Strapping machine with easy access and feed guides

BACKGROUND OF THE INVENTION

Strapping machines are in widespread use for securing straps around loads. There are two principle types of strappers. One type is a manually operated hand tool that can be used, for example, around a job site. Another type of strapper is a stationary arrangement in which the strapper is fabricated as part of an overall apparatus. In such a strapper, the strapping head and drive mechanisms are typically mounted within a frame. A chute is likewise mounted to the frame, through which the strapping material is fed.

In a typical, stationary strapper, the strapping head is mounted at about a work surface, and the chute is positioned above the work surface and above the strapping head. Strap material is fed to the strapping head by a set of feed and take-up wheels. The strapping material is fed, by the feed wheels past the strapping head, around the chute and back to the strapping head. The free end of the strapping material is then grasped, such as by a first part of a gripping arrangement. The strap is then retracted by the take-up wheels and tensioned around the load. The tensioned strap is then gripped by a second part of the gripping arrangement. A cutter in the strapping head then cuts the tensioned strap (from the source or supply) and the strapping head forms a seal in the strapping material, sealing the strapping material to itself around the bundled load.

Strapping operations are typically secondary operations in that these operations are used for bundling or securing individual items into a single, large load. The straps themselves are not of commercial concern to the end user; rather, it is the bundled items that are of concern. As such, it is important to be able to strap and move the items quickly and in a cost effective manner.

To this end, improvements have been made to strapping machines. One such improvement includes an auto re-feed arrangement, such as that disclosed in Bell, et al., U.S. Pat. No. 5,640,899, commonly assigned herewith. In such an arrangement, in the event of a misfeed of strapping material, the misfed strap is cut and ejected from the machine. Fresh strapping material is then automatically re-fed by the feed wheels through the strapping head and around the load. It has been found that such an arrangement saves considerable time and labor vis-à-vis removing the misted or snapped strap and refeeding strap material into the strapper.

One drawback to the known re-feed arrangements is that they require separate feed and take-up wheels. That is, a pair of wheels (generally one driven and one idle) is required to feed the strapping material through the strapping head and the chute. A second, separate set of wheels (again, one driven and one idle) is required to take-up or retract the strap in order to tension the strap around the load. While these automatic re-feed arrangements have been found to save considerable time and labor, the requisite two pairs of wheels introduce additional maintenance concerns as well as timing arrangements with respect to the overall operation of the machine.

It has also been found that typically, these stationary types of strappers are designed and constructed such that the feed and take-up mechanism is located near to the strapping head. Because of the proximity of the feed and take-up arrangement to the strapping head, two sets of feed and take-up wheels are required in order to meet the overall operating requirements, given the physical constraints of the equipment.

Present designs of stationary strappers, which include a closely located feed and take-up mechanism to the strapping head, also include guide paths to, from and between components that are all fixedly mounted to the machine. In the event of maintenance or repair, the machine must be taken out of service for the duration of that work. In addition, skilled technicians are generally required to tend to the machine during the entirety of the maintenance or repair procedure.

It has further been observed that the guides of known strappers, that is those portions of the strapper along which the strap material is guided while it is fed around the strap path tend to clog with debris from the strapping material. This debris can either be residue from the plastic strapping material itself, or debris that is carried by the strapping material into the machine. Typically, these guides have very small clearances between the guides themselves and between the guides and the active (driven or idle, rotating) machine components. As a result, it is necessary, at times, to shut down the machine, open the guide paths and clear these guide paths of debris. Known machines typically require disassembly of those portions of the machine which, again, requires significant labor and time. In addition, strappers are known to occasionally jam, in which strap material may get caught at about the active machine components or between the active and stationary machine components. In order to clear or remove these jams, again, the guide paths require disassembly necessitating time and labor.

Another concern with known strapping machines is that at times, the strap is not aligned with itself prior to forming the seal or “weld”. In order to achieve maximum tension strength in the strap joint the strap should be fully aligned with an adjacent layer of strap prior to welding. This maximizes the area over which the weld is performed. Known strappers rely upon an alignment of stationary strap guides or paths in order to properly position the strap material in this aligned, adjacent arrangement. However, at times, the strap shifts as it is aligned or prior to welding, resulting in misaligned straps and less than optimal joint strength.

