FI92671B - Modified opening bag for plastic bags - Google Patents

Abstract

An apparatus for opening plastic bags to remove their contents has a pair of wheels (11,12) mounted in approximate coplanar relationship such that there is a point of approximate cotangency. The two wheels rotate in opposite directions, and a series of tines 13 are mounted in spaced relation on the periphery of each wheel to extend normal to the direction of travel of the loop. Once a filled plastic bag is placed onto the apparatus at the point of approximate cotangency of the wheels, a biased flexing structure presses the bag against the tines. A hole is created in that surface riding on the tines as the tines move away from the point of approximate cotangency. To remove any articles remaining in an opened bag, a pair of oppositely-rotating rollers (63,68) are positioned so as to draw the bag between them. An oscillating member forward of the rollers acts to prevent any articles remaining in an opened bag from entering between the rollers. A vacuum collection means 73 draws off the emptied bags. The apparatus has particular application to the opening of bags containing recyclable articles. <IMAGE>

Description

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The present invention relates to a device for opening plastic bags and, more particularly, to a device for the controlled opening of plastic waste bags filled with goods for reuse.

Concern for the environment has led to the collection of used glass bottles, cans, paper and other types of goods for reuse. Often, such goods are collected and stored in plastic garbage bags for practical reasons. Thereafter, means are needed to quickly open a large number of such bags because manual opening is a slow and labor-intensive operation.

Different types of mechanical systems have been proposed for opening filled bags and emptying their contents. One such system is disclosed in U.S. Patent 4,798,508, issued to Dow Chemical Company on July 17, 1989, entitled "Machine and Method for Opening a Filled Bag, Emptying the Bag, and Disposing of the Empty Bag." In this case, the sack is guided into the space between the two rotating drums. A series of spikes extending radially from each drum and protrude through a belt running around the drum. When the sack enters the space between the drums, the tines penetrate it and pull it with it to the cutting device. The cutting device cuts the sack in half to empty the contents and the spikes of each drum take one half of the emptied sack with them to the point where the spikes move off the belt each; to remove the bag half.

Because glass bottles and other similar fragile bodies are desired to be kept intact during the opening of waste bags during the reuse process, it is not practical to use a system of the type disclosed in U.S. Patent No. 4,798,508 to open the bags. What is needed instead is means to open the side of the filled plastic bag and to turn the bag so that its contents fall out through the opened side. The device of the invention is a device for opening plastic bags, which is able to quickly open and empty the plastic bag while keeping the individual pieces inside the bag intact. The invention is defined in the appended claims.

The device according to the invention is provided with a pair of wheels, one of which moves in the first plane of rotation and the other in the second plane of rotation. One wheel is adapted to rotate clockwise and the other wheel is adapted to rotate counterclockwise. Each wheel rotates at approximately the same angular speed and is oriented so that the first and second planes are approximately coplanar and have at least one proximal location where the two wheels are tangentially spaced apart. The device is also provided with a set of spikes, which are spaced apart along the circumference of each wheel so as to extend from the same side of the plane of rotation of each wheel and in a direction substantially perpendicular to this spin. The device is further provided with means for pressing the sack onto the spikes moving past a nearby location so that these spikes protrude through the first surface of the sack. The effect of the subsequent spacing of the spikes on the two wheels as the wheels move away from a nearby location causes tear lines on the first surface of the bag. The device is also equipped with vibrating strainer means and vacuum collecting means located in the vicinity of the circumference of each wheel. The tangential spacing of the wheels and the spacing of adjacent spikes on the same wheel are such that as the spikes of the two wheels move away from a proximal position, the tear lines formed on the first surface of the bag are sufficiently close to each other to form a single continuous opening on that surface. All or most of the contents of the sack are adapted to fall through this opening. By means of a combined tensioning and 3 92671 vibrating effect, the vibrating tensioning means are adapted to empty any remaining contents from the bag. The vacuum collecting means are adapted to recover the emptied bag. At least a portion of the vacuum collecting means may be positioned so as to be in close proximity to and downstream of the oscillating tensioning means with respect to the direction of rotation of each wheel.

The oscillating tensioning means may comprise a pair of rollers, each roller mounted so that the axis of rotation of each roller is parallel to the other roller and is substantially horizontal. The two rollers are adapted to rotate in opposite directions and are spaced apart so that their cylindrical surfaces are in contact with each other along the traction line. The draw line is positioned so that the sack attached to the spike passing past one end of the rollers is pulled onto the draw line. The oscillating tensioning means are also provided with an oscillating member extending in front of the pair of rollers and provided with first and second parts. The first part defines one edge of the oscillating gap in the obstacle in front of the draw line; sacks falling into the area of the draw line will be pulled through this gap. The second part defines an oscillating guide member which moves against the sack entering the slot and assists in preventing any pieces in the sack from penetrating the slot.

