the test specimen such that the load applied to the test specimen will be transmitted directly to the load cells. Minimum load cell resolution shall not be greater than 1% of maximum specimen load. A data acquisition apparatus to continuously record load output from the load cell as the test proceeds. A real time analog chart recorder can be used or more sophisticated data acquisition systems which convert analog signals to digital for later processing by microcomputer. Date: 1992 05 21 Page 1 of 4

3. PROCEDURE 3.1. Sample Preparation The sample shall consist of the asphalt cement residue obtained from the distillation of a polymer modified emulsified asphalt. 3.2. Equipment Preparation Assemble the mold on a flat and level brass or glass plate thoroughly coat the surface of the plate and the inside surfaces of the middle brass spacers with a thin layer of a mixture off glycerin and talc to prevent the test material from sticking. Strain the melted sample through a 300 mm sieve. 3.3. Testing Procedure After a thorough stirring pour the sample in the mold. In filling the mold, take care to pour the material in a stream back and forth from end to end until the mold is more than level full. Take care not to disarrange the parts and thus distort the specimen. Allow the test specimen to cool to room temperature for 15 minutes and then place in a water bath at 4 o C for 15 minutes. Remove the test specimen from the water bath and cut off excess bitumen with a hot, straight edged putty knife or spatula to make the mold just level full. Place the trimmed specimen and mold back in the water bath at 4 o C for 30 minutes prior to testing. Remove the test specimen from the plate by a shearing action between the specimen and plate, avoiding any bending of the test specimen. Detach the side pieces and attach the specimen to the pins. Position the crosslead and ensure that the load cells are attached to the specimen. Set the elongation rate for 5 cm/min. Page: 2 of 4 Date: 1992 05 21

Start the strip chart recorder and engage the drive when the recorder pen reaches a major division. This records the relationship between load and time. Elongate the specimen for 100 cm or until the test specimen ruptures. While the test is being made, the water in the tank of the testing machine shall cover the specimen both above and below by at least 2.5 cm and shall be kept continuously at the temperature of 4 o C +.5 o C. Refer to the relationship between load and time and determine the load in kg at 800% elongation at the elongation rate 5 cm/minute at a test temperature of 4 o C. Report this value. 3.4. Additional Testing The relationship between time of test and strain shall be evaluated prior to testing using a sample of the test material. This may be accomplished by measuring the rate at which two gage marks on the surface of the specimen diverge during testing. Gage marks should be located on the surface of the specimen by centering within the confines of the side pieces to provide a gage length of 3 cm. Strain rate shall be determined for each material evaluated. This information is used in determining the Engineering Stress-Strain relationship. From this additional testing other information may be obtained from the original test. The following is a summary. Engineering Stress-Strain: convert the load-time curve to an engineering stress-strain curve. Engineering stress is calculated by dividing load at any point during the test by the original specimen cross-section of 1 sq. cm. Engineering strain is obtained by multiplying the deformation rate by the time at any moment during the test. Plot engineering stress as a function of engineering strain. Evaluate maximum engineering stress and strain. True Stress-Strain: convert the engineering stress-strain curve to a true stress-strain curve. True stress is calculated as the ratio of load to the specimen cross-sectional area at any given time. True strain is the sum of all the engineering strains, which can be calculated by taking the logarithm of (1 + engineering strain). Plot true stress as function of true strain. Evaluate maximum true stress and strain. Asphalt Modulus: determine the slope of the stress-strain curves in the linear portion after initial loading and prior to initial load decline. Date: 1992 05 21 Page: 3 of 4

Asphalt-Modifier Modulus: determine the slope of the true stress-strain curve in the linear portion after initial load decline and during secondary loading, prior to secondary load decline. Area Under Stress-Strain Curve: calculate the area under either stress-strain curve described above. Record this area as the work required to fail the test specimen in tension, or that required to elongate the test specimen the full length of 100 cm. 4. ADDITIONAL INFORMATION 4.1. Precautions Change in readings may be noticed when immersing the test specimen into the water bath which is at a lower temperature than room temperature. This change should not be excessive and the zero adjustment maybe used to compensate for this change. Do not immerse the FD-4 beyond the marking on the base. A one inch safety margin is allowed to protect the LVDT. If a maximum pull of 66.7 Newtons is exceeded, the elastic limit of the springs may be exceeded and permanent deformation may result. 4.2. References ASTM Designation D113-86, Standard Test Method for Ductility of Bituminous Materials, Volume 4.03 ASTM Proposed Designation, Force-Ductility of Bituminous Materials Page: 4 of 4 Date: 1992 05 21

APPROVAL SHEET New Revision X Date of Previous Document 91-03-19 Effective Date: - - Description of Revision (Reason for Revision): Format of test procedure updated. Review/Implementation Process: Reviewed by the Materials Section of the Technical Standards and Policies Branch. Other Manuals/Policies Affected: Nil Follow Up/Training Required: Nil Comments/Concerns/Implications (Budget/Environment/Stakeholders): Prepared and Recommended by D. MacLeod 92-05-21 Quality Control Engineer Date Approval Recommended by R.A. Widger 92-07-21 Senior Materials Engineer Date Approval Recommended by A.R. Gerbrandt 92-07-23 Dir., Technical Standards & Policies Br. Date Approved by D.G. Metz 92-07-25 Assistant Deputy Minister, Infrastructure Date Electronic File Updated 94-03-09 Update Mailed - - Date: 1992 05 21 Page: 5 of 4

2024 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information