CA1089751A - Strapping machine and method - Google Patents

Abstract

TITLE
STRAPPING MACHINE

ABSTRACT OF THE DISCLOSURE
A strapping machine and method for applying flex-ible, heat sealable straps around objects in which the supply coil of strap and the feed rollers for a strap accumulating compartment are driven by a common rotatable drive for synch-ronous feeding. A strap feeding unit for feeding flexible strap in which a feed and pinch roller extend through opposed slots which intersect a strap carrying groove which totally confines the strap.
A strap tensioning mechanism in which rough tension-ing and final tensioning are achieved by the movement of a single mechanical plate. A cutting and sealing head in which feeding of a new strap around the object can occur simultan-eously with the sealing of the previous strap. A track open-ing mechanism which is operated by components of the sealing and cutting head.

Description

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BACKGROUND OF THE INVENTION
Field of the Invention This invention pertains to methods and apparatus for wrapping objects with flexible, fusible strap.

SUMMARY OF THE INVENTION
The principal object of the invention is to provide a high speed strapping machine capable of strapping 80 straps a minute as compared to typical known strapping rates of 35 straps a minute. This is accomplished through simple mechani-cal movements, each combining several functions.
It is another object of this invention to provide animproved flexible strap supply and accumulating device. Basic-ally, this object is obtained by driving the reel or coil of strap for discharging strap synchronously with feed rolls for feeding the discharged strap into an accumulating compartment.
Another object of this invention is to provide an improved strap feeding unit for feeding flexible strap in a strapping machine. Basically, this object is obtained by con-fining the strap in an elongated transverse slot and bringing the powered and pinch rollers together through opposed grooves at right angles to the slot for driving the strap through the slot.
It is another object of this invention to provide an improved strap tensioning mechanism. Basically, this object is obtained by providing first means for pulling the strap around the object with a first tension, providing second means for drawing the strap tightly around the object at a second, greater tension, and actuating both of these means by a simple mechanical movement of a common plate. In the preferred em-bodiment the strap is anchored from the supply end until thefirst predeter~ined tension is reached, and then the anchor is overcome by the tension in the strap to provide removal of ad-ditional strap from the accumulator.
Still another object of the invention is to provide a cutting and sealing head for a strapping apparatus in which a first strap can be sealed while a second strap is simultan-eously being positioned around the object in the same plane.
Basically, this object is obtained by providing strap carrying slots in a platen and grippers which are acting on the first strap so that the strap can pass in a parallel path in the same plane into the track.
Still another object of this invention is to provide an improved track opening device for a strapping apparatus.
Preferably this object is obtained by using a rigid track and coupling the track at one location directly to movements of the members in the cutting and sealing heads so that a simple, single operation accomplishes opening of the track.
BRIEF DESCRIPTION OF THE FIGURES OF THE DRAWING
Fig. 1 is a front elevation of a strapping machine embodying the principles of the invention.
Fig. 2 is an isometric of a preferred strap supply and accumulator.
Fig. 3 is a fragmentary enlarged side elevation of a strap tensioning mechanism.
Fig. 4 is a fragmentary plan of the tensioning mech-anism shown in Fig. 3.
Fig. 5 is a side elevation of a strap feeding unit.
Fig. 6 is an end elevation of the strap feeding unit shown in Fig. 5.
Fig. 7 is a fragmentary detail of the strap feeding unit shown in Fig. 6.

~ 10897 51 Fig. 8 is an enlarged fragmentary front elevation of a cutting and sealing headA
Fig. 9 is an end elevation of the sealing and cut-ting head and illustrating a common cam shaft control for op-erating the elements of the cutting and sealing head.
Fig. 10 is a plan of the sealing and cutting head with elements removed for clarity.
Fig. 11 is an enlarged detail of the sealing and cutting head taken in a plane parallel to the direction of strap movement.
Fig. 12 is a section of the track taken along line 12-12 of Fig. 1.
Fig. 13 is a section of the track taken along line 13-13 of Fig. 1.
Fig. 14 is a section of the track taken along line 14-14 of Fig. 1.
Fig. 15 is a fragmentary perspective of part of the cutting and sealing head.
Fig. 16 is a schematic cam timing sequence.
Fig. 17 is a schematic isometric of a modified form of strap supply.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
As best shown in Fig. 1 the strapping machine in-cludes a strap track 10, a cutting and sealing head 12, a strap feed mechanism 14, a strap supply 16, a strap accumula-tor 18, a strap tensioning unit 20 and a cam control drive 22.
Basically, strap is fed through the strap feed mechanism 14 from the accumulator 18 through the tensioning unit 20. The strap feeds through the cutting and sealing head 12 around the track 10 and the free end of the strap hits an obstruction in the cutting and sealing head to stop its travel. Strap then .

