EP0152959A2 - Procédé et appareil pour la fabrication d'un emballage unitaire par enveloppement d'une charge - Google Patents

Procédé et appareil pour la fabrication d'un emballage unitaire par enveloppement d'une charge Download PDF

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Publication number
EP0152959A2
EP0152959A2 EP85101958A EP85101958A EP0152959A2 EP 0152959 A2 EP0152959 A2 EP 0152959A2 EP 85101958 A EP85101958 A EP 85101958A EP 85101958 A EP85101958 A EP 85101958A EP 0152959 A2 EP0152959 A2 EP 0152959A2
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EP
European Patent Office
Prior art keywords
load
film
wrapping
conveyor
film web
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Granted
Application number
EP85101958A
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German (de)
English (en)
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EP0152959B1 (fr
EP0152959A3 (en
Inventor
Patrick R. Lancaster
William G. Lancaster
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Individual
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Individual
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Publication of EP0152959A3 publication Critical patent/EP0152959A3/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B11/00Wrapping, e.g. partially or wholly enclosing, articles or quantities of material, in strips, sheets or blanks, of flexible material
    • B65B11/008Wrapping, e.g. partially or wholly enclosing, articles or quantities of material, in strips, sheets or blanks, of flexible material by webs revolving around articles moved along the axis of revolution
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B11/00Wrapping, e.g. partially or wholly enclosing, articles or quantities of material, in strips, sheets or blanks, of flexible material
    • B65B11/58Applying two or more wrappers, e.g. in succession

