ASTM E18 Test Methods for Rockwell Hardness of Metallic Materials
The Rockwell indentation hardness principle is used to determine the Rockwell hardness and Rockwell superficial hardness of metallic materials in ASTM E18. The specifications for Rockwell hardness machines and the processes for performing Rockwell hardness tests are outlined in this method.
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- Overview
- Scope, Applications, and Benefits
- Test Process
- Specifications
- Instrumentation
- Results and Deliverables
Overview
ASTM E18 is the standard test method for assessing the Rockwell hardness of metallic materials. This indentation hardness test evaluates a material’s resistance to permanent deformation by applying an indenter (diamond or spherical) to its surface under predetermined loads, then measuring the permanent indentation depth to obtain a hardness value, which is crucial for quality control and material selection. The permanent indentation depth is then measured to determine a hardness value, which is crucial for material selection and quality control. To provide information on tensile strength, wear resistance, and ductility, the test applies a preliminary (minor) load, a total (major + minor) load, and measures the permanent indentation depth after removing the major load.
Scope, Applications, and Benefits
Scope
ASTM E18 is an indentation hardness test that can be used to determine the hardness of metallic materials. This data could relate to tensile strength, wear resistance, ductility, and other physical properties of metallic materials and could be valuable for quality control and material selection.
Applications
- Quality control of steel, aluminum, copper, and alloys
- Verification of heat treatment processes
- Inspection of machined and finished components
- Material selection and process validation
- Routine testing in manufacturing and R&D laboratories
- Acceptance testing for engineering and structural materials
Benefits
- Provides quick and direct hardness measurement
- Ensures high repeatability and reproducibility.
- Requires minimal specimen preparation.
- Suitable for production control and inspection.
- Applicable to soft, medium, and hard metals.
- Uses standardized scales for global comparability
Testing Process
Specimen Preparation
Ensure the test surface is clean, flat, and properly supported; select the correct Rockwell scale.
1Minor Load Application
Apply the specified minor load to seat the indenter and establish the zero reference.
2Major Load Application
Apply the major load for the required dwell time, then remove it while maintaining the minor load.
3Hardness Measurement
Read and record the Rockwell hardness value from the indicator or digital display.
4Technical Specifications
| Parameter | Details |
|---|---|
| Hardness scales | Rockwell A, B, C and other applicable scales |
| Minor load | 10 kgf |
| Major loads | 60, 100, or 150 kgf |
| Specimen condition | Smooth, clean, and flat surface |
| Minimum thickness | As per ASTM E18 requirements |
| Result format | Rockwell hardness value with scale (e.g., HRC) |
Instrumentation Used
- Rockwell hardness testing machine
- Diamond cone (Brale) or hardened steel ball indenter
- Load the application and the control mechanism
- Specimen anvil or support table
- Hardness indicator or digital readout system
Results and Deliverables
- Determines the Rockwell hardness number of the metallic material.
- Hardness value is reported with the appropriate Rockwell scale (e.g., HRA, HRB, HRC).
- Reflects the material’s resistance to permanent indentation.
- Enables comparison of hardness between different metallic materials or batches.
- Confirms material consistency and quality after processing or heat treatment.
- Provides repeatable and reliable hardness data for quality control and inspection.
Frequently Asked Questions
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