Gypsum Powder Manufacturing Process

Gypsum Powder Manufacturing Process: Complete Technical Guide for Industrial Production

The Gypsum Powder Manufacturing Process is a multi-stage industrial procedure that converts natural or synthetic gypsum into fine powder suitable for construction, plastering, prefabricated panels, and other applications. Understanding each step in the process is essential for manufacturers seeking stable quality, energy efficiency, and scalable production.

This article provides a detailed breakdown of the gypsum powder manufacturing process, including material preparation, calcination technology, grinding systems, environmental controls, and process optimization strategies.

1. Raw Material Preparation

The process begins with gypsum rock (CaSO₄·2H₂O), which may be mined naturally or recovered from industrial by-products such as flue gas desulfurization (FGD) systems.

Key Objectives:

• Remove impurities

• Reduce particle size

• Stabilize moisture content

Equipment Used:

Proper raw material preparation ensures consistent calcination and prevents equipment overload.

2. Drying and Moisture Control

Moisture content directly affects calcination efficiency. If gypsum contains excessive water, pre-drying may be required.

Drying Methods:

• Rotary dryers

• Hot air systems

• Waste heat recovery systems

Maintaining moisture within controlled limits improves energy utilization during thermal processing.

3. Calcination Process

Calcination is the core stage of the Gypsum Powder Manufacturing Process. During this step, gypsum dihydrate is heated to remove part of its chemically combined water, producing calcium sulfate hemihydrate.

Chemical Reaction:

CaSO₄·2H₂O → CaSO₄·½H₂O + 1.5H₂O (steam)

Calcination Equipment Types:

Temperature control typically ranges between 120°C and 180°C depending on product specification.

4. Grinding and Classification

After calcination, material is ground into fine powder.

Common Grinding Systems:

• Raymond mill

• Ball mill

• Vertical roller mill

Air classifiers are integrated to control particle size distribution, ensuring uniform product quality.

5. Storage and Packaging

Finished gypsum powder is transported pneumatically to storage silos and then packed in:

• 25–50 kg bags

• Bulk tankers

• Jumbo bags

Automated packing systems reduce labor intensity and ensure weight accuracy.

6. Environmental and Dust Control Systems

Dust management is critical in gypsum processing.

Environmental Systems Include:

• Pulse jet bag filters

• Cyclone separators

• Enclosed conveyor systems

Effective dust control protects workers and meets environmental compliance requirements.

7. Process Optimization and Automation

Modern gypsum powder plants incorporate PLC-based control systems to monitor:

• Temperature stability

• Production rate

• Motor load

• Dust concentration

Automation reduces human error and ensures consistent product properties.

8. Role of Hengshui Decheng Machinery & Equipment Co.,Ltd

Hengshui Decheng Machinery & Equipment Co.,Ltd provides integrated solutions for the gypsum powder manufacturing process, including equipment selection, layout planning, installation support, and commissioning guidance. The company focuses on coordinating crushing, calcination, grinding, and environmental systems to maintain stable production performance.

Frequently Asked Questions (FAQ)

Q1: What is the most critical stage in the gypsum powder manufacturing process?
Calcination is critical because it determines setting time and strength characteristics.

Q2: How can energy consumption be reduced?
Using waste heat recovery and efficient calcination systems can significantly reduce fuel costs.

Q3: Can synthetic gypsum be used?
Yes, but process parameters must be adjusted for purity and moisture content.

Q4: How is product fineness controlled?
Through grinding mill configuration and air classification systems.

Technical Insight

Consistency in gypsum powder quality depends on synchronized operation between thermal systems and grinding systems. Minor temperature fluctuations during calcination can significantly alter final product performance. Therefore, precise thermal control and stable material feed are essential for industrial-scale manufacturing.