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Claims  |
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What is claimed is:
1. In a machine for wrapping a package utilizing a wrapping material to be
applied with a predetermined tension to the package,
a. frame means,
b. a main drive shaft assembly mounted in said frame means,
c. driving means connected in said frame means and connected to the main
drive shaft assembly for rotating the same at a predetermined rate of
rotation,
d. supporting means fixedly connected to and rotatable with the main drive
shaft,
e. package supporting assembly means connected to and rotatable with the
supporting means for holding the package to be wrapped,
f. means connected to said package supporting assembly means for rotating
the same independently of said supporting means,
g. wrapping material supporting assembly means also connected to and
rotatable with the supporting means, disposed thereon in spaced relation
to the package supporting assembly means and adopted to hold wrapping
material therein,
h. means for rotating the wrapping material supporting assembly means
independently of the supporting means and counter to the direction of
rotation of said direction of independent rotation of said package
supporting assembly means whereby said wrapping material is dispensed and
applied about the package to be wrapped, and
i. means operatively associated with said means for rotating the wrapping
material supporting assembly means for applying an adjustable force on the
wrapping material as the same is dispensed from the wrapping material
supporting assembly means to adjust the tension thereof as the wrapping
material is applied about the package being wrapped on said package
supporting assembly means.
2. In a machine for wrapping a package utilizing a wrapping material to be
applied with a predetermined tension to the package,
a. frame means,
b. a main drive shaft assembly mounted in said frame means,
c. driving means connected in said frame means and connected to the main
drive shaft assembly for rotating the same at a predetermined rate of
rotation.
d. support means fixedly connected to and rotatable with the main drive
shaft,
e. package supporting assembly means connected to and rotatable with the
support means and disposed a predetermined distance from the axis of
rotation thereof and including, means for holding a package to be wrapped,
f. means connected to said package supporting assembly means for rotating
the same independently of said support means,
g. wrapping material supporting assembly means also connected to and
rotatable with the support means a predetermined distance from the axis of
rotation thereof and a spaced distance from the package supporting
assembly means,
h. said wrapping material supporting assembly means including, means for
mounting the wrapping material to be dispensed therefrom during the
wrapping of the package on the package supporting assembly means,
i. means for rotating the wrapping material supporting assembly means
independently of the support means including, means for varying the force
exerted on the wrapping material as the same is dispensed from the
wrapping material supporting assembly means to adjust the tension of the
wrapping material whereby on rotation of the support means the wrapping
material is applied about the package to be wrapped.
3. In a machine for wrapping a package as claimed in claim 2 including,
a. an intermediate power transmitting assembly mounted for free rotation in
said frame, and
b. said intermediate power transmitting assembly operatively connecting
said means for varying the forced exerted on the wrapping material to said
means for rotating the wrapping material supporting assembly independently
of the support means.
4. In a machine for wrapping a package as claimed in claim 2 including,
a. bearing means on said support means,
b. a shaft rotatably mounted in said bearing means,
c. said package supporting assembly means fixedly connected to the end of
said shaft remote from the bearing means and rotatable with said shaft,
and
d. the means for independently rotating the package supporting assembly
means is connected for rotating said shaft and the package supporting
assembly means connected thereto.
5. In a machine for wrapping a package as claimed in claim 4 wherein the
means for independently rotating the shaft and package supporting assembly
means connected thereto is a planetary type driving system including,
a. a first gear connected to a said shaft,
b. a second gear fixedly connected concentric to the axis of rotation of
said main drive shaft assembly,
c. a chain connecting the first gear and second gear to provide a planetary
type drive for rotating the package supporting assembly means during
rotation of the support means.
6. In a machine for wrapping packages as claimed in claim 2,
a. bearing means on said support means,
b. an elongated support mandril rotatably mounted in said bearing means and
extending axially from the support means in a line substantially parallel
to the axis of rotation for the main drive shaft assembly,
c. said wrapping material supporting assembly mounted on and rotatable with
the support mandril, and
d. said means for rotating the wrapping material supporting assembly
operatively connected to the support mandril for rotating the same and the
wrapping material supporting assembly connected thereto.
7. In a machine for wrapping packages as claimed in claim 6 wherein,
a. a driving gear is connected to the supporting mandril,
b. said means for varying the force exerted on the wrapping material
including an auxiliary drive assembly,
c. said auxiliary driving assembly connected and driven by said driving
means,
d. said auxiliary driving assembly including, an auxiliary driving shaft,
e. an intermediate power transmitting assembly mounted in said frame, and
f. chain drive means connecting said auxiliary drive shaft and said
intermediate power transmitting assembly to said driving gear.