Definitions

  • the present invention generally relates to packaging and more particularly is directed to a rotating stretch wrapping apparatus for making unitary packages which hold a plurality of components, each package containing a load wrapped in a web of stretched film.
  • two consecutive wraps are applied by rotatable wrapping apparatuses at two consecutive wrapping stations along the load path.
  • the wrap is applied in a first direction across the direction of load motion, resulting in a wrap exhibiting helical bias and unit displacement within the load.
  • a second wrap is applied in a direction opposite the direction of the first wrap, resulting in an opposite helical bias with a unit displacement opposite that of the first wrap.
  • the film dispenser utilized at each wrapping station may advantageously be one which dispenses film at a supply speed independent of the varying takeup or demand speed of film-at the load.
  • Each film dispenser also includes a film stretching mechanism which elongates the film web above its yield point at ambient temperature prior to application thereof to the load, as is described herein.
  • the present inventive apparatus and process provide a distinct and widely-demanded improvement over the prior art, in that consecutive uniform loads are unitized without exposure to heat, stabilized and sealed at high throughput.
  • the resulting wrap exerts containment force and elasticity on all load sides.
  • Figures 1 through 3 shows a ring wrapping apparatus 30 comprising a feed conveyor 32, a wrap and load conveyor assembly 34, two film dispensing mechanisms 36 and 436 with a take-off conveyor 20.
  • a loading device 31 is schematically shown and may be one of a number of types of stacking or placing devices which are well known in the art to place a stack of cartons or materials into a designated area.
  • the load 24 is placed on an infeed conveyor 32 which is comprised of an endless belt 26 mounted on a frame support 28.
  • infeed conveyor could take the forms of, for instance, descending freewheel rollers or a hydraulic or pneumatic pushing device (not shown) which can be used to engage each load 24 with a platen to push the load into the wrapping area.
  • the conveyor embodiment is preferred and the conveyor belts of the present invention are preferably textured to develop a high coefficient of friction against the loads.
  • the conveyor belt 26 as seen in Figure 1 is mounted on rollers 29 which are rotatably journalled by suitable bearing means in brackets which are secured to the frame support 28.
  • the infeed conveyor 32 carries the loads 24 to a first wrapping station 41 comprising a film dispensing apparatus 36, and a wrapping conveyor assembly 34.
  • the first film dispenser 36 as shown in Figure 3 comprises a frame 42 on which a steel "donut" or ring-shaped film support member 44 is rotatably mounted and supported on three planes by guide rollers 46.
  • the film support member 44 can be constructed of aluminum.
  • a plurality of guide rollers 46 project inward from the frame 42 on arms 47 and mounting plates 48 to engage the ring member 44 so that it will rotate in a predetermined plane.
  • a friction drive wheel 49 is positioned adjacent the ring member 44 at its base and engages the ring member 44 to rotate the ring member 44 within the guide wheel rolling area.
  • the friction drive wheel 49 is driven by a motor 50 having a shaft which is suitably connected with a drive reducer 52.
  • a material roll dispensing shaft 54 is rotatably secured on bracket 71 to the ring member 44 for rotation on its axis and is adapted to receive and hold a roll of film material 56.
  • a belted drive ring 60 coaxial with and parallel to ring member 44 is rotatably mounted to frame 42, in a manner substantially as described above for ring member 44.
  • a friction drive wheel 39 is positioned in contact with ring 60 and driven by motor 37 which may be a variable speed or reversible motor, through reducer 35 to rotate ring 60. Alternatively, ring 60 may be fixed to frame 42.
  • the film web is passed through a pre-stretching or elongation mechanism 70 and is tucked or fastened underneath the load.
  • the pre-stretching mechanism 70 which is best seen in Figures 2 and 3, comprises connected roller members 72 and 74 which are rotatably mounted respectively on shafts 73 and 75 which are in turn journalled into a housing 76.
  • the housing 76 is mounted to ring member 44 across the plane of ring member 44.
  • the rollers 72 and 74 are interconnected by speed control means comprising gears 77 and 79 mounted respectively to shafts 73 and 75.
  • Gears 77 and 79 mesh together and operate so that the film web 58 passes first across the upstream roller 72 and then across the downstream roller 74 as it is pulled from film roll 56 to the load 24, with the downstream roller 74 driven at a faster rate than the upstream roller 72, causing the film to be accelerated and stretched preferably beyond its yield point and preferably at ambient temperature in a narrow space 80 between the two rollers.
  • the ratio of the gear 77 to the gear 79 preferably ranges from 5:4 to 4:1. More specifically, the ratio of the gears should be at least 2:1 in order to stretch film material passing across the rollers beyond the yield point of the material.
  • film material so stretched not only gains in tensile strength, but also will recover or retract to an elongation level less than the elongation level achieved during passage between the rollers.
  • stretched film is applied around a surface of constant circumference, such as a load, film recovery causes an increase in containment force on the load.
  • film stretched beyond its yield point does not recover instantaneously, and the method of the present invention completes the load wrapping and sealing well before recovery produces the final tension in the film. Advantages of this condition will be further set forth below.
  • rollers 72 and 74 supply film at a constant speed, then there is no. deceleration which could cause film roll 56 to spill film.
  • the speed of roll 56 need not be independently regulated and a small amount of friction may be exerted constantly on film roll mandrel 54, so that roll 56 will stop spinning when the ring member 44 stops rotating.
  • a pivoting collar 83 is placed around upstream roller shaft 73, and a counterweight 85 and contact frame 84 are mounted at angles to the collar 83.
  • a contact roller shaft 51 is rotatably mounted to frame 84 and carries contact roller 57.
  • Shaft 51 also carries contact roller pulley 53, and upstream shaft 73 carries upstream pulley 55.
