Abstract:
An apparatus for debagging and loading bagged bottles into a production stream is provided with a debagging station and a loading station. The debagging station includes a pair of bristle rollers to grasp the bag flap and a cutting mechanism to sever the flap from the bag and thereby expose the bottles. The loading station includes an infeed table, a take-off conveyor, and an indexing pusher for moving the bottles on the infeed table toward the take-off conveyor. A control system sequentially and repetitively activates the pusher to move the bottles onto the take-off conveyor and activates the take-off conveyor to accelerate the bottles into a production stream.

Description:
BACKGROUND OF THE INVENTION 
     The present invention pertains to an apparatus for debagging bottles and feeding them into a production stream. 
     In the production of bottled goods, the bottles are often purchased in bagged lots which must be opened and fed seriatim into the production stream. A bagged lot is typically formed as a single layer of bottles which are arranged into a square or rectangular matrix. The grouped bottles are encased into a plastic bag, the open end of which has been closed by heat sealing or the like. The closing of the bag creates a sealed flap on one end. 
     Heretofore, the opening and feeding of the bagged lots of bottles has been conducted in labor intensive and inefficient ways. Generally, the bags have been opened by holding the flap and manually cutting the bags with a knife. Thereafter, the operator manually pulls the bag away from the array of bottles. As can be appreciated, the manual slicing of the bags is a slow and tedious task. Moreover, the operation poses not only a personal hazard to the worker, but also a risk of damaging the bottles. 
     Once the bottles have been removed from their bag, they are uniformly fed into the production stream. Typically the bottles are maintained in their rectangular array and successively advanced onto the production conveyor a row at a time. The feeding operation has primarily been accomplished through the use of a continuously moving conveyor belt or an indexing feeding mechanism. 
     In a conveyor feed system, the array of bottles is supported on a continuously moving horizontal feed belt. At all times, each of the bottles is urged toward the laterally driven production belt which directs the bottles into the production stream. Hence, as each row is removed by the production belt the next row is automatically moved forward for removal. However, during the remainder of the time the bottles are required to slide relative to the moving feed belt. Although, larger bottles may be adequately fed by this method, the smaller, less stable bottles have a tendency of tipping over and blocking the feeding process. 
     In an indexing feeding system, the bottles are supported on a feed table and advanced toward the production belt by a pusher member. The operation is controlled by a series of sensors which are mounted in the bed of the feed table at spaced intervals corresponding to the successive rows of bottles. By supporting the bottles on a flat, stationary table and containing the rear row of bottles with the pusher member, the blocking tendencies of the belt feeding arrangement are alleviated. However, because the operation is controlled by a series of sensors fixed to the feed table, it lacks versatility. In particular, these feeding mechanisms are specifically set up for a certain size bottle. The sensors must all be carefully moved and re-set to facilitate a change in the feeding of differently sized bottles. As can be readily appreciated, this task not only requires the time of a trained workman, but also results in a substantial amount of down time for the feeding mechanism. 
     SUMMARY OF THE INVENTION 
     The aforementioned problems are overcome in the present invention, wherein the bottles are easily and efficiently removed from their bags and fed into the production stream. More specifically, the present invention includes a debagging station and a loading station which are designed and coordinated to reduce the amount of manual operation. 
     The debagging step is accomplished by an assembly which comprises a pair of bristled rollers and a cooperating cutting mechanism. The rollers grasp the sealed flap on the bag and automatically pull it outwardly away from the bottles. With the end of the bag extended, the cutter mechanism slices open the bag without risk of damaging the bottles or injuring the operator. 
     The loading station includes a feed table adapted to accept the newly opened bottles in mass from the debagging station, a pusher bar, and a single sensor which all work in concert to feed any size bottle effectively and efficiently. The single sensor controls both the movement of the pusher bar and the movement of the take-off mechanism to feed the bottles into the production stream. This coordinated arrangement provides an unlimited versatility of properly feeding any size bottle into the production stream without adjustment. Moreover, by utilizing a stable, non-moving feed table and a containing rear pusher bar, the risk of toppling the bottles is essentially eliminated. 
