There are many reasons why off-center gates happen, and processors should be aware of all of them to quickly find the ones causing the problem.

Bottle with an off-center gate. The lower of the red circles shows the center of the bottom insert of the mold. The higher one shows where the gate ended up after blowing.

Preform mandrel with three segments. The segments hold the preforms concentric as they travel through the ovens.

Typical setup on a continuous-motion linear machine with passive rotation. The belt can be adjusted to push against the gears, but should not push hard enough to cause side-stress against the bearing.

When the preform is stretched into the blow mold, the vestige of the injection molding process, mostly referred to as a gate, must be placed and held in the center of the bottom insert of the mold. If this does not happen, the side to which the gate is pushed becomes thicker, and, consequently, the other side will be thinner. This is simply the effect of shorter and longer paths of the preform wall to reach the blow mold wall.

With bottles becoming lighter and thinner as a result of cost-cutting measures as well as environmental concerns (“carbon footprint”), the drive to reduce the resulting wall-thickness variances is ever more paramount for a successful PET bottle operation.

 •  Incorrect Stretch Rod Adjustment: The stretch rod must push and securely hold the preform to the bottom insert. This is accomplished by adjusting the stretch rod about 1 mm (0.040-in.) lower to the base than the thickness of the preform at the gate.

 •  Pre-Blow Pressure Too Early and/or Too High: As the stretch rod descends, pressure lower than the final blow pressure is activated to prevent the preform from collapsing and to impart a desired wall thickness to various regions of the bottle. If the pressure comes on early and is high enough to push the preform off the rod, the gate will always go off-center. A test without high-pressure blow, the so-called “pre-blow audit,” can reveal this problem, which is easily fixed by reducing the pre-blow pressure or delaying its onset. The pre-blow audit will reveal the correct pressure to inflate the preform to form a bubble but not yet reaching the mold walls.

 •  Preform Bent Before Stretching: This problem is most often found in single-stage stretch-blow molding when the preform has uneven heat around its circumference imparted by the hot runner. In this case the heater bands should be examined and possibly turned to ameliorate it. If it happens in two-stage molding, see the next bullet point.

 •  Preforms Not Rotating Completely in the Oven: There are two systems in place to guarantee rotation of the preforms:

 1.  Actively rotating a gear on a chain that is connected to the mandrel. This is most often used in machines where the preforms travel though the ovens upside down.

 2.  Passive rotation by letting a gear (often made of plastic) connected to the mandrel slide along a grooved belt, forcing rotation. This is more commonly used on modern machines. In either case it is important that the engagement of the gear is guaranteed over the entire oven length. But engagement cannot be too much, as pushing against the gear would put stress on the bearings leading to premature failure.

Over time the bearings may slowly fail or be impacted by dirt or oil, and some of the mandrels may not turn all the time. It is also possible that the belt will have some slack in certain spots and be fine in others. This can be hard to spot, as the areas inside the oven where this happens may be visible only when certain covers have been removed. The result, however, can be dramatic. When one side of the preform stays much colder than the other, it can—and will—rip the gate vestige out of the base-insert well, even when there is 1-mm interference between stretch rod and base insert.

This problem may be hard to find because the rotation may be inconsistent with only a few spindles sometimes involved. This leads then to intermittent problems in possibly a number of cavities:

 •  Preforms Not Concentric on the Spindles: A similar problem occurs when the preforms “wobble” on the mandrels. This is typical on machines where preforms travel upside down on simple mandrels whose diameter must be smaller than the smallest preform ID in order not to cause infeed jams. Machines where preforms travel right-side up must have better holders to prevent the preforms from falling down. As a side effect, these holders also make sure the preforms rotate evenly. There are a number of designs, most of which consist of three or four segments that have some elasticity to accommodate tolerances in preform IDs.

 •  Well in Bottom Insert Missing: Every bottom insert of the mold must have a well to accommodate the vestige of the injection process. Only with a well can it be avoided that the gate slips on the curved surface of the bottom insert.

1500ml Bottle Blowing Machine

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