  • Pulleys 53 and 55 are surrounded by belt 59, and the ratio of pulley sizes and the circumference of roller 57 are chosen so that the linear surface speed of roller 57 is no greater than the linear speed of upstream roller 72.
  • a coil spring 86 is coupled to frame 84 and housing 76 so as to constantly urge contact roller 57 against the surface of film roll 56 which decreases in radius as film web 58 is paid out during wrapping. Spring 86 forces the roller 57 to maintain contact with the surface of roll 56 during rotation of ring member 44.
  • Counterweight 85 exerts leverage on frame 84 to balance the effect of the force of gravity on roller 57 as ring member 44 rotates. Therefore, friction between roller 57 and film roll 56 will be maintained, and pay out speed of film web 58 from roll 56 will accelerate and decelerate precisely to match starts and stops of ring member 44.
  • counterweight 87 is mounted to ring member 44 opposite elongation mechanism 70.
  • the elongated drive mechanism 90 is best understood by referring to Figures 2 and 3.
  • a power shaft 61 is journalled to and extends beyond housing 76 at least to the plane of ring 60.
  • a power pulley 63 is mounted on power shaft 61 in the plane of ring 60.
  • Ring 60 is channeled to define side walls 64, and power belt 65 encircles ring 60 in the channel between the walls 64.
  • Belt 65 also is distended from ring 60 outward to pass around pulley 63.
  • a tensioner roller 69 mounted to frame 76 presses inward on belt 65 to maintain tension on belt 65 when rotary ring member 44 and stationary ring 60 are not precisely circular or coaxial.
  • belt 65 and pulley 63 may be provided with teeth to minimize slippage. Also the surface of ring 60 between walls 64 may be covered with material chosen to maximize friction with belt 65.
  • a transfer pulley 66 is mounted to this end of shaft 61.
  • downstream roller shaft 75 extends through housing 76, and downstream pulley 68 is mounted to downstream shaft 75.
  • a transfer belt 67 is mounted on pulleys 66 and 68 so that downstream roller 74 is rotated in the same direction as power pulley 63.
  • Pulley 66 may be a variable pulley for adjustment of the ratio of ring rotation speed to film payout speed.
  • ring 60 may be mounted for rotation in a manner similar to ring 44, and the rotation speed of ring 60 may be varied to change the net action of belt 65 and pulley 63, thus altering the film payout speed.
  • downstream gear 79 is mounted to downstream roller shaft 75, and engages upstream gear 77 which is mounted to upstream roller shaft 73.
  • upstream roller 72 rotates in the opposite direction of downstream roller 74 and power pulley 63.
  • Film roll shaft 54 is mounted to bracket 71 across ring member 44 at a distance from upstream roller 72 which is at least equal to the radius of a full film roll 56.
  • Film 58 is dispensed from roll 56 across the far side of upstream roller 72, then in an "S" curve between the upstream and downstream rollers and across the downstream roller 74. It can readily be seen that both the regulation of the film supply speed across roller 74 and the regulation of elongation achieved between rollers 72 and 74 are independent of variations in demand for film at load 24.
  • a film patn extension means comprising an idler roller 81 is journalled to an idler roller bracket 82 mounted to and across the plane of ring member 44. Film web 58 passes from the downstream roller 74 around idler roller 81 and then onto the load.
  • Idler roller 81 must be positioned less than 90 degrees around ring member 44 from the downstream roller 74, in order to avoid contact of film 58 with the load between the downstream roller 74 and the idler roller 81.
  • the idler roller 81 must also be separated from the downstream roller 74 a distance sufficient to avoid film web contact with housing 76, and also sufficient to expose a large area of film 58 to force variance caused by cornering on the load during wrapping.
  • Bracket 82 may be fixedly mounted perpendicular to ring member 44 or fixed thereto in an angled orientation, or gimballed thereto so that it "floats" or adjusts orientation on one or two axes in response to film path angles.
  • a pair of side conveyors 158 are positioned on either side of the load path and are in close proximity or in contact with opposing vertical side faces of the load 24.
  • Each side conveyor 158 comprises a bracket 136 secured to the frame, a skid-sleeve support 138 supported by the bracket 136, skid-sleeve 178 supported by the skid-sleeve support 138, and upstream pulley 172 and a downstream pulley 174 at opposite ends of the skid-sleeve 178.
  • a side conveyor belt or chain 170 circulates in a downstream direction while exposed at an upper edge of skid-sleeve 178, and then returns in an upstream direction within skid-sleeve 178.
  • Belt 170 encircles pulleys 174 and 172.
  • Upstream pulley 172, bracket 138 and support 136 are preferably located upstream from the wrapping station 41, while the skid-sleeve 178 preferably extends downstream through the wrapping station 41.
  • a side conveyor motor 162 is mounted to an overhead portion of frame 42, and is coupled to shaft 164 so as to rotate shaft 164 about its axis. An opposite end of shaft 164 is journalled to bearing 166 also coupled to an upper portion of frame 42.
  • a pair of pulleys 168 are mounted to axle 164 directly above each of the two pulleys 172.
  • a vertical belt 169 encircles each overhead pulley 168 and a second sheave of pulley 172 below. Therefore, operation of motor 162 will drive the circulation of side conveyor belts 170. As the upper portion of belt 170 moves downstream, it carries with it any film web 58 which may be wrapped around the load and the skid-sleeve 178.
  • Skid-sleeve 178 is preferably configured of a material chosen for low friction with the film web 58. As each wrapped load passes the downstream end of each side conveyor 158, the tensioned film web which is wrapped against the load 24 will move off of the side conveyors 158 and resume its memory position against the side vertical face of the load 24.
  • the side conveyors 158 are especially well adapted for maintenance of load integrity under high and variable forces applied during wrapping of the load, and make the present invention especially useful for wrapping loads composed of large numbers of relatively small units.
  • the second film dispenser 436 surrounds conveyor assembly 34 so as to receive loads 24 previously wrapped by dispenser 36. It is a mirror image of dispenser 36 and is rotated in the opposite direction to counteract helical bias of the wrap.