There may be a fixed ring in the vicinity of the circumference of each wheel. The diameter of each tire is slightly larger than the diameter of the circle formed by the spikes of each wheel. The spikes of each wheel move inside and near the corresponding tire. Each ring is mounted on the device such that the upper edge of the portion of the ring extending adjacent the tensioning means extends in the immediate vicinity of the upper end of the spikes passing past the tensioning means.

4,92671 The bag pressing means may comprise a tensioned flexible multi-hinge structure, wherein one loop is provided with plate means adapted to press against the bag. The resilient structure may consist of four loops arranged mainly in a box-like manner in series. The outer end of each outer loop is hinged to the body of the device. The resilient structure is normally supported by the body of the device in the rest position and the spring device returns it to this rest position after movement. With this system, the initial contact between the bag and the disk device moves the resilient device from the rest position. The spring device then presses the sack against the spikes of the wheels at a nearby location and then returns the spring device to the rest position.

The vacuum collecting means may be provided with a second part located downstream of the first part with respect to the direction of rotation of the wheel corresponding to it. The second part of the vacuum collecting means comprises two fixed vertical pipe sections, one of which is located above the path formed by the spikes and the other below this path in a fixed position. Air is forced out of the lower tube section and sucked into the upper tube section at the same flow rate to develop an upward air column across the spikes moving past the fixed position.

The invention will now be described in more detail on the basis of two preferred embodiments, with reference to the accompanying drawing, in which:

Figure 1 shows a partially sectioned opening of plastic bags! t make the first suitable embodiment seen from above.

Figure 2 is a front sectional view of a first suitable embodiment.

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Figure 3 is a sectional side view of a first suitable embodiment.

Figure 4A is a perspective view of a first suitable embodiment.

Fig. 4B corresponds to a perspective view of Fig. 4A, but further illustrates a series of possible positions of a plastic bag attached to the spike of one wheel of the device.

Figure 5 shows a side view of a type of spike that can be used in a first suitable embodiment.

Figure 6 shows an end view of the spike of Figure 5.

Figure 7 shows a top view of another suitable embodiment of the plastic bag opening device.

Figure 8 is a side view of another suitable embodiment.

Fig. 9 shows a cross-section of the chain of the second embodiment and the spike attached thereto along the line IX-IX in Fig. 7.

Figure 10 is a perspective view of a first suitable embodiment of a sack opening device for an alternative tensioning means.

Figure 11 is a perspective view of an alternative suction mechanism for a first suitable embodiment to remove bag residues.

Figure 12 is a perspective view of an alternative sack feeder 6 92671 for a first suitable embodiment.

Fig. 13 is a side view of an apparatus included in the alternative sack feeding system of Fig. 12 for pressing filled sacks against spikes.

Fig. 14 is a cross-sectional end view of the device of Fig. 13 taken along line XIV-XIV of Fig. 13.

Figure 15 is a perspective view of a first suitable embodiment provided with the alternative structural systems of Figures 10-14.

Referring to Figures 1.. . 4A to the first embodiment, it has two identical wheels 11 and 12 arranged in the same horizontal plane. Each of the wheels 11 and 12 is provided with a series of spikes 13 supported at regular intervals along its circumference. Each spike 13 is attached to the outer end of a respective horizontal arm 14, with the inner end of each arm 14 being attached to the circumference of the wheel. The distance between the axes of rotation of the wheels 11 and 12 is such that at a location, generally indicated by reference numeral 15 in Figure 1, the path of the spikes of the wheel 11 runs close to the path of the spikes of the wheel 12. An electric motor (not shown) is connected to the input shaft 15 of the first gear 17 and via the belt 18 to the second gear 19. A pulley 20 is mounted on the drive shaft of the gear 17 to drive the belt 21, which also extends around the pulley 22 fixed to the wheel 11 so as to rotate together with this bike. The wheel 12 has been removed from Figure 1 to better illustrate a corresponding drive system for this wheel, as well as to illustrate the lower body 23 of the device above which the wheels 11 and 12 rotate. The system shown causes the wheel 11 to rotate clockwise and the wheel 12 counterclockwise at corresponding angular velocities, whereby the sets of wheel chips 13 move away from each other after passing point 15.

