Machine for applying a semipermeable patch on a plastic bag

The machine includes a horizontal support for a plastic bag and a vertically movable heat-sealing head pivoted to the support for upward movement through an aperture in the support to contact the plastic bag. A vertically movable pressure platen having a vacuum head for holding a patch thereon is mounted directly above the heat-sealing head and is adapted to be moved into engagement with the plastic bag so that the patch can be heat-sealed to the bag. A cutter is mounted adjacent the pressure platen for reciprocating movement along an oblique path to intersect the aperture in the support directly beneath the pressure platen to provide a slit in the plastic bag prior to the heat-sealing of the patch on the bag over the slit.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention is directed to a machine for heat-sealing a patch to 
a plastic article and more specifically to a machine for perforating a 
plastic bag and heat-sealing a semipermeable membrane to the plastic bag 
to cover the perforation. 
2. Prior Art 
For many years flexible containers such as plastic bags have been provided 
with spouts or valves by means of a machine which will first punch an 
opening in the plastic bag from one side and heat-seal a spout to the 
plastic material from the opposite side. Furthermore, the apparatus for 
carrying out this dual function is extremely complicated and expensive due 
to the fact that the heat-sealing head, the pressure platen and the 
punching apparatus are all disposed coaxially with respect to each other. 
The use of plastic packages having a semipervious membrane covering an 
opening therein to facilitate the sterilization of the products are old 
and well known in the art. Such packages are generally made of polyolefin 
plastic material such as polyethylene, polypropylene, copolymers or 
mixtures of polyethylene and polypropylene. Generally, a low density 
polyethylene is used for the package and a spun-bonded, non-woven 
polyethylene sheet member such as TYVEK, produced by Dupont Chemical 
Company, is used for the semipermeable patch or membrane. Some of the 
prior art packages of this nature merely close the two edges which define 
the mouth of the package by means of a strip of the semipermeable material 
which can be heat-sealed to the plastic bag. Another type of package of 
this nature forms a continuous cut or slit in the plastic sheet material 
as it passes from a supply roll and subsequently heat-seals the sheet 
material into the form of a bag and applies an elongated patch of the 
semipermeable material over the slit. The completed bags are then severed 
from the continuous sheet of material. Still other prior art bags provide 
a plurality of perforations in the plastic bag and cover them with a 
heat-sealing tape which is applied by a completely separate operation. In 
general, the construction of all of the prior art bags of this nature 
either involve a completely automated system wherein the plurality of 
steps are performed in sequence automatically during the formation of the 
bag which results in extremely high equipment cost or else the 
perforations and patches are performed subsequently by individual 
independent steps which involve a considerable amount of bag handling 
which is both inefficient and time consuming. 
SUMMARY OF THE INVENTION 
The present invention provides a simple and economical machine for 
sequentially forming a perforation in a plastic bag and heat-sealing a 
semipervious patch of material such as TYVEK over the perforation 
subsequent to the formation of the bag but prior to the filling and 
closing of the bag. 
The present invention provides a machine for perforating the plastic bag 
and applying a patch of semipervious material such as TYVEK over the 
perforation by means of a cutter and heat-sealing apparatus which are 
located at the same work station but which operate independently of each 
other and which are arranged non-coaxially relative to each other. 
The present invention provides a machine having a horizontal support for a 
plastic bag and a vertically movable heat-sealing head pivoted to the 
support for upward movement through an aperture in the support to contact 
the plastic bag. A vertically movable pressure platen having a vacuum head 
for holding a patch thereon is mounted directly above the heat-sealing 
head and is adapted to be moved into engagement with the plastic bag so 
that the patch can be heat-sealed to the bag. A cutter is mounted adjacent 
the pressure platen for reciprocating movement along an oblique path to 
intersect the aperture in the support directly beneath the pressure platen 
to provide a slit in the plastic bag prior to the heat-sealing of the 
patch on the bag over the slit. 
The foregoing and other objects, features and advantages of the invention 
will be apparent from the following more particular description of a 
preferred embodiment of the invention as illustrated in the accompanying 
drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Packages, such as those formed by the plastic bag 10 shown in FIG. 1 are 
primarily for maintaining items in bacteria-free condition. After the 
items have been placed within the bag 10 and the bag opening sealed the 
items may be readily sterilized through the use of an active agent such as 
ethylene oxide and readily purged of the sterilizing agent. The active 
agent is introduced and removed from the sealed bag through a slit 12 
which is covered by a patch 14 of semipermeable material. As indicated 
previously a suitable material for this purpose is produced by the Dupont 
Chemical Company under the name TYVEK. The slit 12 may be formed in the 
plastic bag and the patch 14 heat-sealed to the bag over the slit 12 by 
means of the machine 20 which is the subject of the present invention. 
The machine 20 is comprised of a base 22 which is adapted to be placed on a 
table or any other suitable surface. A support column 24 is provided with 
a work support arm 26 and a tool support arm 28 which extend laterally 
therefrom in horizontal parallel spaced relationship with respect to each 
other. The work support arm is spaced above the base 22 to permit the 
placement of a bag 10, shown in dashed lines in FIG. 3, over the free-end 
of the arm 26. The arm 26 is comprised of a support plate 30 having a 
substantially flat upper surface and a pair of downwardly extending side 
flanges 32. The support plate 30 is provided with a substantially 
rectangular aperture 34 to provide access to both sides of the plastic 
material of the bag 10. A heat-sealing head 36 is mounted on an arm 38 
pivoted to the side flanges 32 to 40 adjacent the free-end of the rigid 
support arm 26. The opposite end of the arm 38 is raised and lowered by 
means of a pneumatic actuator 42 having a piston rod 44 pivotally 
connected to the arm 38 at 46. The pneumatic actuator 42 is provided with 
a single acting piston and cylinder arrangement (not shown) which is 
conventional and pressurized air is supplied to the pneumatic actuator 42 
through the holes 48. The heat-sealing head 36 is provided with a central 
recess 50 and is connected to a suitable source of electric power by means 
of wires 52. The detailed construction of the heating elements within the 
head 36 are conventional and have only been illustrated schematically in 
dotted lines 54 in FIG. 3. 