    
    
     These and other objects, advantages, and features of the present invention will be more fully understood and appreciated by reference to the written specification and appended drawings. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective view of the debagging and loading apparatus; 
     FIG. 2 is a top plan view thereof; 
     FIG. 3 is a top plan view of the debagging station of the apparatus; 
     FIG. 4 is a cross-sectional view taken along line IV--IV in FIG. 3; 
     FIG. 5 is a cross-sectional view taken along line V--V in FIG. 3; 
     FIG. 6 is a cross-sectional view taken along line VI--VI in FIG. 3; 
     FIG. 7 is a fragmentary end elevational view of the debagging station; 
     FIG. 8 is a perspective view of the loading sensor; 
     FIG. 9 is a rear elevational view of the loading sensor; 
     FIG. 10 is a fragmentary top plan view of the loading sensor; and 
     FIG. 11 is a side elevational view of the take-off conveyor of the apparatus. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     In the preferred embodiment, the apparatus 10 includes a debagging station 12 and a loading station 14 (FIG. 1). The two stations are located adjacent one another so that coordinated action for feeding the bottles into the production stream can be achieved. The bottles 25 are generally supplied in bagged lots 23, which comprise a single layer of bottles arranged into a plurality of adjacent rows of bottles 25a-25h (FIG. 3). This array of bottles is encased in a closed plastic bag 42. Typically, one end of bag 42 is heat sealed such that a loose flap 40 is formed. 
     The debagging station 12 (FIGS. 1-7) includes a debagging table 16, a cutting mechanism 18 and a first pusher assembly 20. With little manual input, these elements cooperate to effectively remove the bag encasing the bottles and transport them to the loading station. 
     Debagging table 16 (FIGS. 1-3 and 7) includes a table top 22 defining an upper flat horizontal surface 24 on which the bagged lots 23 of bottles 25 are placed by the operator, and a plurality of upstanding legs 26 arranged in each corner thereof. Table top 22 is preferably rectangular in shape and defines first and second sides 28, 30 and forward and rearward ends 32, 34. Table top 22 further defines a pair of elongated gaps 27 along first and second sides 28, 30. 
     In the preferred construction, table top 22 includes a main body 22&#39; having a pair of opposite sides 28&#39;, 30&#39;, and a pair of edge bars 29. Edge bars 29 are used to define gaps 27 for pusher assembly 20, as will be more fully described below. Edge bars 29 are narrow, elongated members which are mounted to sides 28&#39;, 30&#39; in spaced, generally parallel orientations therewith. More specifically, each end of each bar 29 is spaced from one of the sides 28&#39;, 30&#39; by spacer blocks 31. Conventional fasteners (not shown) are used to fasten the ends of bars 29 and blocks 31 to body 22&#39;. 
     Cutting mechanism 18 (FIGS. 1-5 and 7) is positioned along first side 28 of table top 22, and includes a flap orienting device 36 and a cutter device 30. Flap orienting device 36 functions to lift the sealed flap 40 of bag 42 encasing the bottles 25, and pull the flap outwardly away from the bottles (FIG. 4). Once the flap has been extended in this manner, cutter device 30 is activated to slice the bag open for easy removal of the bottles 25 therefrom. 
     Flap orienting device 36 primarily includes a pair of opposed, horizontally oriented bristled rollers 44, 46 (FIGS. 1 and 4-5). Each roller 44, 46 includes an axle 48 and a plurality of closely aligned, radially extending bristles 40. Large numbers of equally sized bristles extend from each axle 48 so that no substantial gaps are presented along the peripheral ends 52 of bristles 50. As can be appreciated, ends 52 of bristles 50 collectively define the outer surfaces of rollers 44, 46. Preferably the bristles are composed of nylon, but could be composed of other materials. Rollers 44, 46 are vertically stacked such that only a small gap 54 is defined between the opposed adjacent ends 52 of the rollers&#39; bristles 50. Rollers 44, 46 are mounted in a housing 56 including a plurality of upstanding spaced apart sidewalls 58 and an interconnecting top wall 60. Each of the sidewalls 58 are provided with a pair of bearing mounts (not shown) for rotatably securing the ends of axles 48a, 48b. 