  • the second film dispenser 436 comprises a frame 442 on which a steel "donut" or ring-shaped film support member 444 is rotatably mounted and supported on three planes by guide rollers 446.
  • the film support member 444 can be constructed of aluminum.
  • a plurality of guide rollers 446 project inward from the frame 442 on arms 447 and mounting plates 448 to engage the ring member 444 so that it will rotate in a predetermined plane.
  • a friction drive wheel 449 is positioned adjacent the ring member 444 at its base and engages the member 444 to rotate the member 444 within the guide wheel rolling area.
  • the friction drive wheel 449 is driven by a motor 450 having a shaft which is suitably connected with a drive reducer 452.
  • a material roll dispensing shaft 454 is rotatably secured on bracket 471 to the ring member 444 for rotation on its axis and is adapted to receive and hold a roll of film material 456.
  • a belted drive ring 460 coaxial with and parallel to ring member 444 is rotatably mounted to frame 442, in a manner substantially as described above for ring member 444, on a side of ring member 444 opposite that of film roll 456.
  • a friction drive wheel 439 is positioned in contact with ring 460 and driven by motor 437 which may be a variable speed or reversible motor, through reducer 435 to rotate ring 460.
  • ring 460 may be fixed to frame 442.
  • the film web is passed through a pre-stretching or elongation mechanism 470 which is best seen in Figures 11 and 2 and comprises connected roller members 472 and 474 which are rotatably mounted on respective shafts 473 and 475 which are in turn journalled into a housing 476.
  • the housing 476 is mounted to ring member 444 on housing bracket 471 across the plane of ring member 444.
  • the rollers 472 and 474 are interconnected by speed control means comprising gears 477 and 479 mounted respectively to shafts 473 and 475.
  • Gears 477 and 479 mesh together and operate so that the film web 458 passes first across the upstream roller 472 and then across the downstream roller 474 as it is pulled from film roll 456 to the loads 424, and the downstream roller 474 is driven at a faster rate than the upstream roller 472, causing the film to be accelerated and stretched preferably beyond its yield point in a narrow space 480 between.the two rollers.
  • the ratio of the gear 477 to the gear 479 preferably ranges from 5:4 to 4:1. Preferably the ratio is at least 2:1 in order to stretch the film material of its yield point.
  • the film web is stretched by passage across the rollers 472 and 474 and will recover or retract to some lesser elongation during a time interval following passage across the rollers.
  • rollers 472 and 474 supply film at a constant speed, then there is no deceleration which could cause film roll 456 to spill film.
  • the speed of roll 456 need not be independently regulated and a small amount of friction may be exerted constantly on film roll mandrel 454, so that roll 456 will stop spinning when the ring member 444 stops rotating.
  • a pivoting collar 483 may be placed around upstream roller shaft 473, and a counterweight 485 and contact frame 484 may be mounted at angles to the collar 483.
  • a contact roller shaft 451 is rotatably mounted to frame 484 and carries contact roller 457.
  • Shaft 451 also carries contact roller pulley 453, and upstream shaft 473 carries upstream pulley 455.
  • Pulleys 453 and 455 are surrounded by belt 459, and the ratio of pulley sizes and the circumference of roller 457 are chosen such that the linear surface speed of roller 457 is no greater than the linear speed of upstream roller 472.
  • a coil spring 486 is coupled to frame 484 and housing 476 so as to constantly urge contact roller 457 against the surface of film roll 456 which decreases in radius as film web 458 is paid out during wrapping. Spring 486 counteracts the tendency of roller 457 to move away from the surface of roller 456 during rotation of ring member 444 due to centrifugal force.
  • Counterweight 485 exerts leverage on frame 484 to balance the effect of the force of gravity on roller 457 as ring member 444 rotates. Therefore, constant contact of roller 457 and film roll 456 will be maintained, and pay out speed of film web 458 from roll 456 will accelerate and decelerate precisely to match starts and stops of ring member 444.
  • counterweight 487 is mounted ring member 444 opposite elongation mechanism 470.
  • Elongation drive mechanism 490 is best understood by referring to Figure 2.
  • a power shaft 461 is journalled to and extends beyond housing 476 at least to the plane of ring 460.
  • a power pulley 463 is mounted on power shaft 461 in the plane of ring 460.
  • Ring 460 is channeled to define side walls 464, and power belt 465 encircles ring 460 in the channel between the walls 464.
  • Belt 465 also is distended from ring 460 outward to pass around pulley 463.
  • a tensioner roller 469 mounted to frame 476 presses inward on belt 465 to maintain tension on belt 465 when rotary ring member 444 and stationary ring 460 are not precisely circular or coaxial.
  • a transfer pulley 466 is mounted to this end of shaft 461.
  • downstream roller shaft 475 extends through housing 476, and downstream pulley 468 is mounted to downstream shaft 475.
  • a transfer belt 467 is mounted on pulleys 466 and 468 so that downstream roller 474 is rotated in the same direction as power pulley 463.
  • Pulley 466 may be a variable pulley for adjustment of the ratio of ring rotation speed to film payout speed.
  • ring 460 may be mounted for rotation in a manner similar to ring 444, and the rotation speed of ring 460 may be varied to change the net action of belt 465 and pulley 463, thus altering the film payout speed.
  • downstream gear 479 is mounted to downstream roller shaft 475, and engages upstream gear 477 which is mounted to upstream roller shaft 473.
  • upstream roller. 472 rotates in the opposite direction of downstream roller 474 and power pulley 463.
  • a film roll shaft 454 is mounted to a bracket 471 across ring member 444 at a distance from upstream roller 472 which is at least equal to the radius of a full film roll 456.
  • Film 458 is dispensed from roll 456 across the far side of upstream roller 472, then in an "S" curve between the roller 474.
  • Film path extension means comprising an idler roller 481 is journalled to an idler roller bracket 482 mounted to and across the plane of ring member 444.