,, 10~97S~i builds up in the strap feed mechanism signaling to the cam control drive 22 to begin a cycle of sealing, cutting and ten-sioning. During this cycle the free end of the strap is held while the strap is first roughly tensioned by the tensioning unit 20 to pull the strap out of the track snugly around the object being wrapped. Secondly, the strap is then tightly tensioned around the object and the continuous end of the strap is clamped in the tensioned condition. Next the contin-uous end which underlies the free end, and the free end are pressed against a heating bar until the strap is melted and then the strap is pressed tightly together with the continuous end severed. After cooling the cutting and sealing head opens so that the strap can be removed with the object and a new cycle of feeding the strap around the track is begun. The machine and the method of strapping objects offer advantages over known prior art machines and methods which advantages will be discussed in more detail during the description of each of the sub-assemblies of the machine.
STRAP SUPPLY AND ACCUMULATOR
The strap supply is best shown in Figs. 1 and 2 and includes a coil 24 containing strap S. The coil rests on a pair of shafts 25 and 26. Shaft 26 is provided with a rubber friction cover beneath the coil and is provided with a larger diameter roller 26a at its end. Shaft 26 thus serves as a powered feed roll to pull the strap from the coil via guide rollers 24a and 24b and push it into the accumulator 18.
Shaft 26 is driven by a belt and pulley drive 27. A pinch roller 28 is spring-mounted to press against the powered roll-er 26a.
The accumulator 18 includes a back plate 30 and a closely spaced clear plastic front plate 31 which forms a - . , ,: : : :. . . .