Accordingly, there exists a need for a strapping machine that utilizes modular components, specifically for the drive and sealing functions. Desirably, such modular components are readily removed and installed in machines to minimize the “down time” of such machines. Most desirably, such modular components are readily installed and removed, with minimal or no tools. Further, a need exists for a strapper that minimizes clogging and provides easy access to the guide areas. Again, most desirably, access is provided to these areas with minimal or no tools. Still more desirably, the guide pathway and covering therefor are formed as integral units further minimizing disassembly to clear these paths. In such a strapper, an auto re-feed arrangement is desirable without the use of separate feed and take-up wheels. A need further exist for a strapper in which strap alignment, prior to welding, is actively provided.

BRIEF SUMMARY OF THE INVENTION

A strapping machine positioning a strapping material around an associated load and seals the strapping material to itself around the load. The strapping machine includes a frame, a chute defining a strap path mounted to the frame, a modular feed assembly mounted to the frame, a guide mounted to the frame adjacent the feed assembly, and a modular strapping head mounted to the frame independent of the feed assembly and the guide.

The feed assembly is configured to feed the strapping material from a source to the guide. The guide is mounted to the frame independent of the feed assembly and the strapping head. The guide is configured to receive the strapping material from the feed assembly and to provide a path for the strapping material toward the strapping head.

The strapping head includes a body and provides a conveyance path for the strapping material to the chute. In one embodiment, the strapping head defines a first conveyance path for the strapping material from the guide to the chute, and a second conveyance path to receive a free end of the strapping material to seal the strapping material to itself.

Preferably, the strapping head includes an anvil movably mounted to the body and forming a part of the second conveyance path. The anvil is movable between a first conveying position in which the anvil is pivoted away from the body to enlarge the second conveyance path and a second sealing position in which the anvil is pivoted toward the body to narrow the second conveyance path.

The anvil can be pivotally movable toward and away from the body. Preferably, the anvil is biased toward the body. In this arrangement, strapping head includes a side plate pivotally mounted to the body. The anvil is fixedly mounted to the side plate. The strapping head can include a cam for moving the anvil between the first conveying position and the second sealing position. The cam cooperates with the side plate to pivot the anvil.

The present strapping machine further contemplates an embodiment in which a controller controls the operation of the strapping machine. The controller is operably connected to the feed assembly.

A sensor is disposed to sense the presence and absence of strapping material at the strapping head. The sensor includes first and second movable elements, preferably paddles, that cooperate with one another. The paddles are movable between a first position in which the sensor senses the presence of strapping material and a second position in which the sensor senses the absence of strapping material. The sensor is operably connected to the controller and when the sensor senses the absence of strapping material at the strapping head, a control signal is generated to initiate operation of the feed assembly in a refeed mode.

In a current embodiment, the sensor is mounted to the strapping head at about a strap exit path of the strapping material from the strapping head. Preferably, the paddles pivot about a common pivot pin. The strapping material engages the first paddle to pivot the paddles between the first and second positions.

The sensor can include a proximity sensor cooperating with the first and second paddles. The second paddle is positioned between the proximity sensor and the first paddle being. The first paddle is biased toward the proximity sensor and the second paddle is biased away from the first paddle. First and second biasing elements bias the first paddle toward the proximity sensor and the second paddle away from the first paddle, respectively.

A hinge stop limits travel of the first and second paddles away from one another. The second paddle operably contacts the proximity sensor during the feed mode and the take-up mode, and the second paddle is operably separated from the proximity sensor during a refeed mode.

A preferred strapping head includes a second conveyance path to receive a free end of the strapping material to seal the strapping material to itself. The second conveyance path is defined by a plurality of surfaces within the body. The surfaces define a substantially constant width path through the second conveyance path.

An entryway precedes the second conveyance path. The entryway has a larger path width than the conveyance path width. A gripper is disposed at a terminal end of the conveyance path.

The strapping machine further contemplates an easy access transfer guide mounted to the frame between the feed assembly and the strapping head. The transfer guide includes a fixed portion and a cover portion. The fixed portion is fixedly mounted to the frame independent of the feed assembly and the strapping head. The transfer guide is configured to receive the strapping material from the feed assembly and to provide a path for the strapping material toward the strapping head. The cover portion overlies the fixed portion along a plane that is substantially parallel to the a plane defined by a longitudinal axis and a width of the strapping material.