8. In a machine for wrapping packages as claimed in claim 7 wherein,
a. said auxiliary driving assembly includes, clutch means,
b. a stator on said clutch means connected to said driving means, and
c. a rotor on said clutch means connected to said auxiliary driving shaft,
and
d. means for controlling the operative inter-relation of said stator and
said rotor to exert frictional drag on said auxiliary drive shaft to
control the power transmitted from the driving means through said
auxiliary drive shaft to the driving gear.
9. In a machine for wrapping a package as claimed in claim 2 wherein said
main drive shaft assembly includes, a main drive shaft housing, and a main
drive shaft rotatably mounted in said main drive shaft housing.
10. In a machine for wrapping a package as claimed in claim 9 including,
a. an intermediate power transmitting assembly mounted for free rotation on
said main drive shaft housing,
b. said intermediate power transmitting assembly operatively connecting
said means for varying the force exerted on the wrapping material to said
means for rotating the wrapping material supporting assembly independently
of the support means.
11. In a machine for wrapping a package as claimed in claim 9 including,
a. an intermediate power transmitting assembly mounted for free rotation on
said main drive shaft housing,
b. said intermediate power transmitting assembly including, a cylindrical
housing, a first gear at one end of said cylindrical housing, and a second
gear on said cylindrical housing a spaced distance from said first gear,
and
c. said first gear operatively connected to said means for varying the
force exerted on the wrapping material, and said second gear connected to
the means for rotating the wrapping material supporting assembly.
12. In a machine for wrapping a package as claimed in claim 9 wherein said
means for independently rotating said package supporting assembly means
constitutes,
a. planetary drive means having, bearing means on said support means,
b. a shaft rotatably mounted in said bearing means, and
c. said planetary drive means also including, a first gear fixedly
connected on said main drive shaft housing, a second gear connected to
said shaft, and a continuous chain operatively connecting the first gear
and second gear to each other.
13. In a machine for wrapping a package as claimed in claim 2 wherein,
a. said means for varying the force exerted on the wrapping material is
driven by said main drive shaft assembly,
b. an intermediate power transmitting assembly mounted for free rotation in
said frame means, and
c. said intermediate power transmitting operatively connecting said means
for varying the force exerted on the wrapping material to the means for
rotating the wrapping material supporting assembly means for driving the
same.
14. In a machine for wrapping a package as claimed in claim 13 wherein said
main drive shaft assembly has a main drive shaft housing, and the means
for rotating the package supporting assembly means is,
a. planetary drive means,
b. bearing means on said support means,
c. a shaft rotatably mounted in said bearing means,
d. said package supporting assembly means fixedly connected to the end of
said shaft remote from the bearing means and rotatable with said shaft,
and
e. said planetary drive means including, a first gear fixedly connected to
said main drive shaft housing, a second gear fixedly connected to said
shaft, and a continuous chain connecting the first gear and second gear to
permit the package supporting assembly means to rotate during rotation of
the support means. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates generally to machinery for wrapping a package and
more particularly to a package wrapping machine which creates a unitary
package utilizing a self-adhering wrapping material which is applied to
the package under a predetermined amount of force or tension.
It is known in the prior art that a palletized package can be stretch
wrapped using polyethylene material as is shown and described in U.S. Pat.
Nos. 3,867,806, 3,793,798 and 3,003,297.
The present invention provides an improved stretch-wrap packaging machine
and apparatus which is adapted to hold and wrap small packages and loads
primarily those to be shipped by parcel post and United Parcel Service.
The present invention provides such improved packaging machine or apparatus
having a main driving assembly for rotating a combined supporting member
and safety closure disc on which a package supporting assembly for
supporting a package to be wrapped and a wrapping material supporting
assembly for the wrapping material for wrapping the package are disposed
for independent and counter-clockwise rotation relative each other. The
package supporting assembly is rotated by a planetary drive and the
wrapping material supporting assembly is rotated by an auxiliary driven
means operated off of the main driving assembly. The auxiliary driven
means includes means for regulating the force or torque required to remove
the wrapping material from the wrapping material supporting assembly so as
to apply the desired tension to the wrapping material when the package is
being wrapped.
The package supporting assembly includes means thereon for adjustably
supporting packages of varying sizes within a given range.
The wrapping material supporting assembly includes, unique means forceably
gripping the ends of the roll of wrapping material to simply and
effectively hold it on the wrapping material supporting assembly and for
transmitting the frictional torque or adjustable force exerted on the
mounted roll of dispensing material to adjust the tension thereof.
Additionally means are provided on the wrapping material supporting
structure to move it to and fro along an axis parallel to the axis of
rotation for the wrapping material supporting member.