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housing for the strap. The strap is pushed upwardly into the housing in accordion folds as best shown in Fig. 1. A paddle 32 is pivotally mounted and protrudes down into the top of the housing. The paddle has a low switch operator surface 321 and a full switch operator surface 32f. As the accordion folds build up in the housing the paddle is raised until surface 32f closes a full switch FS to stop the feed. As strap leaves the accumulator the level of the folds drops deactivating the full switch and when the level drops sufficiently so that surface 321 energizes low switch LS the feed roller 26a is again put into motion to increase the supply of strap within the accumu-lator. An empty switch ES will stop the machine if strap no longer is available due to an empty coil 24.
In known plastic strap supplies and accumulators the feed rolls for the accumulator pull the strap from the coil by pulling directly on the strap. A brake is then used to stop the freely rotating coil. Using this technique the payoff speed is limited because the snap in the strap accelerates the coil and the coast of the coil reel at the end of feeding makes the braking action very critical. In the instant appli-cation the feed rolls for driving the coil and feeding the strap are advantageously very simple and require no separate brake for the coil. The drive on the powered shaft 26 oper-ates through a clutch which brings the coil up to speed slowly and the coast at the end of feeding is not a concern since it merely adds a slight amount of additional strap to the accumu-lator. Using this unique technique the strapping machine is able to be run at higher speeds than in the known strapping machines. A further advantage is that with known strap sup-plies a separate reel is needed to hold the coil whereas inthe supply and accumulator of this invention the coil is mere-ly set directly on the supporting shafts 25 and 26. Still further, the strap leaves the coil at a constant linear speed regardless of changes in diameter of the roll.
As best shown in Fig. 17 a modified strap supply is shown. In this embodiment a reel 300 of strap S is rotatably mounted on an axle 302 which is lifted up into suppart brack-ets 303. A belt 304 is pushed by spring 306 against the sur-face of the strap on the reel holding the reel into the brack-ets. The belt is driven by the shaft 26 which is coupled to feed roller 26a. Thus the belt and feed roller are rotated synchronously and the linear speed of the strap leaving the reel and passing through the feed pinch rollers in the same, or as in the embodiment of Fig. 2, slightly greater at the ; pinch rollers, regardless of diameter changes in the strap on the reel.
STRAP FEED MECHANISM
The strap feed mechanism 14 is best shown in Figs. 1 and 8. The feed mechanism includes a continuously rotating powered roller 34 which rotates in a counterclockwise direc-tion. A spring biased pinch roller 35 actuated by solenoid192 presses the strap against the powered roller. The rollers 34 and 35 push the strap along a guide channel 36. As best shown in Fig. 7 the guide channel is provided with a slot 36a and the peripheral surfaces of the rolls 34 and 35 are of ; reduced thickness which is less than the width of the slot 36a. The strap is thus contained at all times and is sup-ported against buckling as it is driven by the rollers through the channel 36. This is an advantageous feature as buckling of the strap has been a problem with known strap-feeding mech-anisms. Known strap-feeding mechanisms generally interrupt the strap guide or channel by breaking the channel upstream and downstream of the feed rollers. This necessitates cham-fering the inlet to the downstream end of the track as the strap is fed from the feed rollers. It is in this area of the chamfer, however, where resistance to the movement of the strap causes the tendency to buckle. As is readily apparent in the instant in~ention of this application there is no cham-fer nor interruption of the channel so that the buckling does not occur.
The strap feed mechanism 14 also includes a compart-ment 38 having a paddle 39 that forms a portion of the chan-nel 36 as it passes over the compartment. The paddle is piv-otally mounted and held by a light spring 40 in the raised position. The paddle is provided with a cam 41 that engages a stop switch S. As strap is fed by the rollers 34 and 35 through the channel 36 the free end of the strap passes through the cutting and sealing head 12 around the track 10 and comes to rest again in the cutting and sealing head. When the free end of the strap is blocked the continuous end in the channel 36 begins to back up pushing the paddle 39 downwardly and activating the stop switch S. This de-energizes the sole-noid 192 and allows a spring to move the pinch roller 35 away from the powered roller 34 to discontinue feeding of the strap and energizes a trigger solenoid 43 (Fig. 1) which pulls a trigger 44 away from a single revolution clutch 45 which is the basic drive component for the cam control drive 22 to be-gin the rest of the cycling of the machine.
TENSIONING UNIT
The tensioning unit 20 is best shown in Figs. 1, 3 and 4 and includes a plurality of freely rotating stationary take-up rolls 48 alternated with freely rotating movable take-up rolls 49. The strap feeds up and down the rolls 48 .. . .