In a preferred arrangement, the cover portion is pivotally mounted to the fixed portion by hinges and is retained in place covering the fixed portion by at least one, and preferably multiple mechanical fasteners. Most preferably, the mechanical fasteners are knurled to permit tool-less loosening. In a current embodiment, fasteners include a hinge-supported portion, so that when the fasteners are loosened from the cover portion (e.g., pivoted away from the cover portion) the hinge-supported portions retain the fasteners mounted to the fixed portion.

The strapping machine can further include an easy access feed guide for covering at least a portion of the feed assembly. The feed guide includes a cover for covering at least a portion of the feed assembly and an arcuate guide wall transverse to the cover. The guide portion is generally parallel to the strapping material as is traverses through the guide. The guide wall is spaced from a periphery of one of the feed wheels at about an entry of the strapping material into the feed guide and converges toward a periphery of the one of the feed wheels as the guide wall approaches the nip of the feed wheels.

The cover portion is removably mounted to the fixed portion by mechanical fasteners. Preferably, the fasteners are knurled to permit tool-less loosening. Most preferably, hinge-supported fasteners are used to mount the cover to the feed guide. This permits the cover portion to be readily removed for quick cleaning.

These and other features and advantages of the present invention will be apparent from the following detailed description, in conjunction with the appended claims.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The benefits and advantages of the present invention will become more readily apparent to those of ordinary skill in the relevant art after reviewing the following detailed description and accompanying drawings, wherein:

FIG. 1

is a perspective view of an improved modular strapping machine in accordance with the principles of the present invention, the strapping machine being illustrated with the strapping head partially removed from the frame, and a portion of the frame missing at about the feeding assembly, for clarity of illustration;

FIG. 2

is a schematic illustration of the strapping machine function, illustrating the strap being fed around a load;

FIG. 3

is a partial perspective view of the modular strapping machine feed assembly and strapping head removed from the frame for clarity of illustration;

FIG. 4

is a partial perspective view of the feed assembly and the frame portion in which it is mounted;

FIG. 5

is a bottom view of the strapping head showing the anvil pivoted outwardly during the feed and retraction modes of operation;

FIG. 6

is a bottom view of the strapping head anvil showing the anvil pivoted inwardly as during the sealing (welding) operation of the strapping head;

FIG. 7

is a perspective view of a strap sensor embodying the principles of the present invention, the sensor being shown when in strapping machine is operating in the refeed mode;

FIG. 8

is a perspective view of the sensor when the strapping machine is operating in the retraction mode;

FIG. 9

is a perspective view of the sensor when the strapping machine is in the strapping mode;

FIG. 10

is an exploded view of the sensor;

FIG. 11

is a perspective view of the gripper and portions of the gripper path through the strapping head;

FIG. 12

is a side view of the gripper of

FIG. 11

; and

FIG. 13

is an exploded view of the gripper of FIGS.

11

and

12

.

DETAILED DESCRIPTION OF THE INVENTION

While the present invention is susceptible of embodiment in various forms, there is shown in the drawings and will hereinafter be described a presently preferred embodiment with the understanding that the present disclosure is to be considered an exemplification of the invention and is not intended to limit the invention to the specific embodiment illustrated.

It should be further understood that the title of this section of this specification, namely, “Detailed Description Of The Invention”, relates to a requirement of the United States Patent Office, and does not imply, nor should be inferred to limit the subject matter disclosed herein.

Referring to the figures and in particular, to

FIG. 1

, there is shown a strapping machine or strapper

10

embodying the principles of the present invention. The strapper

10

includes a frame

12

having a work surface or top

14

mounted thereto. The frame

12

defines a chute or strap path

16

about which the strap S is conveyed during a strapping operation. A strap supply P provides the strap material S for the strapper

10

.