SUMMARY OF THE INVENTION
Thus, the present invention covers an improved tension-wrap packaging
machine for wrapping a package preferably with self-sealing wrapping
material applied to the package with a predetermined amount of tension so
as to provide a unitary package including, a supporting frame, a main
driving shaft, means for rotating the main driving shaft, support member
means connected to and rotatable with the main driving shaft, said support
member means having a package supporting assembly and a wrapping material
supporting assembly mounted on and rotatable therewith, planetary drive
means for rotating the package supporting assembly independent of the
support member means, auxiliary driven means operated by the main driving
assembly for rotating the wrapping material supporting assembly
independent of the support member means and having means to adjust the
force or torque required to remove the wrapping material from the wrapping
material support assembly, and said package supporting assembly and
wrapping material supporting assembly disposed on said support member
means for counter rotation relative each other.
Accordingly it is an object of the present invention to provide an improved
packaging machine for forming a unitary package which accomodates packages
of varying sizes, stabilizes the package during the wrapping thereof, and
tensions the wrapping material used for wrapping the package.
It is another object of the present invention to provide an improved
packaging machine adapted to accomodate a package or load to be wrapped to
stabilize the package during the wrapping thereof by counter-clockwise
movement of the package relative the wrapping material and by tensioning
the wrapping material during the wrapping of the package.
It is another object of the present invention to provide a package
supporting assembly for supporting a package which includes means for
supporting packages of varying widths and length within a given range.
It is another object of the present invention to provide a package
supporting assembly which is driven by a planetary driving system.
It is another object of the present invention to provide a wrapping
material supporting assembly which includes, improved means for gripping
and transmitting frictional forces to the roll of wrapping material
mounted thereon, and means for varying the axial position of the wrapping
material along the axis of rotation for the wrapping material supporting
assembly.
It is another object of the present invention to provide an auxiliary
driven means for driving the dispensing roll supporting assembly for a
packaging machine which includes, a magnetic or the like electrical
control clutch for applying adjustable tension to the wrapping material
being dispensed by the wrapping material supporting assembly.
With these and other objects the features and advantages of the invention
will become apparent from the following more detailed description of a
preferred embodiment of the invention as illustrated in the accompanying
drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of one form of tension wrap packaging machine
in accordance with the present invention.
FIG. 2 is a front view of the tension wrap packaging machine shown in FIG.
1.
FIG. 3 is a rear view of the tension wrap packaging machine shown in FIGS.
1 and 2 of the drawings.
FIG. 4 is a left side view of the tension wrap packaging machine shown in
FIG. 2.
FIG. 5 is a top view of the tension wrap packaging machine shown in FIG. 1.
FIG. 6 is a rear elevational view of the tension wrap packaging machine
shown in FIGS. 1 to 4 with the back panel of the housing removed, a
portion of the supporting frame broken away, and the back outline shapes
of package supporting assembly and wrapping material supporting assembly
shown in dashed lines.
FIG. 7 is a top view with the cover removed of the tension wrap packaging
machine shown in FIGS. 1 to 6 of the drawings.
FIG. 8 is a vertical section along the main drive shaft taken on line 8--8
of FIG. 6.
FIG. 9 is a vertical section taken on line 9--9 of FIG. 6.
FIG. 10 is an enlarged view of the magnetic clutch for the auxiliary drive
assembly.
FIG. 11 is an enlarged front view of the package supporting assembly shown
in FIGS. 1 to 5.
FIG. 12 is an enlarged rear view of the package supporting assembly shown
in FIGS. 1 to 5, and 11.
FIG. 13 is an enlarged left side view of the package supporting assembly
shown in FIGS. 1 to 5, 11 and 12.
FIG. 14 is an enlarged top view of the package supporting assembly shown in
FIGS. 1 to 5, 11, 12, and 13 partly in horizontal section on line 14--14
of FIG. 11.
FIG. 15 is a vertical section taken on line 15--15 of FIG. 11.
FIG. 16 is a vertical section taken on line 16--16 of FIG. 11.
FIG. 17 is an enlarged view of the wrapping material supporting assembly
with the wrapping material thereon.
FIG. 18 is a partial view of the wrapping material supporting assembly
without the wrapping material thereon having the outer hollow shaft move
laterally with respect to the inner driving mandril and partially exploded
to show the movable gripping element for gripping the outer end of the
core for the wrapping material.
FIG. 19 is a longitudinal section taken on line 19--19 of FIG. 17.
FIG. 20 is a view taken from the inner end of the wrapping material
supporting assembly on line 20--20 of FIG. 17.
FIG. 21 is a view taken from the outer end of the wrapping material
supporting assembly on line 21--21 of FIG. 17.
FIG. 22 is a cross-section taken on line 22--22 of FIG. 19.
FIG. 23 is a front view of one of the gripping elements shown in FIGS. 17,
18 and 19.
FIG. 24 is a rear view of the gripping element shown in FIG. 23.
FIG. 25 is a side view of the gripping element shown in FIG. 23.