  • Film web 458 passes from the downstream roller 474 around idler roller 480 and then onto the load.
  • Idler roller 480 must be positioned less than 90 degrees around ring member 444 from the downstream roller 474, in order to avoid contact of film 458 with the load between the downstream roller 474 and the idler roller 481.
  • the idler roller 481 must also be separated from the downstream roller 474 a distance sufficient to avoid film web contact with housing 476, and also sufficient to expose a large area of film 458 to force variance caused by cornering of the load during wrapping.
  • Bracket 482 may be fixedly mounted perpendicular to ring member 444 or fixed thereto in an angled orientation, or gimballed thereto so that it "floats" or adjusts orientation on one or two axes in response to film path angles.
  • a pair of side conveyors 258 are positioned on either side of the load path and are in close proximity or in contact with opposing vertical side faces of the load 24.
  • Each side conveyor 258 comprises a bracket 236 secured to the frame, a skid-sleeve support 238 supported by the bracket 236, skid-sleeve 278 supported by the skid-sleeve support 238, and upstream pulley 272 and a downstream 274 at opposite ends of the skid-sleeve 278.
  • a side conveyor belt or chain 270 circulates in a downstream pulley direction while exposed at an upper edge of skid-sleeve 278, and then returns in an upstream direction within skid-sleeve 278.
  • Belt 270 encircles pulleys 274 and 272.
  • Upstream pulley 272, bracket 238 and support 236 are preferably located upstream from the wrapping station 441, while the skid-sleeve 278 preferably extends downstream through the wrapping station 441.
  • a side conveyor motor 262 may be mounted to an overhead portion of frame 42, and is coupled to shaft 264 so as to rotate shaft 264 about its axis. An opposite end of shaft 264 is journalled to bearing 266 also coupled to an upper portion of frame 42.
  • a pair of pulleys 268 are mounted to axle 264 directly above each of the two drive pulleys 276.
  • a vertical belt 269 encircles each overhead pulley 268 and a second sheave of pulley 272 below. Therefore, operation of motor 262 will drive the circulation of side conveyor belts 270. As the upper portion of belt 270 moves downstream, it carries with it any film web 458 which may be wrapped around the load and the skid-sleeve 278.
  • Skid-sleeve 278 is preferably configured of a material chosen for low friction with the film web 458. As each wrapped load passes the downstream end of each side conveyor 158, the tensioned film web which is wrapped against the load 24 will move off of the side conveyors 258 and resume its memory position against the side vertical face of the load 24.
  • the side conveyors 258 are especially well adapted to maintenance of load integrity under high and variable forces applied during wrapping of the load, and make the present invention especially useful for wrapping loads composed of large numbers relatively small units.
  • Typical films which can be used in the stretch wrapping apparatus are EVA copolymer films with a high EVA content such as the films manufactured by Consolidated Thermoplastics "RS-50", Bemis “Super-Tough”, and PPD “Stay-Tight” films.
  • PVC films such as Borden Resinite "PS-26” can be used in the invention along with premium films such as Mobil-X, Presto premium and St. Regis which utilize a low pressure polymerization process resin manufactured by Union Carbide and Dow Chemical Company. This resin, called linear low density polyethylene, has significantly different stretch characteristics than previous stretch films. These characteristics allow the film to withstand the high stress of extreme elongation without tearing during wrapping of the load.
  • film, film material and film web are used interchangeably throughout the specification.
  • the wrapping conveyor assembly 34 as best seen in Figures 2 and 7 comprises a conveyor 92 stacked atop first and second side web carrier assemblies 94 and 98.
  • the conveyor 92 comprises an endless driven belt 96 mounted on a plurality of rollers 100, which are supported by a plate 102 secured in turn to a frame member (not shown) holding the rollers in a rotatable position as is well-known in the art.
  • Belt 96 is driven by any conventional motor and roller linkage (not shown).
  • the upper belt segment of conveyor 92 travels in a downstream direction shown by the arrow A with the lower segment of the conveyor returning upstream.
  • the assembly 34 extends through both the two film dispensers 36 and 436.
  • Each of the two side web carriers 94 and 98 comprise a driven sprocket 95 beneath one end of the conveyor 92, a free-wheel sprocket 97 beneath an opposite end of the upper conveyor 92, a chain track 93 positioned to extend between the sprockets 95 and 97, and a chain 91 encircling the sprockets 95 and 97.
  • the chain 91 moves in the direction of load motion along the outside edges of the conveyor 92, and returns in the opposite direction beneath the surface of conveyor 92.
  • the chain is exposed and horizontally supported by the chain track 93 along the edge of the conveyor 92, and is isolated by chain track 93 beneath the conveyor 92.
  • Driven sprockets 95 are driven by a motor means (not shown) of any well known conventional type so that the chain 91 moves at the same linear speed as the conveyor 92.
  • a motor means not shown
  • film web wrapped around the load and the conveyor assembly 34 will engage the portions of chains 91 moving downstream beneath the conveyor 92 and be transported thereby at a uniform speed, and it will not engage either the lower portion of conveyor 92 returning upstream or the interior portions of chains 91 moving upstream.
  • This construction allows two webs of film to be wrapped around a load 24 carried by the conveyor assembly 34 through the wrapping stations 41 and 441.
  • the stretched webs are wrapped around the conveyor assembly 34 and the load with both the load and wrap being carried by the conveyor assembly in the same direction.
  • the stretched webs beneath the conveyor assembly 34 assume memory position M against the bottom of the load in the space between the conveyor assembly 34 and take-off conveyor 20, allowing the contained load covered by stretched wrap to be carried away.
  • a contnuous sequence of loads may be wrapped in the manner described above, preferably separated on conveyor 34 by spaces S greater than the load height.
  • continuously wrapped loads are taken off of the conveyor 20 and are sealed and severed into separate loads away from the apparatus.