The strap S is fed from the supply P into the strapper

10

by a feed arrangement

18

. The strap S is conveyed by the feed arrangement

18

, through a strapping head

20

into the chute

16

. The strap material S traverses through the chute

16

, and returns to the strapping head

20

. The free end (that is the first fed end of the strap S) is, upon return to the strapping head

20

, gripped by a first gripping portion

22

a

of a gripper

22

in the strapping head

20

. The feed mechanism

18

then reverses to provide tension in the strap S. When a desired tension is achieved, the strap S is gripped by a second portion

22

b

of the gripper

22

. The strap S is then cut to separate the strap S from the source P. The strap S is then welded or otherwise sealed onto itself. The load L is then removed from inside the chute

16

region or strap path and a new load is positioned therein for strapping.

Unlike known strappers, the present strapper

10

includes a modular arrangement in which the feed assembly

18

and strapping head

20

are removably mounted to the frame

12

. That is, the feed arrangement

18

, which includes generally a motor

24

, and a pair of feed wheels

26

,

28

, is mounted to a base

30

that is in turn mounted to the frame

12

. Referring to

FIG. 3

, there is shown an exemplary feed assembly

18

illustrating the motor

24

, a driven wheel

26

and an idler wheel

28

. The idler wheel

28

is mounted for free rotation with the driven wheel

26

when the strap material S is between the driven wheel

26

and the idler wheel

28

and the motor

24

is actuated.

To assure that the feed assembly

18

is properly mounted within the frame

12

, the feed assembly

18

and frame

12

include portions of a cooperating aligning and mounting assembly

32

. In one such arrangement, as shown in

FIGS. 1 and 4

, the frame

12

includes a

34

nesting member configured as a transverse beam element. The feed assembly

18

includes a complementary, cooperating receiving member

36

that aligns with the transverse beam

34

. In a current embodiment, the receiving member

36

is formed as a generally channel shaped aligning head

38

having a pair of slots or rounded notches

40

formed therein complementary to the beam

34

. The feed assembly

18

is positioned in the frame

12

such that the notches

40

are fitted onto the beam

34

. This aligns the feed assembly

18

in the frame

12

.

At a rear end

42

of the feed assembly

18

, the aligning and mounting assembly

32

includes a clamp

44

. The clamp

44

can be formed, for example, as a handle

46

that is mounted to a threaded stud

48

. The frame

12

can include a base portion

50

having a notch

52

formed therein. The notch

52

has an enlarged or V-shaped opening

54

to readily permit aligning the stud

48

in the notch

52

. As the feed assembly

18

is positioned on the frame

12

, the aligning notches

40

are positioned immediately forward of the beam

34

and the stud

48

is positioned in the open end

54

of the V-opening. The feed assembly

18

is then urged forward until the notches

40

are positioned on the beam

34

and the stud

48

is positioned in the base notch

52

. The handle

46

is then rotated to clamp the feed assembly

18

securely in place on the frame

12

. In this manner, a discharge area

56

of the feed assembly

18

(as illustrated in

FIG. 3

) is properly aligned with a strap guide (the transfer guide

58

) or strap guide for transport of the strapping material S to the strapping head

20

.

The strapping head

20

is mounted to the frame

12

in a similar manner. To this end, the strapping head

20

and the frame

12

include portions of a cooperating aligning and clamping assembly

60

. The frame

12

includes an upper base or shelf

62

having a transverse, forward lip

64

. The lip

64

has an opening

66

therein for receiving the strapping head

20

. The opening

66

is formed by a pair of walls

68

a,b

having aligning slots or notches

70

formed therein.

The strapping head

20

includes an aligning or nesting member

72

that, when the head

20

is moved forwardly in the frame

12

, resides in the aligning slots

70

. In a present embodiment, the aligning member

72

is formed as a beam or like member, and the aligning slots

70

in the walls

68

a,b

receive the beam

72

. A rear end

74

of the shelf

62

includes a notched opening

76

having an enlarged or V-shaped entrance

78

. The strapping head

20

includes a clamp

80

such as the exemplary threaded stud

82

, and a handle

84

for threading the stud

82

. As with the feed assembly

18

, when the strapping head assembly

20

is urged forward, the beam

72

is urged into the slots

70

as the stud

82

is urged into the clamping notch

76

. Once the strapping head

20

is properly positioned, the handle

84

is rotated to clamp the strapping head

20

in place on the frame

12

.

