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Forming Pressure Calculator

Forming Pressure Calculator — Vacuum & Positive Pressure Thermoforming

Forming Pressure Calculator

Quickly estimate vacuum or positive pressure required to form parts reliably.

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This calculator helps you determine the required vacuum or positive pressure for thermoforming based on sheet thickness, forming area, and material properties. Use it to optimize your forming process and ensure consistent part quality.

Positive pressure is typically used for forming thicker sheets or complex geometries, while vacuum forming is suitable for thinner materials and simpler shapes. The right pressure ensures proper material distribution and minimizes defects.

Input Parameters

Typical range: 0.1 - 10 mm
Typical range: 1 - 20,000 cm²

成果

0.00 bar
Method: Empirical (recommended)
With Safety: 0.00 bar
Material: PET
Empirical Method
Physics Method

Empirical Method (Recommended for Production)

The empirical method uses industry-proven formulas that correlate well with actual production results. It's based on extensive testing and provides reliable pressure values for most common thermoforming applications.

The formula used is:

Preq_emp = (Kmat × tmm) / (√Am × η)

Where:

  • Preq_emp = Required pressure (bar)
  • Kmat = Material coefficient (bar·cm0.5/mm)
  • tmm = Sheet thickness (mm)
  • Am = Forming area (cm²)
  • η = Machine efficiency (decimal, e.g. 0.85 for 85%)

Material Coefficients (Kmat)

材料Kmat (bar·cm0.5/mm)Notes
PET0.12Standard for food packaging
聚丙烯0.10Lower stiffness than PET
PS0.09Easier to form
PLA0.11Biodegradable alternative
聚氯乙烯0.13Higher stiffness

Note: These coefficients are starting points and should be calibrated with your specific equipment and material batches.

Physics Method (For Engineering Verification)

The physics-based method provides a theoretical foundation for understanding the forces involved in thermoforming. While more complex, it's useful for validating empirical results and understanding edge cases.

The simplified physical model is:

Preq_phys = (σy × t) / (C × R)

Where:

  • Preq_phys = Required pressure (bar)
  • σy = Effective yield strength at forming temperature (N/mm²)
  • t = Sheet thickness (mm)
  • R = Characteristic length (e.g., √A or effective radius, mm)
  • C = Constant accounting for friction and deformation mode

Material Properties at Forming Temperature

材料σy (N/mm²)Typical Forming Temp (°C)
PET2.5 - 3.590 - 110
聚丙烯1.8 - 2.5140 - 160
PS1.5 - 2.0110 - 130
PLA2.0 - 3.060 - 80
聚氯乙烯3.0 - 4.0110 - 130

Note: The physics method typically gives a pressure range rather than a single value due to material property variations and assumptions in the model.

  • Thermoforming Process

    See how our calculator helps optimize pressure settings for perfect thermoforming results.

  • 材料选择

    Choose from various materials with pre-configured properties for accurate calculations.

  • Pressure Optimization

    Get precise pressure recommendations for vacuum, positive, and hybrid forming modes.

Example Calculations

Here are some typical forming scenarios with recommended pressure values:

Shallow Lunch Tray

Thickness: 0.8 mm
Area: 600 cm²
Material: 聚丙烯
Mode: Vacuum
Recommended pressure: ~0.25 bar

Clamshell Container

Thickness: 1.0 mm
Area: 300 cm²
Material: PET
Mode: Positive
Recommended pressure: ~0.35 bar

Deep Dome

Thickness: 1.5 mm
Area: 200 cm²
Material: PET
Mode: Hybrid
Recommended pressure: ~0.8 bar

常见问题

What happens if the pressure is too low?

Insufficient pressure can result in incomplete forming, poor detail reproduction, uneven wall thickness, and weak spots in the final product. The material may not properly conform to the mold, leading to defects like webbing or bridging between high points.

What are the risks of too high pressure?

Excessive pressure can cause material thinning, especially in corners and deep draws. It may lead to tearing, increased cycle times (as the material needs more time to cool under pressure), and higher energy consumption. In vacuum forming, too much pressure can distort fine details or cause the mold to shift.

How does material affect required pressure?

Stiffer materials (like PET and PVC) generally require higher forming pressures than more flexible materials (like PP and PS). The material's melt strength and elongation properties at forming temperature significantly influence the pressure needed for proper forming.

Why include a safety factor?

The safety factor accounts for variations in material properties, machine performance, and environmental conditions. It ensures reliable forming even with minor fluctuations in these parameters. A typical safety factor of 15-20% is recommended for most applications.

How to adjust for large forming areas?

For large areas, consider segmenting the mold into multiple cavities, increasing sheet thickness, or using higher pressure machines. The pressure required increases with the square root of the forming area, so large areas can quickly require impractical pressure levels.

How to validate these calculations?

Start with the calculated pressure and perform test runs with your specific material batch and equipment. Measure part quality (wall thickness distribution, detail reproduction) and adjust the pressure as needed. Document successful settings for future reference.

Need Help With Your Specific Application?

Our engineering team can provide customized forming recommendations and machine specifications for your production needs.

Contact Our Engineers
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