     Rollers 44, 46 are collectively driven by a motor 62 (FIG. 6). Motor 62 is a conventional electric motor having a drive spindle 64 provided with a drive pulley 66. One end of each axle 48a, 48b extends through one of the sidewalls 58 to facilitate coupling of the axles with motor 62. In particular, each of the axles 48a, 48b includes a roller pulley 68a, 68b which is fixed to the axle in any conventional fashion for rotation therewith. Drive pulley 66 and roller pulleys 68a, 68b are generally aligned and operatively coupled together by a drive belt 70. Drive belt 70 is wrapped in a serpentine manner around the roller pulleys 68a, 68b so that each of the rollers 44, 46 rotate in opposite directions. More specifically, as shown in FIG. 6, the upper roller 68a is rotated in a counter-clockwise direction, while the lower roller 68b is rotated in a clockwise direction at the same speed. As will be described below, this arrangement urges the flap 40 of bag 42 into gap 54. To accommodate the vertical stacking of the rollers, an idler roller 72 is also included in the drive train. Preferably, idler roller 72 is adjustably mounted to facilitate replacement of the belt 70 and to remove any slack which may develop therein. 
     A debagging sensor 65 (FIGS. 1-5 and 7) is secured along top wall 60 of housing 56, and includes a pair of gas springs 67, a central control 69 and a sensor bar 71. Gas springs 67 are each comprised of a cylinder 73, a piston (not shown) and a projecting piston rod 74. Each of the springs 67 are fluidly coupled via conduit 75 to control 69. Control 69 supplies pressurized fluid to the springs and senses the movement of the pistons via conventional proximity sensors and wires (not shown). Sensor bar 71 is an elongated member positioned to extend between rollers 44, 46 and the first row of bottles 25a supported on table 16. Sensor bar 71 is fixed to the distal ends of rods 74 to be resiliently projected a certain distance from rollers 44, 46 in its rest position. Preferably, the sensor bar 71 is secured to springs 67 by a bracket 76 and conventional fasteners (not shown). As will be described more fully below, debagging sensor 65 cooperates with flap orienting device 36 and cutter device 38 to coordinate the movements of the two components for an efficient operation. 
     To achieve the removal of the bottles from bag 42, the operator places a bagged lot 23 of the bottles onto table top 22 such that flap 40 lies adjacent rollers 44, 46. The ends 52 of the rotating bristles 50 will engage the loose flap and direct it into and through gap 54 (FIGS. 3 and 4). Rollers 44, 46 additionally pull the bag taut for easy and efficient cutting. 
     More specifically, as flap 40 is pulled through gap 54, bag 42 and bottles 25 are shifted towards rollers 44, 46. This shifting action causes the row of bottles adjacent the rollers to abut sensor bar 71 of debagging sensor 65 and shift bar 71 against springs 67 until the pistons thereof reach their most compressed positions. At this point, stoppage of the bottles occurs and is sensed by control 69, which in turn signals the cutter device 38. As can be seen in FIG. 4, stoppage of the bottles 25 tightly stretches the portion of the bag 42a positioned between the bottles and the moving rollers 44, 46 for an appropriate cutting operation. Sensor 65, therefore, performs the dual function of a top to prevent the bottles from progressing into the path of the cutter and of activating cutter device 38. 