The present arrangement has a number of advantages over known strappers. First, the modular, tool-less arrangement permits readily changing out either the strapping head

20

or the feed assembly

18

. As such, as maintenance or repair is required on either the strapping head

20

or the feed assembly

18

, that portion of the strapper

10

can be removed and a spare inserted in its place. In this manner, the operational “down-time” of the machine

10

is minimized. That is, the strapping head

20

or feed assembly

18

can be removed and a spare installed in, perhaps less than a minute. That portion of the strapper

10

requiring maintenance or repair (e.g., the feed assembly

18

or strapping head

20

) can then be removed and taken away, for example, to a maintenance shop, where the necessary work can be carried out, away from the strapping machine

10

and other operations.

Another advantage provided by the present strapper

10

is that it establishes a distance between the feed assembly

18

and the strapping head

20

. Those skilled in the art will recognized that, at times, strapping material becomes jammed or are misfed into the strapper

10

. When this occurs, it is most desirable to have a strapper

10

having an auto eject and re-feed arrangement. In such an arrangement, the misfed strap is automatically ejected from the strapper and the strap feed is automatically restarted to place the strapper

10

back into operation. Thus, operator time and attention is minimized by automatically ejecting the misfed strap and automatically refeeding from the strap supply. An exemplary auto refeed arrangement is illustrated in the aforementioned Bell, et al., U.S. Pat. No. 5,640,899.

One drawback to known auto refeed arrangements is that there must be a sufficient distance between the feed wheels and the strapping head to prevent the strap material from being ejected beyond the feed wheels (by the take-up or tension wheels). This is of particular concern in that the machines operate at relatively high speeds and the detecting instruments and control system have certain reaction time constraints. That is, because the strap is conveyed so quickly through the machine, after a misfeed is detected, the strap can be ejected from the machine by the take-up wheels beyond the feed wheels, thus defeating the auto-refeed function. In other words, if there is insufficient distance between the strapping head (which is the location of the misfeed detector) and the feed wheels, the take-up wheels will eject the strap beyond the feed wheels. As such, there will not be fresh strap material to be fed through the feed wheels to the strapping head.

The present arrangement provides the necessary distance between a strap misfeed detector

86

(mounted on the strapping head

20

) and the feed wheels

26

,

28

. As such, only a single set of wheels (e.g., the pair of wheels

26

,

28

) is required for both the feed and retraction functions. In this manner, when a misfeed is detected, the feed wheels reverse to eject the misfed strap from the strapping head

20

. When the jammed or misfed strap is cleared, there is sufficient distance between the detector

86

and the feed wheels

26

,

28

for the feed wheels

26

,

28

to be stopped (from the reverse direction) and returned to the forward feeding direction.

Referring now to FIGS.

3

and

7

-

10

, the strap detector

86

assembly cooperates with the feed assembly

18

, that is the feed wheels

26

,

28

, to stop forward movement of the strap material S when a misfeed is detected, reverse the wheels

26

,

28

to eject misfed strap, and subsequently reinitiate forward movement (refeed) of the strap material S after the misfed strap is ejected. The misfeed detector

86

is mounted at about the top

88

of the strapping head

20

and includes a proximity sensor

90

and first and second biased elements

92

,

94

, respectively. In a present embodiment, the biased elements

92

,

94

are first and second paddles that are biasedly mounted to a base

96

at a detecting end of the proximity sensor

90

. The paddles

92

,

94

are hingedly or pivotally mounted to the base

96

by a common pivot pin

98

.

The paddles

92

,

94

are mounted such that the second paddle

94

is positioned between the first paddle

92

and the base

96

. A biasing element

100

, such the exemplary first spring biases the first paddle

92

away from the base

96

and the proximity sensor

90

. A second biasing element

102

, such as the exemplary second spring biases the second paddle

94

away from the first paddle

92

. In this manner, in order to maintain the second paddle

94

in contact with the proximity sensor

90

, a force must be exerted on the paddles

92

,

94

against the force of the first spring

100

.

The paddles

92

,

94

are positioned to lie across the strap path as indicated at

104

, e.g., on the top of the strapping head path, when there is no force exerted against the first spring

100

. Conversely, when a strap S is in the strap path

104

, and the paddles

92

,

94

are in the feed position (as seen in FIG.