  • the take-off conveyor 220 carries the continuously spiral wrapped loads 224 connected together by the film overwrap from the wrapping stations.
  • the take-off conveyor assembly 220 carries loads 224 more slowly than conveyor 34, in order to decrease the length of spaces S between consecutive loads and the tension on film web in spaces S.
  • the spiral wrapped bundle 224 as seen in Figure 4 is severed into individual packages by a guillotine-like cutting apparatus 225 comprising a frame 227, two parallel bars 228 and 230 and a cutter wire 229 mounted to one of the bars.
  • the cutter wire 229 consists of a nichrome wire which is electrically connected to a source of energy. The resistance of the wire causes sufficient heat so that when the wire is reciprocated with the bars between the bundles 224, the wrap is severed forming encapulated loads 124.
  • the film material may also be simultaneously sealed at each edge, for example by heat applied through the bars, so that the forward edge of one load is sealed as the rearward edge of the preceding load is sealed.
  • sensor 131 projects a light source through the transparent film in the space S between the individual loads against a photoelectric reflector (not shown) to generate an electrical signal commanding the bar drive circuitry to activate pneumatic cylinders 236 driving together the sealer bars 228 and 230.
  • the cutter wire 229 is activated to cut through the film after the film has been clamped between the bars to sever the load 124 from the wrapped sprial bundle 224.
  • any standard circuit can be used to cause the pneumatic cylinders 236 to be activated when the sensor means senses a space between the loads 124.
  • a limit switch, contact switch, pressure sensitive switch or other suitable means can be used to activate the cylinders 236.
  • the bars are driven toward each other during the seal and cut and driven away from each other above and below the load surface for the next seal and cut to provide smooth, efficient operation.
  • the spiral bundle advances and the next spacing S between the loads 124 is sensed by the light sensor 131.
  • the sealing bars which have been previously driven away from each other allowing the loads to be transported are driven toward each other to seal and sever the wrapped loads in the same manner as previously discussed.
  • the film web is in a condition of minimal or zero tension, which permits sealer dwell time for cooling to be reduced to the range of 1 to 4 seconds or completely elminated, further enhancing overall throughput.
  • a traveling sealer-cutter mechanism 240 can be utilized when steady throughout loads is desired.
  • This type of device which is well-known and indicated schematically at Figure 4, surrounds a space S between consecutive loads and moves downstream apace with the loads during the seal and severance operations at the surrounded space S. The mechanism then moves upstream, passing around the load until its trailing end and the next space S are encountered, at which point the operation can be repeated.
  • film web Following severance, the film web recovers or retracts over time against the leading and trailing load ends to exert containment forces thereon.
  • film web was sealed at load ends only after recovery and under significant tension, which required far longer sealer bar contact and load motion interruption to cool the heated seal, or else under no tension and no corresponding end-to-end containment force.
  • feed conveyor 32 brings two initial loads 24 onto the wrapping conveyor assembly 34 which then carries the loads to predetermined wrap positions 41 and 441 within the rings 44 and 444 respectively, and the conveyor assembly stops, leaving the loads in stationary positions.
  • the leading edge of the film web 58 is tucked against the load within ring 44 and the leading edge of web 458 is tucked against the load within ring 444.
  • Rotation of rings 44 and 444 is then begun. Loads 24 are continuously carried through wrapping stations 41 and 441 by conveyor assembly 34, and rings 44 and 444 are rotated continuously.
  • frame 84 is pivoted and roller 57 is urged against roll 56 to maintain roll payout speed at or below the surface speed of roller 72.
  • Chains 170 and 186 are driven to match the speed of conveyor assembly 34, so web 58 in contact with chains 170 and 186 is transported downstream by the chains. As the loads pass each downstream pulley 174, the web 58 leaving contact with belts 170 recovers or retracts under tension against the sides of each load 24.
  • Ring 444 is rotated in the opposite direction from that of ring 44 so that the helical forces applied to the loads by web 58 will be balanced by the opposing helical forces of web 458, and longitudinal and circumferential forces will be reinforced.
  • Take-off conveyor 20, positioned to accept loads from the end of conveyor assembly 34, is constructed like the infeed conveyor and runs at a fixed fraction of the speed of the infeed conveyor.
  • a suitable mechanical means may be set up to make the drive of both the infeed conveyor and the take-off conveyor proportional to the reduction gearing assembly of the drive motor.
  • the motor slows down or speeds up to drive the wrapping mechanism at different speeds, the infeed and take-off conveyors are simultaneously speeded up or slowed down so that the load is moved to conveyor assembly 34 and taken away from the conveyor assembly 34 at consistent relative speed.
  • frame 484 is pivoted and roller 457 is urged against roll 456 to maintain roll payout speed at or below the surface speed of roller 472.
  • Chains 270 are driven to match the speed of conveyor assembly 34, so web 458 in contact with chains 270 and 186 is transported downstream. As the loads pass each downstream pulley 274, the web 458 leaving contact with belts 270 recovers or retracts under tension against the sides of each load 24. As the loads cross over the downstream end of conveyor assembly 34, the webs 58 and 458 leaving contact with chains 91 recover or retract under tension against the bottom face of each load 24.
  • the empty wraps between the loads are then severed and optionally sealed as previously discussed, and the sealed loads are taken away to another transport area.
  • the end wraps recover after severance to gradually apply end-to-end containment forces.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Basic Packing Technique (AREA)
EP19850101958 1984-02-23 1985-02-22 Procédé et appareil pour la fabrication d'un emballage unitaire par enveloppement d'une charge Expired EP0152959B1 (fr)

