IS Glass Container Machine Product

Overview

An Individual Section (IS) machine is the workhorse of industrial glass container production, capable of forming thousands of bottles, jars, and cosmetic containers daily with minimal human intervention. The machine uses a molten glass delivery system, multiple mold cavities, and pneumatic forming and cooling to achieve rapid production cycles at high throughput.

The term "Individual Section" refers to each independent forming station—each with its own plunger, blank mold, and blow mold—operating in synchronized rotation. A four-section IS machine, for example, simultaneously processes four gobs, allowing one container to be manufactured every quarter of a revolution, resulting in a continuous stream of finished product.

How It Works

Molten glass (1000–1200 °C) flows from the melting furnace into the Gob Distributor. The Metering Shutter pneumatically gates the glass flow, and the Shear Blade cuts individual gobs at precise weights (typically 20–100 grams, depending on the final container size). Each gob falls into a cavity on the Invert Mechanism—a rotating carousel that indexes through the forming process.

At the first station, the gob lands in a Blank Mold Section cavity. The Plunger descends, compressing the hot glass into the cavity shape. Simultaneously, inside blow air (2–8 bar) admitted through the Plunger Air Valve distributes the glass evenly and begins to inflate it. The Cavity Cooling Jacket rapidly cools the mold, setting the preform shape in approximately 1–2 seconds.

The carousel then indexes to the next section, rotating the partially formed preform (still at 600–800 °C) to the Blow Mold Section. Here, the plunger retracts, and high-pressure outside blow air (3–10 bar) injected through the Blow Air Valve expands the preform to its final shape, precisely matching the blow mold cavity. The glass is held under pressure for 2–3 seconds while intensive cooling via the Mold Cooling Circuit sets the final shape and wall thickness.

The Mold Cooling Circuit, driven by the Coolant Pump, circulates water at 40–80 °C through drilled passages in the Cavity Cooling Jacket. A Cooling Tower or chiller rejects the thermal load (500–1000 kW) back to ambient. The Flow Control Valve maintains stable temperature, a critical control variable because mold temperature directly affects container wall thickness and product quality.

After blow molding, the Take-Out Mechanism pushes the finished hot container (200–300 °C) from the blow cavity onto the Discharge Conveyor. The container travels to an annealing lehr, where it is gradually cooled to room temperature over 20–30 minutes, relieving internal thermal stresses.

Pneumatic Integration

The Air Supply System is critical. The Air Compressor, typically a 30–50 kW rotary screw unit, delivers 500–800 scfm (standard cubic feet per minute) at 7–10 bar into the Air Receiver. The Air Dryer removes moisture to prevent condensation inside cavities, which would cause surface defects. The Pressure Regulator independently controls inside blow and outside blow pressures, both critical to wall thickness uniformity.

Synchronization and Control

The entire machine is driven by the Main Motor, typically 20–50 kW, which spins the Main Gearbox at constant speed. Embedded in the gearbox is the Timing Cam, a mechanical profile that controls vertical plunger motion. As the carousel rotates, the rotating plunger rods are guided by the cam profile, which drives them up and down at precisely timed intervals synchronized to the gob distribution and mold positions.

Modern IS machines add electronic PLC control over the solenoids, allowing programmable inside blow and outside blow pressure profiles, gob weight adjustments, and cycle timing for different container shapes without mechanical changeover—only cavity molds need to be swapped.

Container Quality and Production

A well-tuned IS machine produces containers with wall thickness uniformity typically ±0.2 mm, and zero internal stress (owing to proper annealing). Defect rates are typically 2–5% (including minor chips, thin walls, or slight surface marring) on a well-maintained machine. Most defects result from mold wear or thermal imbalance; preventive maintenance of cavity cooling water and periodic mold cavity refinishing are essential.

Production rates vary by container size: a large bottle (500 mL) might be made at 60 bottles/min on a four-section machine, while small cosmetic jars (50 mL) achieve 200+ pieces per minute. Total throughput scales linearly with the number of sections: an eight-section machine produces approximately twice as many containers per hour.

Variants and Product Range

IS machines can produce a wide range of shapes: beer and wine bottles, food jars, pharmaceutical vials, cosmetic jars, and oil bottles. Shape changes require mold cavity swaps (typically 1–2 hours per product changeover). Some glass plants operate dozens of IS machines in parallel, each running a different container size or color, feeding multiple downstream annealing and inspection lines.