     Cutter device 38 (FIGS. 1, 4-5, and 7) is comprised of a hot cutting wire 78, a cutting base 79, a rodless cylinder 80, and a track 81. Cutting base 79 is essentially a planar, upright C-shaped member having a pair of spaced apart horizontal arms 82 between which cutting wire 78 is tightly strung. Rodless cylinder 80 is fixedly attached to the bottom of base 79 in any known manner, to achieve the lateral movement of the cutting wire 78. Rodless cylinder 80 is shaped to matingly engage track 81 for reciprocal movement therealong. Track 81 is located beneath table top 22 and is oriented to be substantially parallel to rollers 44, 46. The rodless cylinder and track are generally well known to those having ordinary skill in the control art. Examples of rodless cylinder driving systems which can be used are those of Tol-o-matic of Minneapolis, Minn., Model No. BL100-1P or Assembly No. 0910-0006. Of course, other rodless cylinders or other types of driving arrangements could be used. Cutting wire 78 is electrically heated in a conventional fashion so that the plastic bag 42 is quickly severed when contacted thereby. Additionally, cutting wire 78 is sufficiently long to cut through the entire portion of the bag 42a stretched between the first row of bottles 25a and rollers 44, 46. The cutting operation is performed by moving cutting wire 78 in a direction parallel to rollers 44, 46. The cutting motion is effected by rodless cylinder 80 being driven along track 81. 
     Once bag 42 has been completely cut open, the operator manually removes the bag from the bottles. More specifically, a split rail 90 is mounted to extend above the second side 30 of table top 22, opposite rollers 44, 46 (FIGS. 1-3 and 7). Split rail 90 preferably includes a pair of spaced apart rails 92, 94 securely attached to an edge bar 29 by a plurality of supports 96. To remove the bottles from the bag, the operator reaches through the rails 92, 94, grabs the end of the bag opposite the opened end, and manually pulls the bag away from the rollers 44, 46. The opening between the rails is smaller than the height of the bottles so that the bottles are held upon the table top 22 while the bag is pulled between the rails. Once the bag is completely removed, it is discarded. 
     At this point, the bottles 25 have been debagged and are now ready to be transferred to the loading station 14 for feeding into the production stream. Transferring the bottles to the loading station is accomplished through the use of a pusher assembly 20 (FIGS. 1-3 and 7). 
     Pusher assembly 20 includes a pair of side frames 98, pusher bars 101 and a drive construction 103 (FIGS. 1-3 and 7). Side frames 98 are vertically oriented plate members positioned within gaps 27 defined along each side of table top 22. Each side frame 98 includes an upper portion 105 which projects above upper surface 24 and a lower portion 107 which extends below table top 22. Pusher bars 101 are fixedly attached to the upper portion 105 of side frames 98 to extend completely across table top 22. Preferably two bars are used to engage upper and lower portions of the bottles so that a stable pushing arrangement is achieved. Upper portions 105 are generally arcuate in shape so that the pusher bars 101 are spaced forwardly of the sections of the frame members 98 extending through gaps 27. This construction permits all of the bottles to be moved onto loading station 14, as described more fully below. Of course other pushing constructions could be used. Lower portion 107 is operatively coupled to the drive construction 103 for effectively moving the pusher bars 101 back and forth across the table top. 
     Drive construction 103 (FIG. 1) is oriented below table top 22 and includes a pair of guide rods 111 and a central fluid driving system 113 (FIG. 7). More specifically, each guide rod 111 is attached to the underside 114 of table top 22 adjacent sides 28, 30 by a mount 115. A bearing 117 is slidably mounted for reciprocal movement along each of the guide rods 111. Bearings 117 are secured to a bridging plate 119 which extends below table top 22 between the two guide rods 111. Additionally, each end of the bridging plate 119 mounts and supports the upwardly projecting side frames 98 supporting pusher bars 101. Centrally mounted between bridging plate 119 and the underneath surface 114 of table top 22 is the fluid driving system 113. 
     In the most preferred embodiment, driving system 113 is comprised of a rodless fluid cylinder 123 matingly received onto a track 121. As mentioned above, these types of rodless cylinders are generally well known to those having ordinary skill in the control art. Suffice to say, cylinder 123 will be reciprocally moved along track 121 through the use of pressurized air. Of course other types of driving arrangements such as a drive screw could be used. 