9

), first paddle

92

is urged against its spring

100

force, toward the proximity sensor

90

. The second paddle

94

is operably connected to the first paddle

92

such that any force exerted on the first paddle

92

urges the second paddle

94

into contact with the proximity sensor

90

. Although the second paddle

94

is biased away from the first paddle

92

, the spring force of the first spring

100

is greater than the spring force of the second spring

102

. As such, the first paddle

92

forces the second paddle

94

, against the spring force of the second spring

102

, into contact with the proximity sensor

90

.

In the take-up position, as illustrated in

FIG. 8

, there is sufficient slack (or lack of tension) in the strap S to permit the first paddle

92

to “drop”. However, because some tension remains in the strap S, the first paddle

92

does not “drop” fully to rest on the top

88

of the strapping head

20

. Thus, even though the first paddle

92

has moved down (but not fully dropped) the spring force of the second spring

102

maintains the second paddle

94

in contact with the proximity sensor

90

.

Referring now to

FIG. 7

, the paddles

92

,

94

are shown in the refeed position, in which the strap S is fully full missing from the strapping head path

104

. In this position, the first paddle

92

fully “drops” to rest on the top

88

of the strapping head

20

, as urged by the force of the first spring

100

. Even though the force of the second spring

102

urges the second paddle

94

away from the first paddle

92

(upward, toward the proximity sensor

90

), a hinge stop

106

on the first paddle

92

at the hinge region

108

(best seen in

FIG. 10

) contacts a flat

110

on the second paddle

94

at the hinge region

108

, thus preventing further separation of the paddles

92

,

94

from one another. In this arrangement, contact of the hinge stop

106

with the flat

110

prevents the paddles

92

,

94

from separating from one another beyond an angle of about 45°. In this manner, when the strap S is fully missing from the strapping head path

104

, because the spring force of the first spring

100

is greater than the spring force of the second spring

102

, and due to the engagement of the hinge stop

106

with the flat

110

, the second paddle

94

is pulled from contact with the proximity sensor

90

. This initiates a refeed sequence in the strapping machine controller

112

.

This dual paddle

92

,

94

arrangement provides for continued contact of the second paddle

94

with the proximity sensor

90

when the strapper

10

is in the feed mode, and the take-up or retraction mode. As will be recognized by those skilled in the art, when there is a reduced tension on the strap material S, the first paddle

92

may move away from the second paddle

94

, however, it will not move so far as to permit the second paddle

94

to disengage from or lose contact with the proximity sensor

90

. Also as will be recognized by those skilled in the art, when there is a misfeed of strap S, when the seal or weld fails, or when the strap S breaks, the first paddle

92

will move fully away from the proximity sensor

90

, allowing the second paddle

94

to break contact with the sensor

90

.

When the detector

86

detects a misfed strap S (i.e., when the second paddle

94

breaks contact with the sensor

90

), the strapper S may be controlled such that the strapper

10

automatically operates in an ejection mode, in which any strap S remaining within the strapping head

20

is ejected therefrom. Following ejection, the auto refeed sequence can start in which strap material S is automatically refed by the feed wheels

26

,

28

up to the strapping head

20

. Detector arrangements other than that illustrated will be recognized by those skilled in the art and are within the scope of the present invention.

Referring now to

FIG. 3

, the present strapper

10

includes multiple easy access guides

58

,

114

. As their references suggest, these guides

58

,

114

provide ready access to the strap path in order to, for example, clean debris and/or clogs from the path. Unlike known strappers, the guides

58

,

114

are formed as part of removable sections of the strapper

10

. That is, while in known strappers, doors provide access to a fixed guide, the present guides

58

,

114

are formed as part of the removable portions of the machine

10

. As seen in

FIG. 3

, a feed guide

114

is formed as part of the removable section covering the feed wheels

26

,

28

.

The feed guide

114

includes a curved or arcuate guide portion

116

(shown in phantom lines) that extends from an entryway

118

below the feed wheel motor or drive

24

to about a nip

120

of the wheels

26

,

28

. At the entryway

118

, the guide portion

116

is spaced from a periphery of the driven wheel

26

. Traversing along the arc of the guide

114

toward the nip

120

, the guide portion

116

approaches the periphery of the driven wheel

26

. Referring to

FIG. 3

, it can be seen that the strapping material S enters the feed guide

114

, traversing below the feed drive

24

. The strapping material S is guided by the guide portion

116

into the nip

120

for feeding to the strapping head

120

.