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and 49 as shown in Fig. 3 and when the movable rolls 49 are shifted to the phantom line position in Fig. 3 it can be seen that a considerable amount of strap can be pulled back from the track 10 at the downstream end of the strap. The take-up rolls provide a rough or large retraction of the strap to pull it out of the track 10 and snugly around the object being wrapped. At this time, of course, the free end of the strap is clamped at the cutting and sealing head so that only the continuous end is retracted by the take-up rolls. The strap between the take-up rolls and the accumulator passes over a pair of flanged rollers 50 in between which is fastened an anvil 51. The anvil has a smooth end surface Sla. A pair of spaced anchor arms 52 are pivoted on a plate 53 by pivot post 54. Pivotally mounted between the anchor arms is an anchor block 56 having a protruding wedge 56a. The anchor block has a surface 56b that rides against a pin 57. A spring 58 con-nects to the anchor arms at a point 58a and pulls the arms toward the anvil to pull the wedge 56a against the strap and press it against the smooth end surface 51a of the anvil. The strap is thus trapped and unable to move from the accumulator during rough tensioning. As the strap is drawn tight on the package, however, the tension increases so that the anchor block begins to rotate relative to the anchor arms and over-comes the force of the spring 58a. When the tension reaches a preset desired amount the anchor block swings over-center rel-;~ ative to the spring away from the strap and anvil. This frees the strap for movement from the accumulator as the rollers 49 continue to move toward the right. The anchor arms are fixed to a lever 59 that is engaged by a shoulder 60 that forms part Of a T-shaped frame 61. The T-shaped frame is attached to a movable front plate 62 which carries the movable rollers 49 ~ 9751 and reciprocates from left to right as shown in Figs. 1 and 3.
When the front plate 62 is to the left the lever 59 is rocked counterclockwise so that the anchor block is freed from the tape. As the front plate moves to the right, however, the spring 58 pulls the anchor arms 52 toward the anvil to bring the anchor block into engagement with the strap.
The front plate 62 slides on ways 64 and is pulled to the left by a spring 65 (Fig. 1). The upper end of the plate is s~pported by a roller 63 running in a slot in a fixed bar 63a. The front plate is coupled to a tension arm 70 that is coupled to a bell crank 71. The free end of the bell crank is provided with a cam follower 72 that follows a cam 73 which is fixed to a cam shaft 76 that is coupled to the single revo-lution clutch 45. ~hus the tension arm begins to swing the front plate 62 to the right when the single revolution clutch is energized after the free end of the strap has completely encircled the object and has come to rest within the cutting and sealing head.
Spaced just above the front plate 62 is a knurled 20 tension roller 80 that is coupled to a slip clutch 82 (Fig. 4) such that the roller 80 is free in the counterclockwise direc-tion as shown in Fig. 1 but will engage the clutch 82 when ro-tated clockwise and provide a drag to a predetermined desired amount. The strap is pinched against the tension roller 80 by an eccentrically mounted pinch roller 84. The pinch roller is connected to a tension lever 86 of having a cam follower roll-er 87. The lever is pulled down by a spring 88. As the front plate 62 moves to the right during a tensioning cycle the cam roller 87 riding on the top of the plate keeps the pinch roll-er 84 away from the flanged tension roller 80 so that the strap can be freely drawn back by the rollers 49. The top ~U897Sl surface of the plate 62 has a downward ramp 92 and an upward ramp 94. When the front plate moves to the right a distance sufficient to allow the roller 87 to move past the downward ramp 92 the tension lever 86 swings counterclockwise to engage the pinch roller 84 against the tension roller 80. The strap is also pushed to the right (Fig. 3) by a roller which rotates on the movable frame 61 until the tension reaches the desired load on the slip clutch 82 and allows the strap to rotate the roller 80. Continued movement of the front plate 62 to the right draws the roller up the up ramp 94 allowing the dog 89 to seat beneath the notch at the end of the tension lever to hold the tension lever up and in an inactive position away from ramp 92 as the front plate is returned. When the front plate is returned to the left a pin 96 engages the dog 89 to release the tension levers so that the roller 87 returns to the top surface of the front plate 62. An adjustment bar 67 is connected to plate 62 by screws and can be moved to the left to overlap ramp 92 with a second ramp 92a thus changing the starting time of the final tensioning.
Known strapping machines usually employ two tension-ing devices. The first dra~s the strap around the package more or less loosely. The second comes into action and draws the strap up to its final tension. In the instant application the invention performs both of these operations by a single mechanism requiring only a single timing sequence. This ad-vantageously results in simplicity of manufacture and opera-tion and greater strapping and tensioning speeds.
CUTTING AND SEALING HEAD
As best shown in Figs. 1 and 8-14 the cutting and sealing head 12 is provided appro~imately centrally in the lower run of track 10 and forms a part thereof. The track -' 10 9 5~ :
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includes a rectangular plastic strip 100 having a groove 102 for receiving the strap. The track is abutted against a cover 104 by springs 105. The track is mounted on a pad 106 which slides on posts 107. Stripper pins 108 pass through the track and pass into the groove 102 as the track and pads are moved away from the cover. Thus the stripper pins eject the strap from the track groove to prevent binding. The track pads are connected to track bars llO which are engaged by paddles 182 and 184 to be described to open the track during the desired timing sequence of the strapping cycle.
The sections of track immediately adjacent the cut-ting and sealing head 12 are best shown in Figs. 12-14. Fig.
12 which is taken along the line 12-12 of Fig. 1 shows the groove 102. Fig. 12 also shows groove 36a below the groove 102. This second groove is to allow the continuous strap to move in beneath the captured free end of the strap and for beginning the threading of a new strap during the sealing cycle. Fig. 13 illustrates only the groove 102 since at this location along the track there is only a single groove as the free end of the strap is stopped in the cutting and sealing head.
The cutting and sealing head 12 is provided with a cover plate 116 that is movable transversely of the direction of strap movement. For clarity movements described as being transverse hereinafter will mean transverse to the path of the strap. Also in Fig. 10 which is a plan view of the cutting and sealing head it should be understood that the cover plate 116 has been removed for clarity. The cover plate forms an anvil for gripping and sealing the strap as will be described.
30 The cover plate 116 is reciprocated by a cam follower 118 which rides on a cover plate cam 119. A left hand gripper 120 W7`51 pivotally mounted in a left hand yoke 120a which is pivot-ally mounted for vertical movement between an upper position as shown in Fig. 11 where it can clamp the continuous end of the strap to the cover plate. The left hand gripper is mov-able into a lower position as shown in phantom lines in which the free end of the strap engages a stop surface 121 to stop the strap as it makes a loop around the track 10. The left hand gripper is provided with a track groove 122 which allows feeding of new strap while the gripper 120 is raised holding the previous loop of strap. The left hand gripper is free to move downwardly and is held in its raised position by a cam follower 124 that rides on a left hand cam 125. A spring 123 buffers the force between the gripper and the gripper yoke.
