Injection Rate Calculation in Injection Molding – Cost Calculator

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Injection Rate Calculator

Screw Diameter (mm)

Injection Stroke (mm)

Injection Time (seconds)

Calculation Results:

Theoretical Shot Volume: 0 cm³

Injection Rate: 0 cm³/s

function calculateInjectionRate() { var diameter = parseFloat(document.getElementById('screwDiameter').value); var stroke = parseFloat(document.getElementById('injectionStroke').value); var time = parseFloat(document.getElementById('injectionTime').value); var resultDiv = document.getElementById('injectionResult'); if (isNaN(diameter) || isNaN(stroke) || isNaN(time) || time <= 0 || diameter <= 0 || stroke <= 0) { alert("Please enter valid positive numeric values for all fields."); return; } // Formula: Volume = PI * (Diameter/2)^2 * Stroke // Values are in mm, so Volume is in mm3. Convert to cm3 (divide by 1000) var radius = diameter / 2; var volume_mm3 = Math.PI * Math.pow(radius, 2) * stroke; var volume_cm3 = volume_mm3 / 1000; // Injection Rate = Volume / Time var rate = volume_cm3 / time; document.getElementById('resVolume').innerText = volume_cm3.toFixed(2); document.getElementById('resRate').innerText = rate.toFixed(2); resultDiv.style.display = 'block'; }

Understanding Injection Rate in Injection Molding

In the world of plastic manufacturing, the Injection Rate is one of the most critical process parameters. It defines the volumetric flow rate at which molten plastic is injected into the mold cavity. Mastering this calculation ensures part consistency, reduces internal stresses, and optimizes cycle times.

What is the Injection Rate Formula?

The injection rate is determined by the volume of material moved by the screw and the time it takes to move it. The calculation follows two steps:

Calculate Shot Volume (cm³): V = π × (r²) × S
- r is the screw radius (Diameter / 2) in cm.
- S is the injection stroke in cm.
Calculate Injection Rate (cm³/s): R = V / t
- V is the Shot Volume.
- t is the Injection Time (filling time).

Why is Injection Rate Important?

The speed at which plastic enters the mold affects the physical properties of the finished product. Here is how injection rate impacts the process:

Shear Heating: Higher injection rates increase shear rate, which generates heat. This lowers the viscosity of the plastic, allowing it to flow more easily into thin-walled sections.
Surface Finish: A consistent injection rate prevents "hesitation marks" and "jetting," ensuring a smooth surface finish.
Molecular Orientation: High-speed injection tends to orient polymer molecules in the direction of flow, which can impact the mechanical strength and shrinkage of the part.
Venting: If the injection rate is too high, air trapped in the mold may not escape fast enough, leading to "burn marks" (dieseling effect).

Example Calculation

Suppose you are running a molding machine with the following parameters:

Parameter	Value
Screw Diameter	40 mm (4.0 cm)
Injection Stroke	100 mm (10.0 cm)
Injection Time	2.0 Seconds

Step 1: Calculate Volume.
Radius = 2.0 cm.
Volume = 3.14159 × (2.0²) × 10.0 = 125.66 cm³.

Step 2: Calculate Rate.
Injection Rate = 125.66 cm³ / 2.0 s = 62.83 cm³/s.

Factors Affecting Real-World Injection Rates

While our calculator provides the theoretical rate, several real-world factors can influence the actual performance:

Material Viscosity: Highly viscous materials (like PC) may require more pressure to maintain the desired injection rate compared to low-viscosity materials (like PP).
Check Valve Efficiency: If the non-return valve (check ring) leaks, the actual volume injected will be lower than the calculated theoretical volume.
Machine Response Time: The time it takes for the hydraulics or electric motors to reach the set speed can create a slight discrepancy in very short injection cycles.
Mold Flow Resistance: Thin gates and complex runners increase backpressure, which may limit the machine's ability to maintain a high injection rate.

Frequently Asked Questions

Is injection speed the same as injection rate?
No. Injection speed usually refers to the linear velocity of the screw (mm/s), while injection rate refers to the volumetric flow (cm³/s). Two different machines moving at the same linear speed (mm/s) will have different injection rates if their screw diameters are different.

How do I choose the right injection rate?
It depends on the material and part geometry. Thin-walled parts usually require high injection rates to fill before the plastic freezes. Thick-walled parts often benefit from slower rates to prevent turbulence and internal voids.