In a current embodiment, the guide

114

is retained in place on the feed assembly

20

(covering at least a portion of the feed wheels

26

,

28

) by a plurality of threaded fasteners

122

, illustrative of which are the three fasteners shown. The fasteners

122

are preferably knurled to permit installation and removal without the use of tools, e.g., by hand. The fasteners

122

can be supported on hinged or pivoting supports

124

that, once loosened, permit pivoting the fasteners

122

away from the guide

114

to permit removal. In this manner, the fasteners

122

are maintained affixed to the feed assembly

18

, thus preventing inadvertently misplacing the fasteners

122

.

As will be appreciated from the figures, because the guide

114

itself includes that surface

116

on which the strapping material S travels during operation, the guide

114

can be readily removed from the feed assembly

18

, and the surface

116

cleaned of debris. The guide

114

can then be readily replaced on the feed assembly

18

. Again, this is unlike known guides which are fixed in place and are only accessible by pivoting door or access panel. In that, as set forth above, the tolerances are rather small and the spaces rather narrow through the strap path, the present easy access feed guide

114

provides numerous, readily appreciated advantages over the prior known guide access arrangements.

A bridging or transfer easy access guide

58

extends, as set forth above, between the feed assembly

18

and the strapping head

20

. In that this portion of the feed path extends between the two modular components, it is fixedly mounted to the frame

12

. However, this guide

58

is positioned in a region of the strapping machine

10

that is readily accessible even with the feed assembly

18

in place. In this manner, the path itself is readily accessibly to perform maintenance or, for example, to dislodge debris or jammed strap material S.

Additionally, the guide

58

is configured so that it is easily opened or uncovered to permit ready access to the strap path. The guide

58

includes, as provided above, a fixed portion

126

that extends between the feed assembly

18

discharge and the entrance of the strapping head

20

. A cover

128

is mounted to the fixed guide portion

126

that covers the fixed pathway

126

. Preferably, the cover

128

is hingedly mounted to the fixed portion

126

, by hinges

129

(one shown) so that it is readily pivoted open. In a preferred arrangement, mechanical fasteners

130

, such as the hinge-supported fasteners used for the feed guide

114

, are disposed on the fixed portion

126

, to maintain the cover

128

in place. Thus, to remove the cover

128

, it is necessary only to loosen the fasteners

130

(by hand, without the need for tools) and pivot them out of the way. The cover

128

can then be pivoted from the fixed path portion

126

(again, by hand, without the need for tools) to provide access thereto.

Also unlike known strapper path access doors, the present transfer guide cover

128

permits access to the strap across the width of the strap S. Conventional strapping machines include access doors that open to permit access to the strapping material at the thickness (i.e., the gauge measurement dimension) of the strap. Thus, grasping the strap can be a difficult and arduous task. As will be appreciated by those skilled in the art, providing access to the strap S at the width dimension provides a larger area in which to work and greatly facilitates access to debris or pieces of strap material S that may be lodged in the strap path

126

.

Referring now to

FIGS. 5-6

, the present strapper includes a novel strapping head assembly

20

that utilizes a moving anvil

132

. As will be recognized by those skilled in the art, the anvil

132

is that portion of the strapping head

20

against which the strapping material S is pressed during the sealing or welding operation. In order to increase the speed and efficiency of the operation of strappers generally, the strap path at this point is generally narrow and is typically sized only slightly larger than the strap S itself. To this end, known strapping machines include a constriction or throat at about the entrance to the at which debris can collect. Over time, the collection of debris at this area constricts the entrance to the anvil generally resulting in increased strap misfeeds and eventual maintenance of the machines.

The present strapper

10

includes a number of improvements that are directed to minimizing or eliminating this debris collection problem and minimal strap path size problem. Referring to

FIGS. 5-6

, there is shown a bottom view of the strapping head

20

. The head

20

includes two openings for receiving strap S. The first course of strap enters the strapping head

20

through a first opening indicated generally at

134

. As the strap S is conveyed through this opening

134

, it passes beyond the anvil

132

. That is, it traverses through that portion of the head

20

that forms the anvil

132

.