With the pneumatic actuator 42 in its non-actuated condition the parts will 
be disposed as shown in FIG. 3 with the heat-sealing head 36 disposed 
completely below the support plate 30. Upon actuation of the pneumatic 
actuator 42 the arm 38 will be pivoted upwardly to move the upper surface 
of the heat-sealing head 36 into substantially flush relation with the 
upper surface of the support plate 30 as shown in FIG. 7. 
On the uppermost arm 28 a double acting pneumatic cylinder and piston 
device 52 is mounted with the longitudinal axis thereof vertically 
disposed directly above the aperture 34 in the work supporting plate 30. 
Suitable pneumatic connections 54 and 56 are provided for directing air 
under pressure to opposite sides of the piston (not shown) which is 
mounted for axial reciprocation within the unit. A piston rod 58 is 
connected to the piston and extends downwardly therefrom along a vertical 
axis. A vacuum head 60 is secured to the end of the piston rod 58 and is 
provided with an internal passage 62 which is connected at one end to a 
vacuum hose 64 by means of a fitting 66. The opposite end of the passage 
62 communicates with the bottom surface of the vacuum head 60 in alignment 
with the axis of the actuator and a suitable pressure pad 68 is secured 
thereto by any suitable means. An aperture may be provided centrally of 
the pressure pad 68 in communication with the passage 62 or the entire 
pressure pad 68 may be constructed of a suitable air pervious material 
through which the air may readily diffuse. Upon an application of a vacuum 
through the conduit 64 a patch 14 can be held on the face of the pressure 
pad 68 for downward movement into engagement with the plastic bag 10. 
Also mounted on the upper arm 28 is a second double acting pneumatic 
cylinder 70 having air inlet nozzles 72 and 74 for admitting air under 
pressure to opposite sides of a piston (not shown) which is slidably 
mounted within the unit. A piston rod 76 is secured to the piston and 
extends outwardly from the lower end of the unit 70 with the axis thereof 
intersecting the aperture 34 in the support plate 30 at approximately the 
mid-point thereof. A cutting blade 78 is mounted in a head 80 which is 
mounted on the end of the piston rod 76. An additional guide rod 82 is 
also secured to the head 80 and is slidably disposed within a guide 
aperture 84 in the block 86 in which the pneumatic unit 70 is mounted. 
In operation, a plastic bag is opened and drawn over the free end of the 
supporting arm 26 as best shown in FIG. 3. At this time the heat-sealing 
head 36 is retracted downwardly to its lowermost position, the vacuum head 
60 is raised to its uppermost position and the knife 78 is also raised to 
its uppermost position as best seen in FIG. 3. A patch 14 is positioned on 
the pressure pad 68 of the vacuum head 60 and a vacuum is applied to hold 
the patch in position thereon. By suitable pneumatic switching, not shown, 
air under pressure is supplied through the fitting 72 of the pneumatic 
actuator 70 to extend the blade 78 to its lowermost position as shown in 
FIG. 6 wherein the blade cuts through the plastic material of the bag 10. 
As mentioned previously a recess 50 is provided within the heat-sealing 
head 36 so as not to interfere with the blade 78 as it passes through the 
material. The flow of air under pressure is then shifted to the fitting 74 
and the piston within the pneumatic actuator unit 70 is moved upwardly and 
the blade retracted to the position shown in FIG. 3. 
With the bag still held in position on the support surface either manually 
or by any suitable clamps, not shown, air is then supplied under pressure 
to the fitting 54 to extend the piston rod 58 downwardly to bring the 
patch 14 into engagement with the outer surface of the bag 10. 
Simultaneously, air under pressure is supplied through the conduit 48 to 
raise the heat-sealing heat 36 into engagement with the inside surface of 
the bag and current is applied through the leads 52 to heat the head 36. 
During a continuous production run the current can be maintained in the ON 
state at all times for the head 36 to keep the same at operating 
temperature. The upper surface of the heat-sealing head 36 is subtantially 
rectilinear and will engage the plastic bag and completely surround the 
slit previously formed by the blade 78. The upward movement of the 
heat-sealing head 36 and the downward movement of the pressure pad 68 
force the patch 14 and the plastic material of the bag 10 into engagement 
for a predetermined length of time sufficient to provide a heat-seal 
therebetween. The pressurized air is then removed from the conduit 48 
allowing the heat-sealing head 36 to be retracted downwardly either under 
the influence of its own weight or by spring means, not shown, disposed 
within the pneumatic actuator 42. The air under pressure will be supplied 
to the fitting 56 of the pneumatic actuator 52 to raise the vacuum head 60 
from the position shown in FIG. 7 to the position shown in FIG. 3. The bag 
may now be removed from the support arm 26 and the patch will be secured 
to the bag in the manner best shown in FIGS. 1 and 2. The bag may now be 
filled with the articles to be sterilized and the open edges of the bag 
sealed together by any suitable heat-sealing apparatus. 
The exact shape of the patch and the configuration of the heat-sealing head 
may be varied within the scope and the present invention and hydraulic or 
electrical actuators may obviously be substituted for the pneumatic 
actuators 42, 52 and 70. 
While the invention has been particularly shown and described with 
reference to a preferred embodiment thereof it will be understood by those 
in the art that the foregoing and other changes in form and details may be 
made therein without departing from the spirit and scope of the invention.