FIG. 26 is a schematic drawing of the electrical circuit and the associated
elements of the switch for starting and stopping the motor of the main
driving assembly and the control for adjusting the clutch of the auxiliary
driving assembly.
Referring to the drawings FIGS. 1 to 5 show a preferred form of tension
wrap packaging machine generally designated 10 in accordance with the
present invention having a supporting frame assembly 11 which is mounted
on spaced legs as at 12a and 12b.
Supporting frame assembly is generally rectangular in horizontal section
and is elongated in the vertical direction. It is formed with a front
panel 13, a left side panel 14, a right side panel 15, a rear panel 16,
and a removable top cover 17.
The front panel is provided with a cylindrical opening as at 18 and the
rear panel is provided with an enlarged square opening as at 19 having a
removable rear cover 19a to facilitate access to the various assemblies
for rotating and driving the various elements for holding a package to be
wrapped and the wrapping materials to be wrapped about the package all as
will be more fully described hereinafter.
MAIN DRIVING ASSEMBLY
The main driving assembly generally designated 20 is mounted on a shelf 21
which is disposed transversly to the vertical axis of the supporting frame
10 about the mid point thereof and is held between the front panel, and
the back panel as is shown in FIGS. 6 and 7 of the drawings.
The main driving assembly 20 includes an electric motor 22 which is
connected to a reduction gear means 23 for driving a gear or pulley 24.
Gear or pulley 24 is connected by belt 25 to a main driving gear or pulley
26 in turn connected to one end of the main driving shaft 27, the gears 24
and 26 being so sized that the main driving pulley 26 will rotate the main
driving shaft 27 at approximately 10 to 12 R.P.M.
The main driving shaft 27 is mounted by suitable bearing means 28a and 28b
in a bearing housing 29 which is supported on a transverse beam 30 fixedly
connected by any suitable means to the left side panel 14 and to the right
side panel 15 of the supporting frame 11, as is also shown in FIGS. 6 and
7.
FIG. 7 shows that the main drive shaft 27 extends a sufficient distance so
that the end remote from the main driving pulley 26 can be fixedly
connected to the support member 33 which is in turn fixedly connected to a
circular safety disc 34 which is sized so as to close the opening 18.
Thus, the supporting assembly consisting of the support member 33 and disc
34 acts to improve the appearance of the supporting frame 11 by concealing
the various driving assemblies for the tension wrap packaging machine 10
and as a safety mechanism to reduce the hazards to persons operating the
tension wrap packaging machine 10 which can arise where rotating parts and
elements of a machine are exposed.
Since the supporting member 33 and disc 34 are fixedly connected to the
main driving shaft 27 each time that the driving shaft 27 is rotated,
these elements will rotate therewith at the same speed.
Connected to the inner face of the disc 34 are bearing supports as at 35
and 36 which are disposed on opposite sides of the axis of rotation for
the disc 34 for reasons that will be cleaar when the operation of the
tension wrap packaging machine is described below.
The bearing supports 35 and 36 are block like members having kerfs or slots
as at 37 and 38 extending inwardly from the side faces thereof so as to
define a front leg and a rear leg one each of the respective bearing
supports as at 39a and 40a for bearing support 35 and 39b and 40b for
bearing support 36. The respective front leg 39a and rear leg 40a have a
supporting shaft 43 rotatably mounted therein, and the front leg 39b and
rear leg 40b have a supporting mandril or supporting shaft 44 rotatably
mounted therein as is shown in FIGS. 6 and 7.
In assembled position the supporting shaft 43 and supporting mandril or
shaft 44 will be rotated by suitable driving assemblies, more fully
described below, about axis parallel to the axis of rotation for the
safety disc 34 but spaced radially therefrom as is shown in FIGS. 6 and 7
of the drawings.
The supporting shaft 43 extends through the safety disc 34 beyond the front
face thereof and a shaped bracket 45 fixedly connected to the end thereof
a spaced distance from the front face of the safety disc 34 permits a
package supporting assembly 50 to be mounted thereon so that the package
supporting assembly 50 will be rotated in juxtaposition to the front face
of the safety disc 34 and about the axis of rotation for the supporting
shaft 43 as is also shown in FIGS. 1, 2 and 7 of the drawings.
PACKAGE SUPPORTING ASSEMBLY AND PLANETARY DRIVE THEREFORE
Package supporting assembly 50 as shown in FIGS. 1, 2, 4, 5 and 11 to 14
includes, a back plate 51 which is disposed perpendicular to the axis of
rotation for the supporting shaft 43 by a slotted bracket 52 on the back
face thereof for connecting the package supporting assembly to the shaped
bracket 45. Slots 46 permit threaded elements 47a and 47b to engage and
lock or hold the back plate in any adjusted positions within the range of
the slots.