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Each of the spikes 13 is attached to the circumference of either wheel 11 or 12 so as to be vertical. However, they may be inclined in the direction in which the perimeter moves. Fig. 5 is a side view of a spike 13 attached to the circumference 28 of one of the wheels 11 and 12 so as to extend at an angle of about 75 degrees to the plane of rotation of that particular wheel; although the magnitude of this angle is not critical, all spikes should still be installed at the same angle. The tip 29 at the end of the spike 13 is actually a horizontal edge 30, as can be better seen from the end view of Figure 6. As also shown in Figure 6, each spike may also be inclined radially so that its outer end extends towards the center of that wheel.

The downcomer 33 is attached to the body of the sack opening device at such an angle that its lower end terminates in the vicinity of point 15. The upper end of the downcomer 33 may be located below the end of the conveyor belt (not shown). The angle of the downcomer 33 is steep enough for the plastic bag filled with the goods to slide freely down the downcomer 33 onto the set of double spikes moving past the point 15. The two toothed wheels 35 are mounted so as to rotate freely at a distance from each other on a shaft 36, each end of this shaft being fixed to the other end of two identical beams 37. The wheels 35 are typically spaced about 20 cm (8 ") apart. The other end of each beam 37 is articulated to a shaft 38 attached to the body of the bag opening device.

As shown in Figs. 2 and 3, the wheel 12 is supported by a first bearing 40 so as to rotate about a fixed shaft 41 extending from the upper surface of the lower body 23 of the device; the wheel 11 is supported in a corresponding manner. The shaft 41 has a fold slightly above the bearing 40 towards the point 15. Above this fold point, a second bearing 43 located on the shaft 41 supports a truncated cone-shaped plate 45. A pin 46 mounted on the upper surface of the wheel 12 extends into an opening in the lower surface 48 of the plate 45. Thanks to the pin 46, the wheel 12 and the plate 45a 92671 can rotate together in angularly shifted planes of rotation. A similar type of plate 49 rotates together with the wheel 11. The purpose of the plates 45 and 49 is to place a waste bag moving past the point 15 on a series of two spikes 13; the sack rests on the truncated cone-shaped edges of the two plates and the annular protrusion 50 on each plate.

A portion of the lower body 23 defines a sloping ramp 52 which forms an angle of about 25 degrees with the horizontal. The upper end of the ramp 52 protrudes below the portion of the wheels 11 and 12, as shown in Figures 1 to 4B, and the lower end of the ramp 52 contacts the conveyor belt device 53.

As best seen in Figures 4A and 4B, the tensioning means, generally indicated at 60, is located in the vicinity of the circumference of the wheel 12; an identical means is placed in the vicinity of the circumference of the wheel 11. The means 60 consists of a motor 62 which drives a first vertical shaft 63 via a gear 64. The gear 64 is supported by a vertical support 65 attached to the ramp 52 via a lower support 66 connected. The lower part of the first shaft 63 is provided with gear teeth extending vertically parallel to the axis of symmetry of this shaft. The second shaft 68, which is rotatably supported on the lower support 66, extends parallel to the shaft 63 and has a complementary set of teeth in contact with the teeth of the shaft 63. Due to the teeth in contact with the shafts 63 and 68, the forward movement of the shaft 63 to the clock causes the shaft 68 to rotate to the counter-clock. The teeth of the shafts 63 and 68 are each located in their respective housings 70 and 71, the distance between the two housings defining two narrow vertical slots. In connection with the tensioning assembly 60, there is a suction tube 73, shown in Figures 1 and 2 and outlined in Figures 3, 4A and 4B. The suction tube 73 extends in an inclined position, its other end being located in the immediate vicinity of the outer gap of the vertical slots between the housing 70 and the housing 71.

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The two lower handlebars 75 and 76 extend in the vicinity of the track of the spikes 13 from the ramp 52 to the top of the housing 71, with the lower end of the handlebars 75 attached to the ramp 52 at a point closer to the wheel 12 than the lower end of the handlebars 76. The upper handlebar 78 extends upwardly from an attachment point in the housing 70 to an attachment point (not shown) in the body of the sack opening device.

The cam rod 80 extends in the vicinity of the track of the spikes 13 from a point between point 15 and the tensioning assembly 60. One end of the cam rod 80 is attached to the ramp 52 and the other end of this cam rod is attached to the top of a vertical support 81 attached at its lower end to the ramp 52. As shown in Figures 4A and 4B, the vertical plate 82 is supported by the vertical support 83 from the bag opening device body. The plate 82 is substantially rectangular and is mounted so that its lower surface is located slightly above the annular protrusion 50.