     In any event, cylinder 123 is securely attached to bridging plate 119 while track 121 is attached to the underside 114 of table top 22. Hence, as cylinder 123 is moved along track 121 by the pressurized air, bridging plate 119 moves therewith along guide rods 111. Similarly, side frames 98 are moved along with bridging plate 119 to cause the desired movement of pusher bars 101. 
     In operation, pusher bars 101 are positioned along the rearward end 34 of table top 22 in their rest position. In this orientation, the operator places the bagged lots of bottles onto the table top 22 and removes the bag therefrom as described above. Once the bag is completely removed, the pusher assembly 20 is activated by the operator such that it moves toward the forward end 32 of table top 22. This movement causes pusher bars 101 to engage the line of bottles positioned adjacent rearward end 34 and push the entire array of bottles in mass across the table 16 in the direction indicated by arrow A. The bottles are laterally contained during the pushing operation by split rail 90 and sensor bar 71. The forward orientation of pusher bars 101, as compared to lower portion 107 of side frames 98, ensures that all of the bottles will be completely received onto the loading station 14 despite the fact that gaps 27 stop short thereof. Once the drive construction 103 has driven the pusher bars all the way across the table to push the bottles 25 onto loading table 109 the pressurized air is reversed to return the side frames 98 and pusher bars 101 to their rest position at the rearward end 34 of table top 22. 
     Loading station 14 includes an elongated loading table 109, a pusher device 125, a loading sensor 127, and a take-off conveyor 129 (FIGS. 1 and 2). Loading station 14 is adapted to receive groups of bottles 25 from debagging station 12 and feed them seriatim onto the feed conveyor 131 for use in the production stream. 
     In particular, loading table 109 includes an elongated table top forming a feed bed 133 and a plurality of upstanding legs 135. Feed bed 133 defines first and second sides 137, 139 and forward and rearward ends 141, 143. Also, as with table top 22 of debagging table 16, feed bed 133 includes a main body 133&#39; and a pair of outside edge bars 134. Edge bars 134 extend along the entire length of sides 137&#39;, 139&#39; of body 138&#39; in a spaced apart relation to form a pair of elongated gaps 136. Each edge bar 134 is secured in place by passing conventional fasteners (not shown) through edge bars 134 and spacer blocks 138. 
     In the preferred embodiment, forward end 32 of debagging table 16 abuts contiguously against a portion of the first side 137 of loading table 109. The upper surface 140 of feed bed 133 is generally coplanar with upper surface 24 of table top 22, so that the bottles 25 are moved smoothly from table 16 to table 109. Rails 147, 149 are positioned along the length of second side 139 and the portion of first side 137 not abutted by table 16, to contain the bottles and keep them from falling from the feed bed 133. 
     Pusher device 125 is essentially the same construction as pusher assembly 20 for debagging station 12. More specifically, pusher device 125 includes a pair of side frames 98&#39;, pusher bars 101&#39; extending across the width of loading table 109, and a driving system 113&#39;. Likewise the driving system 113&#39; is comprised of a pair of guide bars 111&#39; extending along the entire length and underneath feed bed 133, a bridging plate 119&#39;, a rodless fluid cylinder 123&#39;, and a central track 121&#39;. In the most preferred embodiment, the rodless cylinder 123&#39; for loading station 14 is preferably of the type including a brake means, so that the incremental movement of the bottles to be described below can be more accurately controlled. 
     Loading sensor 127 (FIGS. 1-2 and 8-10) is positioned at the forward end 141 of loading table 109. Loading sensor 127 senses when the bottles need to be moved forwardly by pusher member 125, and when the forward row of bottles are properly positioned on take-off conveyor 129 for feeding into the production stream. 