A right hand gripper 128 is vertically reciprocally mounted and is moved down by a cam follower 130 that rides on a right hand gripper cam 131. The cam follower 130 pulls the right hand gripper down against the force of a set of Be~le-ville springs 134. These springs when allowed to push the right hand gripper up press the gripper teeth of the right hand gripper against the strap to anchor the free end of the strap against the cover plate 116. The right hand gripper is provided with a track groove 136 which provides a lower path for the strap as the free end of the strap passes between the cover plate and the upper surface of the right hand gripper on its way to the stop surface 121 on the left hand gripper.
A platen 138 is pivotally mounted on a platen yoke 138a. The platen yoke is pivotally mounted for movement be-tween the left hand and right hand grippers and between an upper position as shown in solid lines in Fig. 11 in which it presses the lower continuous end of the strap against the upper free end of the strap and against the stop plate 116 to `- ~089751 squeeze the straps together after melting. The platen is provided with a lower groove 140 for allowing the continuous end of the strap to be moved beneath the sealed loop of strap for starting a new feeding cycle. A cam follower 142 follows a platen cam 143 to move the platen upwardly from the phantom line lower position to the solid line position shown in Fig.
11. A spring 189 presses the platen with a small force during heating and Belleville springs 190 press the platen with a greater force for bonding the melted ends.
A heater bar 147 is mounted for transverse movement by a cam follower 148 that follows a heater bar cam 149. The heater bar moves between the two runs of strap and melts the strap as the platen presses the straps together by spring 189 and then is removed prior to final pressing of the straps to-gether by the platen through springs 190. The left hand grip-per yoke 120a and the platen yoke 138a are pivotally mounted on an innerslide 160 that is reciprocally mounted for trans-verse movement. Springs 162 urge the left hand gripper and platen to seat against their respective yokes. The inner slide is reciprocated by a follower 163 that rides between cam surfaces on an inner slide cam 164 and the back of cover plate c~m 119. Thus while the platen and left hand gripper can move up and down they also are moved transversely by the inner slide. Springs 170 move the cover plate to the left and the cam follower 118 moves it transversely to the right.
OPERATION
The operation of the cutting and sealing head 12 is best described with a complete overall operation of the mach-ine. In the start condition the strap S has been loaded in the machine and fed around the track 10. The main drive motor M is running. The position of all elements of the machine are :-.. : : :: ~ . : :
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shown as in the drawings. At a signal to apply a strap the trigger solenoid 43 energizes and pulls the trigger away from the sin~le revolution clutch 45. This releases the clutch and engages the drive with a cam shaft 180 on which all of the various cams are mounted. The cam shaft begins to rotate and releases the right hand gripper 128. The right hand gripper is driven upward by the Belleville springs 134 and anchors the free end of the strap (in from its terminal edge) against the cover plate 116. Continued rotation of the cam shaft causes the inner slide 160 to move transversely to the right away from the strap. Since the platen 138 and the left hand grip-per 120 are mounted on the inner slide they also are pulled away from the strap to clear the strap area for tensioning.
The retraction of the inner slide also opens the strap guide track 10. This occurs by paddles 182 and 184 which are on the platen and left hand gripper, respectively, and which engage the track bars 110. Motion of the track pads 106 causes the stripper pins 108 to push the strap free of the track groove 102. Once S~e platen and left hand gripper are clear of the strap and the track is open the tension cam 73 drives the ten-sion arm 70 in a counterclockwise direction (as viewed in Fig.
1) and pushes the front plate 62 to the right to begin ten-sioning.
The first motion of the front plate allows the anchor block 56 to be swung down and clamp the strap to the anvil 51. Continued motion of the front plate 62 causes the strap to be drawn from the track down on the package. The strap is drawn by the alternate sets of moving and fixed roll-ers 49 and 48. When the strap is around the package and no more strap can be drawn from the track the tension in the strap increases and trips the anchor which releases and allows ': ,' :', `- ~08g~5~
-the strap to be drawn from the accumulator so that the front plate can complete its stroke. Toward the end of the front plate movement the tension lever roller 86 falls down the ramp 92 and allows the tension rolls 84 and 80 to close on the strap. The strap is then drawn to the final tension by the remainder of the front plate movement.
At the beginning of the tensioning, after the inner slide is retracted, the left hand gripper 120 and the platen 138 drop downward in response to the platen and left hand gripper cams. Near the end of tensioning, the inner slide 160 moves back to its initial position. During this motion the platen and left hand gripper, now in the lower position, come back underneath the just tensioned strap. This motion also allows the track to close. Thus at this moment the con-tinuous run of the strap is confronting the trapped free end of the strap. The left hand gripper is then raised to the up position by its cam and clamps the continuous end of the strap against the cover plate.
At the end of the tension front plate 62 movement the tension lever 86 rolls up the ramp 94 and separtes the tension rollers 80 and 84. Just as the left hand gripper comes up to the press the strap against the cover plate and thus against the underside of the free end of the strap the heater blade 147 moves in between the straps at the seal area.
Once the heater blade is in place the platen 138 rises to an intermediate position and presses against the strap by the spring 189. During this time a cutter 186 on the surface of the right hand gripper 128 shears the continuous end of the strap to separate it from the supply. At the intermediate position the platen presses the bottom strap, heater and top strap together so that the strap is melted for sealing. The - , ' . ~ . .
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`~' lb8g7si press force is determined by a spring and plunger between the platen and the platen lever which is pivoted on the axis 168.
At this time a switch 200 is actuated by cam 201.
The activation of this switch energizes a feed solenoid ~92 that draws the pinch roller 35 against the powered feed roller 34 by a lever 193. Because the strap is pressed between the rolls it is fed and passes through the channel 36, the groove 112 in track 10, the groove 136 in right hand gripper 128, the groove 140 in platen 138, the groove 122 in the left hand gripper 120, the groove 102 in the track 110 as it leaves the cutting and sealing head.
When the melting of the strap is complete the heater blade is pulled back by the heater cam 149. When the heater bar is clear of the strap the platen cam 143 drives the platen up hard against the overlapping ends of the straps and presses the melted sections together. The Belleville springs 190 be-tween the platen and the platen lever overcome the spring 18 and determine the pressing force. These springs 190 do not affect the heating force from spring 189, however, since they do not contact the bottom of the platen until the cam forces the platen up into its final press. After the melted plastic has hardened the left hand gripper 120, the platen 138, and the right hand gripper 128 move down to their initial posi-tions in response to their respective cams. After the grip-pers and platen have started down the cover plate 116 is re-tracted by its cam 119 against the force of springs 170 to allow the sealed strap to leave the sealing head. The cover plate immediately returns to the initial position after the strap is free.
After the tensioning part of the cycle the front tension plate 62 is returned by its cam 73 so that at the end 975~;