The two rods 85 extend downwards at an angle from the body of the sack opening device so that their lower ends are spaced apart from the spikes 13. The top view of Figure 1 shows the position in which the rods 85 are positioned with respect to the device assembly.

e

The first embodiment of the device operates as follows. When wheels 11 and 12 rotate together at an angular speed of 3.. . At 10 rpm (preferably about 8 rpm), the filled plastic bag is dropped down the downcomer 33. The two toothed wheels 35 rotate as the plastic bag slides beneath them and end up resting on the bag as the bag moves to two sets of spikes 13 at 15. The wheels 35 press the plastic bag more firmly over the spikes 13 due to their weight and the wheels 35 also help the bag to position the spikes. Although the bag opening device has been found to function satisfactorily without wheels 35, their presence is still effective. As two sets of 10,92671 spikes 13 are spaced apart, the horizontal edge 30 of each spike bites the surface of the sack resting on that edge. In operation, each wheel 11 and 12 has a diameter of about 180 cm (about 6 feet), the successive spikes 13 attached to the circumference of each wheel have a length of about 10 cm (about 4 ") and are located about 10 cm (about 4"). ) and the two wheels 11 and 12 are spaced such that the spikes 13 of the respective wheel at point 15 are about 10 cm (about 4 ") apart. In this construction, it has been found that the spikes on the surface of the sack are spaced apart. the distance between the spikes 13 of the two wheels at location 15 has been found to be an important parameter for the efficient operation of the device.If this distance is too small the sack rests on the spikes and does not become properly pierced, if this distance is too the large tear lines created on the sack surface are not located close enough to each other to a The areas connecting these lines could tear to form a single hole in this surface.

During the formation of the hole, the upper surface of the sack comes into contact with the two rods 85 of the sack. The movement of the upper part of the sack is slowed down while the lower part continues its movement supported by the spikes, whereby the sack turns so that its opened • lower surface moves in front of the upper part of the sack. The rods 85 are placed high enough above the spikes 13 to allow this sack to turn. Most of the goods 86 for reuse in the opened bag fall through the opened lower surface of the bag onto the ramp 52 and then slide onto the conveyor belt assembly 53 which transports them to the sorting station. The pieces on the wheel projections 50 come into contact with the respective plates 82 above these projections, whereby these plates 82 push such pieces onto the ramp 52. Hard objects, such as canisters, sometimes wedge onto the spikes 13. The cam bar 80 pushes such pieces away from the spikes.

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Although most of the pieces in each bag are removed by the method described above, a few pieces are usually left in the corners of the bag. The tensioning means 60 and the handlebars associated with this means are used to assemble these pieces. One or more of the spikes 13 pulls the opened plastic bag 87 across the lower guide rods 75 and 76, and then between these lower guide rods and the upper guide rod 78. The sack then moves into the vertical gap between the housings 70 and 71 and into the path of the two interconnected teeth of the shafts 63 and 68. As soon as the interconnected teeth have a grip on the sack, these teeth begin to pull the sack across their contacting surfaces. Any pieces left in the bag are too large to protrude into the vertical gap between the housings 70 and 71 and such pieces are pushed through the bag and onto the ramp 52. As the remnants of the bag 87 move out the other side of the tensioning means 60, the suction tube 73 collects these remnants and feeds them (not shown).

Figures 7, 8 and 9 show another embodiment of the sack opening device of the invention. In this embodiment, each of the two chains 90 and 91 extends along a path partially defined by a guide track, indicated by reference numerals 92 and 93, respectively. Each guide track 92 and 93 comprises an upper track portion and a lower track portion, as shown in Fig. 9. The principle of operation of the chute 95 corresponds to the principle of operation of the chute 33 of the first embodiment, and the principle of operation of the two toothed wheels 96 corresponds to the principle of operation of the two wheels 35 of the first embodiment. The chain 90 rotates around the sprocket 97 and the sprocket 98, and the chain 91 rotates around the sprocket 99 and the sprocket 100. A plurality of spikes 102 are mounted on the chains 90 and 91. Unlike the first embodiment, each spike 102 is vertical and has a pointed top. In order to stabilize the travel of the spikes 102 along the guide tracks 92 and 93, each spike is provided with two support wheels 103, the axis of rotation of each wheel 103 being in line with the longitudinal axis of the spike. One wheel 103 of each pair of support wheels runs along the upper track portion of either guide track 92 or 93, and the other wheel 103 runs along the lower track portion. A vertical suction tube 104 is positioned midway between the centers of the sprockets 98 and 100, with the lower end of this tube terminating slightly above the plane passing through the upper ends of the spikes 102. The conveyor system, generally designated 105, extends below the area between the guide tracks 92 and 93 to collect goods that fall from the sacks held by spikes moving along these tracks.