Applications Claiming Priority (2)

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US58277984A 1984-02-23 1984-02-23
US582779 1984-02-23

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EP0152959A2 true EP0152959A2 (fr) 1985-08-28
EP0152959A3 EP0152959A3 (en) 1986-10-22
EP0152959B1 EP0152959B1 (fr) 1990-05-09

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EP19850101958 Expired EP0152959B1 (fr) 1984-02-23 1985-02-22 Procédé et appareil pour la fabrication d'un emballage unitaire par enveloppement d'une charge

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EP (1) EP0152959B1 (fr)
CA (1) CA1244751A (fr)
DE (1) DE3577539D1 (fr)
GB (1) GB2154537A (fr)

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0197574A1 (fr) * 1985-03-13 1986-10-15 TOSA AUTOMAZIONI S.r.l. Machine pour envelopper un emballage dans un film étirable contractible à froid et/ou à chaud
EP0224766A1 (fr) * 1985-12-04 1987-06-10 Lantech, Inc. Procédé et dispositif d'enveloppement sous un important étirement
US4866909A (en) * 1985-12-04 1989-09-19 Lantech, Inc. High tensile wrapping process
AU700740B2 (en) * 1994-04-22 1999-01-14 Tkk Engineering Pty Limited Film wrapping apparatus and method
CN107031904A (zh) * 2017-05-31 2017-08-11 中国重型机械研究院股份公司 板材横向覆膜装置
DE102017204231A1 (de) * 2017-03-14 2018-09-20 Krones Aktiengesellschaft Verpackungsvorrichtung und Verfahren zum Umwickeln von Artikeln mit dehnbarer Folie
CN110182398A (zh) * 2019-06-10 2019-08-30 埃迪派克(天津)科技有限公司 一种卧式缠膜机控制系统
US10597181B2 (en) 2013-09-20 2020-03-24 Krones Ag Bottle wrapping apparatus employing thin film of stretching plastic material
CN111516922A (zh) * 2020-05-29 2020-08-11 杭州萱博健身器材有限公司 一种胶带打包机及使用方法
CN113665867A (zh) * 2021-08-09 2021-11-19 严锋波 一种工件防护膜缠绕输送控制调节机构
CN114834666A (zh) * 2022-05-31 2022-08-02 河北久丰农业机械有限公司 一种自动密封缠膜装置及缠膜方法
CN115258314A (zh) * 2022-08-06 2022-11-01 山东健源生物科技有限公司 一种青贮全混合日粮智能化全自动压制打包装置
CN116978637A (zh) * 2022-04-12 2023-10-31 苏州杰可拓智能科技有限公司 一种用于母线的绝缘胶带自动缠绕设备

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Publication number Priority date Publication date Assignee Title
DE3727076A1 (de) * 1987-08-14 1989-02-23 Focke & Co Vorrichtung zum umwickeln von gegenstaenden mit einer folienbahn
DE4121573A1 (de) * 1991-06-29 1993-01-07 Walter Wacker Vorrichtung zur herstellung einer umhuellung
SE9703463L (sv) * 1997-09-25 1998-09-21 Extena Plast Ab Förfarande och anordning för upplindning av böjliga långsträckta element till i en rad arrangerade delrullar och omslutande av dessa med en skyddsfilm av elastiskt material, samt en förpackning med omslagna rullar framställd enligt det uppfinningsenliga förfarandet
ITMI20091512A1 (it) * 2009-08-28 2011-02-28 Al Ma C Packaging S R L Procedimento per il confezionamento di gruppi di contenitori per prodotti liquidi alimentari, in particolare bottiglie di acqua e/o bevande, e fardello ottenibile per mezzo di tale procedimento
DE202022102324U1 (de) 2022-04-29 2023-08-01 Emba-Protec Gmbh & Co. Kg Verpackungsvorrichtung