     Loading sensor 127 (FIGS. 8-10) includes an L-shaped bracket 151 having a horizontal mounting leg 153 and a vertical mounting leg 155. Mounting leg 155 is preferably fixed to a pair of upstanding supports 157 which also support crossbar 159 to act as a forward barrier at the forward end 141 of loading table 109. 
     A pair of spaced apart bearing blocks 161 are fixedly mounted along the upper surface of supporting leg 153. Each bearing block 161 defines a central aperture 163 through which a rod 165 is reciprocally supported. Each rod 165 is oriented in a substantially parallel relationship to loading table 109. The first ends 167 of rods 165 face toward pusher member 125 and are interconnected by a sensor bar 169. Sensor bar 169 extends across substantially the entire width of loading table 109, and is positioned on the feed bed side of supports 157. As will be discussed below, sensor bar 169 is engaged by the bottles 25 to sense their various movements. The second ends 171 of rods 165 are interconnected by a biasing bar 173. Biasing bar 173 couples rods 165 to a biasing means 175 which urges the sensor bar 169 out over take-off conveyor 129. 
     Biasing means 175, in the preferred embodiment, includes a pair of spaced apart braces 177 which project outwardly from supporting leg 153 in a direction away from loading table 109. A pivot pin 179 is secured between the distal ends of braces 177 for the pivotal mounting of biasing member 181. Biasing member 181 includes a bearing sleeve 183 rotatably received over pivot pin 179, an arcuate finger 185, and a biasing weight 187. Finger 185 extends upwardly from sleeve 183 and is adapted to engage the biasing bar 173 with its free end 189. The biasing weight 187 extends oppositely from sleeve 183 at such an angle that finger 185 is urged to move clockwise (as shown in FIG. 8). The biasing weight 187 preferably includes a slender rod 190 and an adjustable weighted knob 192 which is secured to the rod through the use of a set screw or the like. Adjustment of knob 192 permits the operator to adjust the biasing force provided by the biasing means 175. 
     In use, the biasing weight 187 urges finger 185 clockwise (as seen in FIG. 8) so that its free end 189 pushes against biasing bar 173. The force of finger 185 on biasing bar 173 moves rods 165 through bearing blocks 161 so that sensor bar 169 is extended over the take-off conveyor 129. Preferably stops 194 are adjustably mounted on rods 165 to abut the ends of bearing blocks 161 and set the position of sensor bar 169 in its rest position. 
     Loading sensor 127 further includes a sensor element 196 and a complimentary sensing plate 198 (FIGS. 8 and 10). Sensing plate 198 is an L-shaped member having one arm 202 attached to the inside surface of sensor bar 169 and a projecting arm 204 projecting outwardly toward biasing bar 173. Sensor element 196 is preferably an optical sensor which is adapted to sense when arm 204 crosses in front of it. More specifically, when sensor bar 169 is not engaged with any bottles 25, and is biased outwardly by biasing weight 187, sensing arm 204 is positioned to the side of the optical sensor 196. However, when a row of bottles 25 engages sensor bar 169, it is moved backwardly against the force of biasing weight 187, until the bottles are completely placed upon take-off conveyor 129. In this position, arm 204 is juxtaposed to optical sensor 196 so that the sensor registers its presence. As will be discussed below, the sensing or not sensing of the arm 204 by optical sensor 196 controls the incremental advancement of the bottles 25. 
     Also at the forward end 141 of loading table 109 is the take-off conveyor 129 (FIGS. 1-2 and 11). Take-off conveyor 129 is positioned parallel to the feed conveyor 131 of the production stream and is designed to remove a row bottles at a time onto the feed conveyor. More specifically, take-off conveyor 129 (FIG. 11) includes an endless belt 206 upon which are mounted a plurality of take-off paddles 208. As is conventional, belt 206 is wrapped about a pair of spaced apart pulleys 210, 212 mounted upon axles 214, 216. Axle 214 further includes a sprocket 218 which is coupled to a drive sprocket 220 secured to the drive shaft 222 of a conventional air motor 224. Pulley 212 is an idler pulley which is adjustable through a conventional adjustment mechanism 226 to permit replacement of the belt and account for any slack which may develop therein. 