The second embodiment of the device operates in a manner similar to the device of the first embodiment. The filled waste bag is placed on the downcomer 95 and slides over the spikes 102 moving past the location 107. The two sets of spikes 102 then extend away from each other along straight lines and create a hole in the adjacent surface of the sack. Thereafter, the two sets of spikes 102 travel a short distance along parallel paths while the emptied sack remains firmly in place between them. Next, the two sets of spikes 102 approach each other as each of them rotates around one of the respective sprockets 98 and 100, releasing the grip of the spikes 102 from the emptied bag. The bag then passes under a suction tube 104 which pulls the empty bag out of the spikes and removes it into a waste container (not shown).

Figures 10 to 14 show some alternative structural arrangements that may be used in connection with the first embodiment of the device, and Figure 15 shows the first embodiment provided with these alternative arrangements.

Figure 10 shows an alternative tensioning means for a first suitable embodiment. External manual. a motor 120 which drives a helical gear 121 with a helical gear 121. The helix of the gear 121 is mounted on a bearing located in the body portion 122 of the bag opener and is connected to the horizontal axis 123 of the first roll indicated by reference numeral 124. The first roll 124 consists of a steel cylinder and a surrounding soft urethane cylindrical ring 2 having a thickness of about 5 cm (approx. 1 "). The horizontal shaft 127 of the second roller, generally indicated by reference numeral 12Θ, is mounted on a bearing in the body 122. The second roller 128 consists of a steel cylinder corresponding to the first roller 124 and a cylindrical ring 129 of soft urethane having a thickness of is about 2.5 cm (about 1 "). The horizontal shafts 123 and 127 are mounted on the body portion 122 at a distance from each other such that the ring 125 is continuously pressed against the ring 129; this contact causes the roller 128 to rotate at the same angular speed as the roller 124, but in the opposite direction.

The alternative tensioning means further comprises a cam plate 132 mounted on the shaft 127 such that the working surface of the plate 132 is close to the ring 125. The eccentricity of the plate 132 is such that its largest radius is about 0.32 cm (about 0.125 ") larger than its smallest radius. , whereby the largest radius of the plate 132 is rotated 180 degrees with respect to the smallest radius.The bearings of the body member 134 of the sack opening device are mounted on a pivot shaft 135 to which two rods 136 are attached.Rods 136 extending above the second roller 128 are fixedly connected to the curved plate 137. which forms the upper edge of the horizontal slot 138, which slot is at the same height as the contact line of the rings 125 and 129. A metal plate 140 attached to the body of the sack opening device forms the lower edge of the slot 138. A freewheeling camshaft 142 is attached to one rod 136. 142 is positioned to rotate along the cam plate 132 .

During the rotational movement of the shaft 127 and the cam plate 132, the cam wheel 142 and the plate 137 move back and forth vertically.

. The rotational movement of the cam plate 132 causes the distance between the top and bottom of the slot 138 14 92671 to vary between a minimum value of about 0.64 cm (about 1/4 ") and a maximum value of about 0.95 cm (n. 3/8 "). The alternative tensioning means is mounted on the body of the sack opening device so that the horizontal slot 138 is at almost the same height as the trajectory formed by the upper ends of the spikes 13 and so that one end of the slot 138 and the other end of the rollers 124 and 128 are in the vicinity of this same trajectory. Attached to the plate 137 is a wedge-shaped plate 144 which remains a small distance from the top of the spikes 13 in all the vertical positions of the plate 137. Extending between the plates 137 and 144 are two support members 145 to maintain their relative position relative to each other.

A plastic bag attached to one of the spikes 13 is pulled through the slot 138, after which the rings 125 and 129 adhere almost immediately to it. The proximity of the plates 144 and the tips of the spikes 13 prevents any trapped pieces from moving over these spikes. The plate 144 also acts as a barrier, preventing the pieces in the sacks from being thrown up against the plate 137 and thus preventing pieces such as glass bottles from breaking. The bottom surface of the plate 144 extends in a plane just slightly above the slot 138, and contact of the plate 144 with the bagged pieces directs these pieces so that their path does not extend directly into the slot 138. The small size of the gap 138 acts as a barrier to the reusable pieces in the bag. for tires 125 and 129 the possibility of railing the sack off these tracks. Occasionally, a flattened can or similar thin piece wedges into the slot 138; in this case, it has been found that the reciprocating movement of the gap 138 removes such wedged bodies.