of the cam shaft rotation the front plate is back to its ini-tial position and has moved the dog 89 out from under the ten-sion lever 86 and has retracted the anchor block 56. Ready for the next cycle. At the end of the cam shaft rotation the trigger 44 engages the single revolution clutch 45 which then disconnects the drive from the cam shaft.
Just after the cover plate 116 closes, the end of the new feeding strap enters the sealing head and strikes the stop surface 121. ~eeding then stops when the strap backs up into the compartment 38. This completes the cycle of opera-tion.
Known strapping machines start the strap feeding part of the cycle only after the seal has been made and after the strap has been ejected from the machine or require that the strap be shifted sideways to clear the loop being sealed from the new strap being fed. As described above, in the in-vention of this application feeding of the new strap occurs in a single plane and during the sealing operation thus shorten-ing the total cycle time. Known strapping machines also use separate actuators such as air cylinders or solenoids to pro-vide the opening for~e for the track. In the invention of this ~pplication the motion of the gripper and platen in the sealing and cutting unit provide this opening force and is much simpler in construction and operation and far more re-liable. Known strapping machines rely on the lateral stiff-ness of the strap to keep the straps aligned with each other in the seal area. Since the slides and guides employed in known strapping machines and always the heater blade are mov-ing sideways relative to the strap, there is a tendency in the known strapping machines for the straps to be moved out of alignment thus producing misaligned seals. In the invention ' ...... ~ .... :. ' ',, '' ; ~ .
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of this application a stripper bar 203 is advantageously pro-vided to keep the two straps aligned rather than solely rely-ing on lateral stiffness of the strap. In known strapping machines the gripper for holding the free end of the strap prior to tensioning is generally done either by separate trig-gering mechanisms such as cylinders or solenoid or by the technique of coupling the gripper with motion of the seal head then stopping the head for tensioning and finally re-starting the head to complete the seal after tensioning is complete. In the invention of this application the initial gripper is applied, tensioning and sealing are all accom-plished with one revolution of a cam shaft giving simplicity, reliability and a very high-speed machine. -While the preferred embodiment of the invention has been illustrated and described and the known advantages appar-ent have been discussed, it should be understood that varia-tions and other advantages will be apparent to one skilled in the art without departing from the principles herein. Accord-ingly, the invention is not to be limited to the specific em-bodiment illustrated in the drawings.