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GB820866A (en) * 1956-08-24 1959-09-30 Sheridan Service Company Ltd Bundle tying machine
US3589091A (en) * 1968-09-06 1971-06-29 Cloud Machine Corp Method and apparatus for wrapping or labeling a package
DE2303590A1 (de) * 1972-01-26 1973-08-09 Transpak Consulting Ab Oy Vorrichtung zum aufwickeln von verpackungsumschlaegen
US4050220A (en) * 1975-04-15 1977-09-27 Lancaster William G Spiral bundler
GB2076772A (en) * 1980-05-20 1981-12-09 Lancaster W G Rotating stretch wrap apparatus
EP0140301A1 (fr) * 1983-10-29 1985-05-08 B. Hagemann & Co. Procédé et dispositif pour envelopper des paquets dans une feuille étirable

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US4204377A (en) * 1974-06-12 1980-05-27 Lantech, Inc. Process and apparatus for wrapping netting material around a load
US4302920A (en) * 1979-11-21 1981-12-01 Lantech Inc. Film web drive stretch wrapping apparatus and process

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB820866A (en) * 1956-08-24 1959-09-30 Sheridan Service Company Ltd Bundle tying machine
US3589091A (en) * 1968-09-06 1971-06-29 Cloud Machine Corp Method and apparatus for wrapping or labeling a package
DE2303590A1 (de) * 1972-01-26 1973-08-09 Transpak Consulting Ab Oy Vorrichtung zum aufwickeln von verpackungsumschlaegen
US4050220A (en) * 1975-04-15 1977-09-27 Lancaster William G Spiral bundler
GB2076772A (en) * 1980-05-20 1981-12-09 Lancaster W G Rotating stretch wrap apparatus
EP0140301A1 (fr) * 1983-10-29 1985-05-08 B. Hagemann & Co. Procédé et dispositif pour envelopper des paquets dans une feuille étirable

Cited By (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0197574A1 (fr) * 1985-03-13 1986-10-15 TOSA AUTOMAZIONI S.r.l. Machine pour envelopper un emballage dans un film étirable contractible à froid et/ou à chaud
EP0224766A1 (fr) * 1985-12-04 1987-06-10 Lantech, Inc. Procédé et dispositif d'enveloppement sous un important étirement
US4866909A (en) * 1985-12-04 1989-09-19 Lantech, Inc. High tensile wrapping process
AU595254B2 (en) * 1985-12-04 1990-03-29 Lantech, Inc. High tensile wrapping process
AU700740B2 (en) * 1994-04-22 1999-01-14 Tkk Engineering Pty Limited Film wrapping apparatus and method
US10597181B2 (en) 2013-09-20 2020-03-24 Krones Ag Bottle wrapping apparatus employing thin film of stretching plastic material
DE102017204231A1 (de) * 2017-03-14 2018-09-20 Krones Aktiengesellschaft Verpackungsvorrichtung und Verfahren zum Umwickeln von Artikeln mit dehnbarer Folie
CN107031904A (zh) * 2017-05-31 2017-08-11 中国重型机械研究院股份公司 板材横向覆膜装置
CN110182398A (zh) * 2019-06-10 2019-08-30 埃迪派克(天津)科技有限公司 一种卧式缠膜机控制系统
CN110182398B (zh) * 2019-06-10 2022-05-31 埃迪派克(天津)科技有限公司 一种卧式缠膜机控制系统
CN111516922A (zh) * 2020-05-29 2020-08-11 杭州萱博健身器材有限公司 一种胶带打包机及使用方法
CN111516922B (zh) * 2020-05-29 2024-06-04 杭州萱博健身器材有限公司 一种胶带打包机及使用方法
CN113665867A (zh) * 2021-08-09 2021-11-19 严锋波 一种工件防护膜缠绕输送控制调节机构
CN116978637A (zh) * 2022-04-12 2023-10-31 苏州杰可拓智能科技有限公司 一种用于母线的绝缘胶带自动缠绕设备
CN116978637B (zh) * 2022-04-12 2024-03-26 苏州杰可拓智能科技有限公司 一种用于母线的绝缘胶带自动缠绕设备
CN114834666A (zh) * 2022-05-31 2022-08-02 河北久丰农业机械有限公司 一种自动密封缠膜装置及缠膜方法
CN115258314A (zh) * 2022-08-06 2022-11-01 山东健源生物科技有限公司 一种青贮全混合日粮智能化全自动压制打包装置
CN115258314B (zh) * 2022-08-06 2023-08-22 山东健源生物科技有限公司 一种青贮全混合日粮智能化全自动压制打包装置

Also Published As

Publication number Publication date
DE3577539D1 (de) 1990-06-13
GB8504585D0 (en) 1985-03-27
GB2154537A (en) 1985-09-11
EP0152959B1 (fr) 1990-05-09
CA1244751A (fr) 1988-11-15
EP0152959A3 (en) 1986-10-22

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