The strap S then traverses beyond the head

20

, through the chute

16

and around the load L. The strap S is then directed into second opening indicated generally at

136

. Once the strap S enters the second opening

136

, it is grasped at the free end by the gripper

22

and tension is provided by the take-up operation of the feed assembly

18

.

The anvil

132

is mounted to the strapping head

20

in a pivoting arrangement. That is, when the strap material S is fed through the strapping head

20

, the anvil

132

pivots outwardly, away from the strap path to enlarge the size of the opening

136

through which the strap material S traverses. In this manner, an increased area is provided for the material S to move through the strapping head

20

. Specifically, the width dimension w of the path is increased, as is, consequently, the height h dimension. Once the material traverses through the chute

16

and back up through the gripper opening

136

, the anvil

132

then pivots back into place. A guide edge

137

of the anvil

132

urges the strap material S into place (to overlie the prior course of strap S) and the strap S is sealed to itself.

This novel pivoting anvil

132

arrangement provides a number of advantages over fixed anvils. First, as set forth above, it increases the area of the opening

136

through which the strap material S traverses, thus, reducing the possibility for misfeeds. Second, the pivoting anvil

132

moves the strap material S into position so that the first and second courses of strap materials overlie one another for sealing or welding. This increases the assurance that the first and second courses of strap material S will overlie one another without misalignment, to provide optimum strap seal strength.

In a current embodiment, the anvil

132

is fixedly mounted to a side plate

138

of the strapping head

20

. The side plate

138

is pivotally mounted to the strapping head body

140

by a pivoting arrangement, such as the exemplary pivot pin

142

. The plate

138

is biased toward the body

140

. A cam

144

is positioned within the strapping head body

140

and cooperates with the side plate

138

. During the feed cycle, the cam

144

rotates and a lobe

146

on the cam contacts the side plate

138

, urging the side plate

138

away from the body

140

. This, in turn, pivots the anvil

132

away from the body

140

, thus enlarging the opening

136

. During the gripping, takeup and sealing (e.g., welding) cycles, the cam shaft

144

further rotates such that the lobe

146

disengages from the side plate

138

, thus, allowing the anvil

132

to pivot back into place. Those skilled in the art will recognized other arrangements by which the pivoting anvil

132

can be provided, which other arrangements are within the scope and spirit of the present invention.

In addition to the pivoting anvil

132

, as best seen in

FIGS. 11-13

, the present strapping head

20

includes a novel gripper path indicated generally at

148

, through which the first course of material traverses for gripping, prior to tensioning and sealing. Unlike known strappers in which the path tapers downwardly toward the gripper, in the present strapper

10

, the strap path

148

is formed from parallel walls

150

,

152

that provide a constant path width through the path

148

toward the gripper

22

. Although conventional design teaches away from such a constant cross-sectional path, it has been found that the benefits achieved by this path

148

configuration, that is less opportunity for debris collection and malfunction, far outweigh any of the disadvantages.

In the present disclosure, the words “a” or “an” are to be taken to include both the singular and the plural. Conversely, any reference to plural items shall, where appropriate, include the singular.

From the foregoing it will be observed that numerous modifications and variations can be effectuated without departing from the true spirit and scope of the novel concepts of the present invention. It is to be understood that no limitation with respect to the specific embodiments illustrated is intended or should be inferred. The disclosure is intended to cover by the appended claims all such modifications as fall within the scope of the claims.

Number	Name	Date	Kind
3759169	Goodley	Sep 1973	A
3768396	Coleman	Oct 1973	A
3913472	Buck	Oct 1975	A
4011808	Aoki et al.	Mar 1977	A
4050372	Kobiella	Sep 1977	A
4155799	Matsushita et al.	May 1979	A
4520720	Urban et al.	Jun 1985	A
4711071	Kägi	Dec 1987	A
5287802	Pearson	Feb 1994	A
5640899	Bell et al.	Jun 1997	A
5823103	Kuei	Oct 1998	A
6415712	Helland et al.	Jul 2002	B1
6478065	Haberstroh et al.	Nov 2002	B1

Strapping machine with easy access and feed guides

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (13)

Provisional Applications (1)