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Claims (11)

CLAIMS:

1. In a machine for applying a flexible strap around an object, a strap tensioning mechanism comprising:
first means for pulling a loop of strap around the object with a first tension;
second means for pulling the loop of strap more tightly around the object with a second tension greater than said first tension; and mechanical control means for actuating said first and second strap pulling means in numerical sequence.

2. The strap tensioning mechanism of claim 1, in-cluding first means to anchor the free end of the strap, a supply, second means for anchoring the strap from the supply, said control means being operative to engage said second anchoring means prior to tensioning so that strap is pulled only around the object, and said second anchoring means in-cluding release means for freeing the strap from the supply when said first tension is reached in the strap, said second anchoring means including an anvil, an anchor member, an an-chor arm pivotally and resiliently carrying the anchor member toward and away from said anvil, and said release means in-cluding a resilient pivot connection in which movement of the anchor member against the strap and anvil will hold the strap until the tension in the strap reaches said first tension and then pulls the anchor member with the strap past the anvil so that the anchor member moves in the direction of strap move-ment and releases the strap.

3. The strap tensioning mechanism of claims 1 or 2, said control means including an elongated movable plate com-monly driving both said first and second pulling means in said numerical sequence, said first pulling means including a plur-ality of stationary strap engaging rollers, a plurality of movable strap engaging rollers secured to said movable plate for movement relative to said stationary rollers, the strap being alternately engaged by both sets of rollers so that movement of said movable rollers will extend the length of strap wrapped around said rollers.

