Description |
1 online resource |
Series |
Mechanical engineering theory and applications |
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Mechanical engineering theory and applications.
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Contents |
MILLING ; MILLING ; CONTENTS ; PREFACE ; HARD-MILLING USING CARBIDE CUTTERS: EXPERIMENTAL INVESTIGATION AND OPTIMIZATION ; ABSTRACT; 1. INTRODUCTION ; 1.1. Benefits of High-Speed Milling ; 1.2. Hard-Milling ; 1.3. Specific Benefits Offered by Hard-Milling ; 1.4. Tooling for Hard-Milling ; 1.5. Literature Survey Related to Hard-Milling ; 1.6. Challenges in Hard-Milling Domain ; 2. ANALYSES OF TOOLING PARAMETERS ; 2.1. Design of Experiments ; 2.1.1. Predictor Variables ; 2.1.2. Response Variables ; 2.1.3. Fixed Parameters ; 2.2. Experimental Setup |
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2.2.1. Characteristics of Workpiece and Tool Materials 2.3. Results and Discussion ; 2.3.1. Tool Life; 2.3.2. Progress of Tool Wear ; 2.3.3. Tool Wear Mechanisms ; 2.3.4. Surface Roughness ; 2.3.5. Cutting Forces ; 3. ANALYSES OF HELIX ANGLE, WORKPIECE MATERIAL HARDNESS, MILLING-ORIENTATION, AND MQL; 3.1. Design of Experiments; 3.1.1. Predictor Variables ; 3.1.2. Response Variables ; 3.1.3. Factorial Design of Experiments ; 3.1.4. Experimental Setup ; 3.1.5. The Fixed Cutting Parameters ; 3.2. ANOVA and Numerical Optimization ; 3.2.1. Tool Life ; 3.2.2. Side Surface Roughness |
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3.2.4. End Surface Roughness 3.2.5. Cutting Forces ; 3.3. Tool Wear Mechanisms ; 4. ANALYSES OF CUTTING PARAMETERS ; 4.1. Response Surface Methodology for Design of Experiments ; 4.1.1. Predictor and Response Variables ; 4.1.2. The Fixed Parameters ; 4.2. Experimental Results, ANOVA, Regression, and Optimization ; 4.2.1. Tool Life ; 4.2.2. Averaged Arithmetic End Surface Roughness Measured Along Feed Direction ; 4.2.3. Averaged Arithmetic End Surface Roughness Measured Across Feed Direction ; 4.3. Progress of Tool's Flank Wear and Effect of MQL ; 4.4. Tool Wear Mechanisms |
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5. BALL NOSE MILLING: INFLUENCE OF WORKPIECE INCLINATION ANGLE, WORKPIECE MATERIAL, AND CUTTING PARAMETERS5.1. Response Surface Methodology for Design of Experiments ; 5.1.1. The D-Optimal Method ; 5.1.2. Predictor and Response Variables ; 5.1.3. The Fixed Parameters ; 5.2. Experimental Results, ANOVA, Regression, and Optimization Tool Life ; 5.2.1. Averaged Arithmetic Surface Roughness Measured Along Feed Direction ; 5.2.2. Averaged Arithmetic Surface Roughness Measured Across Feed Direction ; 5.3. Tool Wear Mechanisms ; CONCLUSION ; REFERENCES |
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A REVIEW ON MOTIONS OF VIAL AND CHARGE MATERIALS AND ENERGY TRANSFER IN MECHANICAL MILLING ABSTRACT ; 1. MECHANICAL MILLING PRINCIPLE ; 2. PROCESS VARIABLES ; 2.1. Types of Work Material ; 2.2. Particle Size of Work Material ; 2.3. Types of Milling Apparatus; 2.4. Rotational and Revolutional Speeds ; 2.5. Filling Ratio ; 2.6. Ball to Powder Mass Ratio (BPMR) ; 2.7. Ball Size ; 2.8. Milling Environment ; 2.9. Milling Temperature ; 3. THE MOTION OF CHARGE MATERIALS AND VIAL ; 3.1. Types of Motion of Charge Materials and Vial ; 3.2. Ball Thrown Method ; 3.3. Agitation Method |
Bibliography |
Includes bibliographical references and index |
Notes |
English |
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Description based on print version record |
Subject |
Grinding and polishing.
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Mills and mill-work.
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TECHNOLOGY & ENGINEERING -- Mining.
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Grinding and polishing
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Mills and mill-work
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Form |
Electronic book
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Author |
Filipovic, Lovro A., editor
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LC no. |
2020678442 |
ISBN |
9781621000129 |
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1621000125 |
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