Back plate 51 can have any given shape and will be sized to receive and
accomodate a range of packages having various heights within the range of
the back plate 51. The lower face 53 of the back plate is square or linear
and spaced members 54 and 55 extending from the sides of the back plate 51
adjacent the respective ends of the square or linear face 53 to support
therebetween a guide rail 56 on which are slidably mounted a pair of
coating arms 57 and 58, which can be locked in a given position along the
guide rail 56 by a locking assembly generally designated 59.
The arms 57 and 58 are elongated members of predetermined length to support
a concomitant range of package lengths and include, hubs, as at 57a and
58a and elongated flat support sections as at 57b and 58b. The hubs have
transverse openings therethrough, so they can be mounted on the guide rail
56 to permit the support sections 57b and 58b of the respective arms 57
and 58 to be disposed in spaced relation as a function of the given width
of the sized package to be wrapped by the tension wrap packaging a
machine.
The locking assembly 59 includes, a centrally disposed threaded bore 60 in
locking assembly support block 59a, an opening 61 in locking strip 59b is
aligned with the bore 60, so that a manually operable thumbscrew 62 can be
extended through the opening 61 into the threaded bore 60 and can move a
cooperating locking washer 63 disposed between the locking strip 59b and
the thumbscrew 62 into engagement with the locking strip 59b causing the
same to move towards and away from the lower face 53 of the back plate 51
and thus to lock the hubs 57a and 58a in the spaced positions at which
they are set on the guide rail 56. On threaded movement in the opposite
direction the hubs 57a and 58a of the arms 57 and 58 will be released to
permit the same to be repositioned as may be necessary for a package to be
wrapped having a different width requirement as may be the case.
The package supporting assembly 50 will be initially positioned so that the
upper surface of the supporting sections 57b a and 58b of the respective
supporting arms 57 and 58 are disposed in a parallel plane perpendicular
to a vertical plane extending through the axis of rotation for the safety
disc 34. Further, however, when the safety disc 34 is rotated by the main
driving assembly, the supporting shaft 43 and the package supporting
assembly 50 also will be rotated independently of the rotating safety disc
34 so that the upper surface of the respective supporting sections 57b and
58b will at all times be maintained in a horizontal plane perpendicular to
the vertical plane through the axis of rotation for the safety disc 34. A
planetary driving assembly generally designated 65 is provided for this
purpose.
Planetary driving assembly 65 includes, a stationary gear 66, which is
connected to the front end of the bearing housing 29 for the main driving
gear 27. Stationary gear 16 lies concentric to the axis of rotation for
the safety disc 34.
A connecting gear 67 on the supporting shaft 43 rotatably mounted in
suitable bearing means, not shown on the front leg 39a and the rear leg
40a, lies in the same plane as the stationary gear 66, and a connecting
chain 68 connects the stationary gear 66 to the driven connecting gear 67
on the shaft 43. When the safety disc 34 is rotated, the shaft 43, by
reason of the planetary driving assembly 65, is caused to turn or rotate
through 360.degree., which is a function of the pivotal and incremental
movement of the connecting chain 68 about the stationary gear 66. Since
this turning of the supporting shaft 43 is a function of the angular
pivotal and incremental movement about the stationary gear 66, the package
supporting assembly 50 is moved in the same relative horizontal position
at all circumferential positions to which the shaft 43 is moved during the
rotation of the safety disc 34.
WRAPPING MATERIAL SUPPORTING ASSEMBLY AND AUXILIARY DRIVE WITH CLUTCHING
MEANS
The supporting mandril 44 is an elongated shaft having a length about equal
to the length of the respective arms 57 and 58 of the package supporting
assembly 50. Similar to the supporting shaft 43, supporting mandril 44
extends through the safety disc 34 so that it projects a substantial
distance beyond the front face of the safety disc along an axis parallel
to the axis of rotation for the safety disc but spaced radially therefrom
a sufficient distance to enable a wrapping material supporting assembly
generally designated 70 to be mounted thereon and to support a roll of
wrapping material generally designated WM as shown in FIGS. 1 to 4 and 17
to 25 of the drawings.
The elongated supporting mandril 44 provides the inner member of the
wrapping material supporting assembly 70 and has a guideway or groove 71
milled in the outer surface thereof. Mounted on the supporting mandril 44
is a hollow cylindrical outer member 72 having a bore 73 end to end
therethrough sized for a sliding fit relative the outer surface of the
supporting mandril 44. The outer member 72 has roller bearing means 74
which is sized to fit and to roll in the guideway or groove 71 when the
outer member 72 is telescoped to and fro relative the longitudinal axis of
the inner member 71.