4. In a machine for applying a flexible strap around an object, a strap tensioning mechanism for tightening the strap along a path between the object and the supply by retracting the strap from the object, comprising:
means for guiding the strap around the object and holding the free end thereof;
first means for moving the strap out of said path for pulling the loop of strap around the object with a first tension;
anchor means for releasably anchoring the strap be-tween the tensioning mechanism and the supply so that as said first means moves the strap out of the path the strap is held at its free end and the supply thus causing the loop of strap around the object to tighten onto the object;
second means for pulling the strap more tightly around the object with a second tension greater than said first tension;
mechanical control means for actuating said first and second strap pulling means in numerical sequence; and said second means including a set of rollers pinch-ing the strap and allowing movement of the strap toward the object at the second tension and only when the second tension is obtained, a second member for moving the strap out of the path between the set of pinching rollers and the object for tightening the strap around the object with said second ten-sion, and means for releasing said anchor means when said first ten-sion is exceeded to release the strap between the pinching rollers and the supply and avoid breaking the strap.

5. The apparatus of claim 4, said pinching rollers in-cluding a first roller having a slip clutch to allow free movement of the strap toward the supply but restricted movement of the strap at said second tension toward the object.

6. The machine of claim 1, including a strap supply and accumulating apparatus, comprising:
means for supporting a coil of strap for rotation about an axis of rotation;
coil drive means for directly engaging the strap on the peripheral surface of the coil for rotating said coil;
an accumulating compartment having an inlet and an outlet, feed roll means located at said compartment inlet for moving strap into said inlet;
means coupling said coil drive means to said feed roll means for substantially synchronous rotation of the feed roll means and coil drive means whereby the linear speed of the strap leaving the coil and the linear speed of the strap passing through the feed roll means are approximately equal during all strap move-ments; and means for controlling said coil drive and feed roll means for varying the quantity of strap fed into said accumulating compartment.

7. The machine of claim 1, including a rotatable coil and coil suporting means having a first rod parallel to the coil axis of rotation for supporting the peripheral surface of the coil and also forming coil drive means, and including a second rod freely rotatably mounted for rotation about an axis below and parallel to said coil axis, an accumulating compartment having an inlet and an outlet, feed roll means located at said compartment inlet for moving strap into said inlet, said feed roll means including an axial extension of said first coil supporting rod.

8. The machine of claim 6, said coil having a cen-tral axle, said means for supporting a coil including end brackets for carrying the central axle, said coil drive means including a belt in contact with the peripheral surface of the strap of the coil for rotating the coil by direct engagement with the strap of the coil, means for driving said belt, said belt driving means being coupled to said feed roll means for providing said synchronous movement between the belt and the feed roll means.

9. The machine of claim 1, including a strap feed-ing unit for feeding flexible strap, comprising:
a track guide having a transverse strap carrying groove and opposed slots at right angles to said strap carry-ing groove, a feed roller located on one side of said track guide and having a peripheral surface extending into said groove through one of the slots, a pinch roller located on the opposite side of said track guide and having a peripheral sur-face extending into said groove through the opposite slot, said slots having a transverse width less than the width of said groove so that the strap is confined top, bottom and at its side edges by the groove at the location of the feed and pinch rollers, means for rotating the feed roller, and means for pushing the rollers together for pushing strap along the groove.

10. A method for applying a flexible strap around an object comprising the steps of:
feeding strap from a supply in a path to and around the object;
clamping the free end of the strap;
anchoring the supply end of the strap;

moving the strap out of the path between the supply and the object to pull strap tightly around the object with a first tension;
releasably gripping the strap between the supply and the object with a force sufficient to allow the strap to be pulled from the supply with a tension equal to the desired final tension in the strap around the object;
releasing the supply end of the strap; and moving the strap out of the path between the object and the releasable clamping location so as to draw the strap more tightly around the object until the yieldable releasable pressure is reached in the strap.

11. The method of claim 10 in which said strap is moved out of said path in said numerical sequence by a single motion but at two different locations along the path of the strap between the object and the supply.