     Take-off conveyor 129 is not a continuously running conveyor, but rather is periodically actuated by loading sensor 127. In particular, when sensor bar 169 is pushed backwardly so that arm 204 is juxtaposed to optical sensor 196, take-off conveyor 129 is activated to move the row of bottles positioned thereon laterally from the loading table 109 and onto the feed conveyor 131. 
     Preferably, take-off conveyor 129 and feed conveyor 131 are arranged in a parallel relationship and in close proximity to one another (FIGS. 1 and 2). As the bottles are moved laterally off loading table 109 they engage an arcuate, generally S-shaped split guiding rail 228 which forces the bottles to move laterally relative to take-off conveyor 129 and onto feed conveyor 131 where it is moved into the production stream. Take-off paddles 208 are provided so that the bottles will positively move onto the feed conveyor and not begin to bunch when they engage guiding rail 228. Moreover, the guiding rail is positioned sufficiently high off the take-off conveyor 129 so that the paddles 208 can pass therebeneath. The paddles are positioned so that one is adapted to engage the end bottle on the next row to be taken off each time it is activated. 
     In the complete operation of the apparatus 10, an operator first manually takes a bagged lot 23 of bottles 25 and placed it on the upper surface 24 of debagging table 16, so that the sealed flap 40 of bag 42 is positioned adjacent the continuously rotating rollers 44, 46. The bristled rollers 44, 46 engage the flap 40 and direct it into the gap 54 defined therebetween. Once the flap has passed through the gap, the bag and bottles are pulled toward the rollers until the front row of bottles 25a engage the sensor bar 71 of debagging sensor 65. Sensor bar 71 stops the bottles once they are fully on take-off conveyor 129, which causes the end portion 42a of the bag to be stretched taut between rollers 44, 46 and the bottles 25a. Additionally, once sensor bar 71 has stopped the bottles, debagging sensor 65 signals the hot wire cutter 78 to pass laterally across the bag so that the bag is easily sliced open. 
     After the bag is opened, the operator then manually reaches through the split rail 90 and easily pulls the bag from the bottles. Once the bag has been removed, the operator manually activates pusher member 20 to push the group of bottles in mass, in the direction indicated by arrow A, from debagging table 16 to the loading table 109. Activation of pusher assembly 20 also moves pusher device 125 of loading station 14 to its rearward position adjacent end 143 to receive the newly opened bottles. Once all the bottles are pushed onto loading table 109, pusher assembly 20 returns to its rest position. 
     At this point loading sensor 127 is not engaged by any bottles, and therefore signals that the bottles should be advanced in the direction indicated by letter B. Pusher device 125 is activated to push the bottles in mass forwardly toward loading sensor 127 until the first row of bottles 25a engage and move sensor bar 196 until optical sensor 196 senses the juxtaposition of arm 204. 
     Loading sensor 127, then, stops the advance of the pusher device 125 and activates take-off conveyor 129 to remove the first row of bottles 25a. Once the last bottle and paddle have cleared the end of sensor bar 196, biasing weight 187 forces the sensing bar 169, through finger 185 and rods 165, outwardly again toward pusher device 125. This movement of sensor bar 169 moves the sensing arm 204 to the side of the optical sensor 196 which thereby activates, once again, the pusher device. Device 125 moves the bottles forwardly again, until the next forward row of bottles engages sensor bar 169 and activates the optical sensor as described above. In this way, nearly any size of bottle may be effectively and efficiently debagged and fed into the production stream through a minimum use of manual labor. In fact, the entire debagging and loading operation can be easily performed by a single operator. 
     The above description is that of a preferred embodiment of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention as set forth in the appended claims, which are to be interpreted in accordance with the principles of patent law including the Doctrine of Equivalents.