The outer diameter of outer member 72 is sized so that the hollow core 75
of the roll of wrapping material WM can be fitted thereon. At the inner
side of the outer member 72 adjacent the front face of the safety disc 34
an annular shoulder 76 is provided and the inner side of the hollow core
75 will abut against the annular shoulder 76 in assembled position. A
gripping member 76 on the face of the shoulder 76 will bite into the end
of the hollow core 75 in assembled position.
Outboard of the outer end of the outer member 72 remote from the annular
shoulder 76 a sized gripping member 78 is disposed on a manually movable
threaded holding assembly generally designated 80. The gripping member 78
is disposed to bite into the outer end of the hollow core 75 and coacting
with gripping member 76 will hold and fixedly connect the roll of wrapping
material WM so that on rotation of the wrapping material support assembly
the pay off of the wrapping material can be both controlled and the
tension adjusted thereon by suitable driving means hereinafter described.
Threaded holding assembly 80 includes a threaded section 81 which is
adapted to engage a threaded section 82 on the outboard end of the outer
member 82 and a knurled handle 83 provides means for threading the
threaded section so as to move the gripping element connected thereon into
and out of engagement with the hollow core 75.
Gripping members 77 and 78 have substantially the same construction and
only gripping member 77 is therefor illustrated at FIGS. 23, 24 and 25 as
a formed annular member struck from sheet metal by any suitable means as
will be understood by those skilled in the art. The character numerals
recited for Gripping member 76 are also applicable to gripping member 78.
Each gripping member has an outer annulus or peripheral edge as at 77a and
an inner annulus or inner circumferential edge as at 77b. Spaced
triangular elements as at 77c extend or project from one face of the
gripping member. In assembled position the pointed end of the triangular
elements 76c on each gripping element extend into the hollow portion of
the core 75 and the angle sides of the triangular elements will be sharp
enough to bite into the respective ends of the core 75.
Spaced lugs as at 77d offset from the peripheral edge 77a and an inwardly
extending key 77e offset from the inner circumference 77b provides means
for holding the respective gripping members 76 and 78 in assembled
position on the annular shoulder 76 and on the threaded holding assembly
80, all of which is shown in FIGS. 17, 19, 23, 24 and 25 of the drawings.
The threaded holding assembly 80 includes an annular member 80a which as
indicated above is threaded on its inner annulus as at 81 to permit the
threaded holding assembly 80 to be threaded on and off the threaded
portion 82 on the outer member 72.
On one side of the threaded annular member 80a an undercut annular flange
83 is formed to provide means for mounting the gripping member 78 as by
lugs 77d which are bent to engage the peripheral edge of the undercut and
thus bring the outer face of the gripping member 78 into abutment with the
face of the undercut annular flange 83 so that the triangular elements 77c
face inwardly towards the core 75 of the wrapping material WM when the
threaded holding assembly 80 is threaded onto the outer member 72, as is
shown in FIGS. 17, 18 and 19 of the drawings.
Threaded holding assembly 80 is sized to permit the annular member 80a to
be gripped and rotated so as to thread the same in or off the outer member
72. When the threaded holding assembly 80 is threaded off the outer
member, a roll of wrapping material WM may be placed in position on the
outer member 72 of the wrapping material supporting assembly 70 or an
empty core may be removed. After a new roll is placed into position on the
outer member 72, the threaded holding assembly 80 can be threaded so as to
bring the respective inner gripping element 76 and outer gripping element
78 into tight holding and gripping engagement with the respective ends of
the core 75 for the new roll of wrapping material WM.
Outer member 72 on which the wrapping material is mounted includes the
outer hollow cylindrical member 85 and a central elongated shaft 86 which
are fixedly connected by an end cap 87 as shown in FIG. 19. It will be
understood that hollow cylindrical member 85 and the elongated central
shaft 86 may be cast, molded or formed as a single element without
department from the scope of the present invention.
A handle 88 is formed on the exterior end of the outer member 72 for
sliding the same axially as will now be described.
The outer member 72 is disposed so that the elongated central shaft 86
extends into the hollow cylindrical support mandril 44 and spaced bearings
as at 89 on the inner end of the central shaft 86 and 90 on the outer end
of the mandril 44 permits the central shaft 86 to be slidably disposed in
the mandril 44.
The inner annular element 76 is fixedly connected to the interior edge of
the outer member 72 and the inner gripping element 76 is fixedly connected
thereto. A bearing holder 91 transversly disposed in the inner annular
element 76 holds tghe roller bearing 74 which rides and rolls in groove 71
on the inner support mandril 44.
The groove 71 has an automatic stop as at 92. On inward movement the inner
or interior face 93 of the inner annular element 76 acts as an inner stop
to the inward sliding movement of the outer member 72 and relative the
inner support mandril 44 and the stop shoulder 92 acts as an outer stop to
the outward sliding movement of the outer member 72.
