Patent ID: 8635836
Filing Date: 2014-01-28
Classification: B29C,B31D

Abstract:
1. An air cushion manufacturing machine, comprising: a machine body, having a cover installed to the top side of the machine body and liftable to the rear side of the machine body, and an inlet and an outlet formed at both ends of the machine body respectively; a film supply unit, installed at the inlet of the machine body, for allowing a double-layer film with a sealed side and an open side to enter between the top side of the machine body and the cover, and the double-layer film being inflated by an inflating element; a motor, installed in the machine body, and having a main shaft for outputting kinetic power; a transmission device, driven by the motor, for driving the operation of a plurality of motion mechanisms; a feed unit, separately installed on the top side of the machine body and the bottom side of the cover, and driven by the transmission device, for driving the double-layer film to feed towards the outlet; a sealing device, having a plurality of heat sealers, separately installed at the outlet on the top side of the machine body and the front of the machine body, for performing lateral and transverse heat sealing processes to the inflated double-layer film when the double-layer film stops its feeding; and a power supply, for supplying electric energy required by the sealing device, such that the electric energy is converted into heat energy required by the heat sealer, characterized in that the power supply is coupled to a solid state relay (SSR), and the solid state relay controlled by the processor compensates the heat loss of the sealing according to the cycle of the sealing process and a power-on time percentage is controlled to produce a punctuate periodic micro heating to the heat sealer to achieve a constant-temperature heat compensation for each sealing course of the heat sealer; wherein the main shaft of the motor includes an active bevel gear; and the transmission device further comprises: a power multidirectional mechanism, for engaging a first driven bevel gear installed at the first driven shaft and a second driven bevel gear installed at the second driven shaft with the active bevel gear, and having a third driven shaft installed on the same axis of the main shaft and dynamically coupled to the main shaft; a swing motion mechanism, for pivotally coupling an end of a first crank to the first driven shaft, an end of a first link rod to the other end of the first crank, and the other end of the first link rod to a lateral of a swing gear; a first reciprocating motion mechanism, for pivotally coupling an end of a second crank to the second driven shaft, an end of a second link rod to the other end of the second crank, and the other end of the second link rod to the bottom of a first elevating stand; and a second reciprocating motion mechanism, for pivotally coupling an end of a third crank to the third driven shaft, an end of a third link rod to the other end of the third crank, and the other end of the third link rod to the bottom of the second elevating stand; the feed unit further comprises: a plurality of upper and lower feed rollers, with roller surfaces attached to each other and installed at the upper and lower axles respectively, and having upper and lower feed gears engaged with each other and mounted on the upper and lower axles respectively, and the lower feed gear being operated together with a one-way bearing, such that the lower feed gear and the swing gear constitute a power transmission relation; the sealing device further comprises: a lateral heat sealing unit, having a lateral heat sealer disposed at the top of a first elevating stand, and having an upper press plate installed at a top dead spot opposite to the lateral heat sealer; and a transverse heat sealing unit, having a transverse heat sealer disposed at the top of the second elevating stand, and having an upper press plate installed at the top dead spot opposite to the transverse heat sealer.