It will be clear that such sliding movement can be effected by manually
gripping the handle 88 an exerting pulling or pushing forces thereon to
place the wrapping material roll at the desired position for paying off
the wrapping material from the roll at the desired position relative the
package 95 to be wrapped as is shown in FIGS. 2, 4 and 5 of the drawings.
Wrapping material supporting assembly 70 will be rotated with the safety
disc 34 and in addition, will be rotated independently thereof about the
longitudinal axis of the supporting mandril by an auxiliary driving
assembly which includes clutching means for adjusting the rate and tension
of the wrapping material being paid out off of the wrapping machine roll
WM.
Thus, referring to FIGS. 8, 9, 17 and 19, the supporting mandril 44 has a
driving gear 101 connected to the section of the supporting mandril
between the front leg 39b and rear leg 40b of the bearing support 36.
Driving gear 101 coacts with an intermediate power transfer 102 which is a
cylindrical element rotatably connected on the housing for the main
driving shaft 14 by suitable bearings, not shown, which permit the free
rotation thereof concentric to the axis for rotation of the main shaft 14
and the safety disc 34 connected thereto.
Intermediate power transfer assembly 102 has a front gear 103 and a rear
gear 104 which are fixedly connected and rotatable with the cylindrical
center portion thereof. The front gear 103 is in the same plane as the
driving gear 101 on the supporting mandril 44 and the driving gear 101 and
front gear 103 are connected by a continuous chain 105.
The driving force for rotating and for adjusting the driving force
transmitted to the front gear 103 and the driven gear 101 through
connecting chain 105 is transmitted to the rear gear 104 of the
intermediate power transmitting assembly 102 through an auxiliary driving
assembly generally designated 110.
Auxiliary driving assembly 110 includes, an auxiliary driving shaft 111
which is rotatably mounted in suitable spaced bearings 112 and 113
connected to the transverse supporting beam 30. The auxiliary driving
shaft 111 is sufficiently long to extend in opposite directions beyond the
sides of the transverse supporting beam and at the end adjacent the safety
disc 34 is provided with a connecting gear 114 which is in alignment with
rear gear 104 on the intermediate power transmitting assembly 102 to
permit a continuous chain 115 to connect these gears in driving
engagement.
On the rear end remote from the connecting gear 114 is a magnetic clutching
assembly 116. Magnetic clutching assembly 116 includes, a connecting
sprocket 117 disposed in alignment with a driving sprocket 118 fixedly
connected and rotatable with the main drive shaft 27. Power can be
transmitted from the driving sprocket 118 to the connecting sprocket 117
by means of a power transmitting continuous chain drive 119, all of which
is shown in FIGS. 6, 7, and 9 of the drawings.
Thus, when the main driven gear 26 is rotated driving sprocket 118
conencted on the main driving shaft 27 will also be rotated and will
transmit power through the chain drive 119 to the connecting sprocket 117
which in turn will transmit power through the magnetic clutch 116 to the
auxiliary shaft 111. The auxiliary shaft 111 in turn will transmit power
through connecting gear 114 and chain drive 115 to the rear gear 104 of
the intermediate power transmitting assembly 102 causing it to rotate
independently of the rotation of the main shaft 27. The driving force
transmitted by front gear 103 and connecting chain 105 to the driving gear
101 on the elongated supporting mandril 44 will rotate the same and the
wrapping material supporting assembly 70 with the force and torque
transmitted through the auxiliary driving assembly 110.
The driving force transmitted through this auxiliary driving assembly 110
will be regulated by the magnetic clutch 116, and can be controlled by the
operator of the machine through a suitable electrical control system to be
described in more detail below.
The magnetic clutch 116 is purchasable on the open market and one such
clutch adapted for use in connection with the tension wrap packaging
machine in accordance with the present invention is model EC-17c-4 Coil
Number 1, Style "L" manufactured and sold by Electroid Company. This
device acts to apply more or less frictional engagement to the connecting
sprocket 117 so as to adjust and regulate the amount of rotational force
or torque transmitted to the auxilairy driving shaft 111.
Thus, FIG. 9 shows that the connecting sprocket 117 is rotatably connected
to the rear end of the auxiliary shaft 111 and fixedly to a hub portion
120 on the magnetic clutch 116. Hub portion 120 is provided with an
annular metal friction shoe 121. A corresponding and mating metal friction
shoe 122 is provided on an armature 123 which is mounted in a rotor 124
fixedly mounted on and rotatable with the auxiliary driving shaft 111. The
rotor is operatively associated with a coil assembly 125 which is fixed to
the transverse support beam 30. Current is delivered to the coil field 126
in the coil assembly 125 through electrical current supply lines 127 and
108 and the magnetic flux exerted by the coil field 126 will be determined
by the amount of electrical current applied thereto through the lines 127
and 128.
As electrical current is applied to the coil field, it will induce a
corresponding magnetic flux in the armature 123 and this will produce a
corresponding magnetic field in the metal friction shoes 122 which will
effect the mating metal friction shoes 121. Thus, the driving force
transmitted from the connecting sprocket 117 to the auxiliary driving
shaft 111 and the train of driving gears to the wrapping material
supporting assembly 70 will be adjusted as a function of the magnetic flux
exerted in the clutch mechanism and the control system for operating the
main driving assembly and auxiliary driving assembly as will now be
described.
CONTROL SYSTEM
FIG. 26 shows that the control system for operating the tension wrap
packaging machine in accordance with the present invention is relatively
simple and utilizes a conventional 110 volt A.C. circuit. Therefore a
conventional electric plug 130 is provided for connecting the control
circuit into any conventional wall outlet, not shown.
The electrical circuit carrying 131 and 132 from the plug 130 are connected
to two parallel current carrying circuits. One circuit is for operating
the motor 22 and the other circuit is for adjusting the flux applied to
the coil field 126 of the clutch mechanism 116. Thus, line 131 is
connected to one side of the coil field for the motor 22. The other side
of the coil field, in turn being connected by line 133 to the terminal 134
have a switch 135. The switching arm 136 of the switch 135 is connected to
the line 132 so that when the switching arm 136 is moved into contact with
the terminal 134 current will flow through the motor circuit and place the
motor into operation and when the switch arm is out of contact with the
terminal 134, the motor circuit will be open, and the motor will cease
operating.
Lines 131 and 132 are also connected to a rectifier 137 which converts the
A.C. current to D.C. current required to oeperate the coil field 126 of
the clutch mechanism 115. Thus, D.C. line 138 leads from the rectifier to
line 127 for coil field 126 and connecting line 139 leads from line 128 of
the coil field 126 to the resistance 140 of a conventional potentiometer
141 of the type well known and understood by those skilled in the art.
D.C. line 142 leads from the movable contact 143 to the rectifier 137 to
complete the circuit as will be understood by those skilled in the art,
the movable arm can be moved relative the resistance 140 to adjust the
amount of current applied to the coil field 126 of the clutch mechanism
115.
The switch 135 and potentiometer 141 are disposed in a common control
housing 145 shown in dashed lines in FIG. 14 which is shaped so that the
operator of the tension wrap packaging machine can both switch the motor
on and off and adjust the current applied to the coil field 126 of the
clutch mechanism 115 so as to both place the tension wrap packaging
machine into operation and to adjust the tension of the wrapping material
applied to the package to be wrapped.
Particular attention is called to the wrapping material WM. Wrapping
materials having self sticking and resilient physical properties typically
may be polyvinyl chloride film of 75 mil thickness made up in rolls on a
hollow core. Polyethylene films may also be used. However, it will be
understood by those skilled in the art that other types of wrapping
materials can also be used. For example, polyvinyl films may be used with
a sealing tape or an adhesive backing and the use of such other materials
are clearly within the scope of the present invention.
OPERATION
In operation, the arms or load bars 57 and 58 are set to the package width
and locked in position by manual operation of the locking assembly 59.
A portion of the wrapping material is paid off of the wrapping material
supporting assembly 70 and several turns thereof are wrapped about the
arms or load bars to provide a platform for the package to be wrapped.
The package covered with insulating material, not shown, if required, is
placed in position on the wrapped section of the arms or load bars 57 and
58 and the main driving assembly of the tension wrap packaging machine is
started by depressing the foot-operated switch 135 and potentiometer 141
lightly. This allows the machine to dispense wrapping material without
applying tension thereto and permits by reason of the counter rotation of
the package and the wrapping material to wrap the wrapping material about
the package for at least one revolution without tension thereon.
After the first revolution, the foot-operated switch 135 and potentiometer
141 is now depressed more heavily and the wrapping material is tightened
about the load by establishing the proper tension thereon as a function of
the frictional engagement established by the clutch means 116 of the
auxiliary driving assembly 110 above described.
The tension wrap packaging machine 10 is then permitted to revolve as many
revolutions as necessary to wind or wrap the wrapping material about the
package so as to cover the same with the required amount of wrapping
material.
After the package is wrapped, the machine is stopped, the wrapping material
cut off, and the package is removed from the horizontal bars by sliding
the same axially thereon. The ends of the wrapping material are closed by
hand and the package is ready to be shipped.
In the event that additional wraps of wrapping material are desired from
another or transverse direction to that of the initial application, the
same may be applied by repeating the operational steps for the machine as
above enumerated.
Thus, there has been described a tension wrap packaging machine for
creating a unitary package having a plurality of layers of plastic
material, tension wrap thereabout, which wrapped mate | | |