Figure 11 shows an alternative suction mechanism for removing bag residues from the bag opening device. An alternative suction mechanism comprises a primary suction tube device, generally designated 150, and a secondary suction device, generally designated 151.

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The primary device 150 comprises a rectangular tube 153 having a cross-sectional area of about 130 cm 2 (about 20 square inches) located in the bag opening device immediately downstream of the tensioning means. A rectangular slit is cut in one surface of the tube 153, and the tube is oriented so that the path of the spikes 13 passes through this slit. A secondary exhaust pipe device 151 is located on the track of the spikes 13 about 120 cm (about 4 feet) downstream of the pipe 153. This secondary device comprises two circular pipes 155 and 156, each having a cross-sectional area of about 130 cm 2 (about 20 square inches). The tube 155 is positioned so as to extend vertically so that its lower open end is located just above the upper ends of the spikes 13, and the tube 156 is positioned so as to extend vertically so that its upper open end is located just below the lower ends of the spikes 13. As shown in Figure 11, the supply tubes 153 and 155 are fed to a common suction tube 157 which opens into a bag residue collection tank 158. On top of the tank 158 is a fan 159 which develops both the suction effect of the tube 157 and the corresponding outward air flow through the tube 156. The resulting strong air flow between tubes 156 and 155 is sufficient to pull any remaining plastic residue off the spikes 13.

Figures 12, 13 and 14 show an alternative sack feeding system. The filled sacks are generally placed in a trough, indicated at 160, having a horizontal base 161 connected to two inclined side members 162. A plurality of pushers 165 are connected through a longitudinal slot 164 in the base 161 and connected to an endless chain used. The first end of the trough 160 terminates in the vicinity of its previously discussed point 15, where two sets of spikes 13 are located closest to each other. The sack pressing device, generally indicated at 170, is mounted on the body of the sack opening device above point 15. The device 170 shown in side in Figure 13 comprises four articulated rods 171, 172, 173 and 174, as well as. two ramp members 175 and 176, which will be dealt with .β 92671 in the following. One end of the rod 171 is hinged at 180 to the body of the sack opening device. In its rest position, the rod 171 extends downwards at one end at an angle of about 60 degrees to the horizontal. The other end of the rod 171 is articulated to the other end of the rod 172. In its rest position, the rod 172 has a first portion extending from one end thereof at an angle of about 20 degrees to the horizontal and a second portion of the same piece extending upwardly from the first portion at an angle of about 40 degrees to the horizontal. The other end of the rod 172 is rotatably connected to the other end of a short rod 173 extending upward at an angle of about 50 degrees to the horizontal. The other end of the rod 173 is articulated to the other end of the rod 174, which in its rest position is in a substantially horizontal position. The other end of the rod 174 is hinged at 181 to the body of the sack opening device; the frame is also provided with a support bar 183 which holds the bar 174 in its horizontal rest position by supporting it from below. The dimensions "a", 11b ", 11c", "d" and "e" shown in Fig. 13 are respectively about 33 cm (13 "), 46 cm (18"), 56 cm (22 "), 23 cm (9 ") and 66 cm (26"), respectively. As also shown in Figure 13, two strong springs 184 extend successively from the frame support rod 183 to the rod 171; these springs are subjected to only a small load when the sack press 170 is in its rest position shown in Figure 13.

The inner ramp member 175 attached to the second portion of the rod 172 is a plate 185 having two edge flanges 186. Each edge flange 186 terminates along one edge of the plate 185 which edges are parallel to the rod 172. The outer ramp member 176, which is articulated to the rod 172 by two lugs 187, consists of two plates 188, each of which supports an edge flange 189, which plates are connected by a U-shaped member 190. Also extending from each plate 188 is a ridge-like element 191 parallel to the edge flanges 189. In the rest position of the outer ramp member 176, the plates: 188 rest on the plate 185 of the inner ramp member 175. The size of the inner ramp member 175 is selected to press against sacks smaller than the sacks against which the outer ramp member 176 is to be pressed.

The alternative sack feeding system of Figures 12, 13 and 14 operates as follows. After the series of filled sacks is placed in the trough 160, the pushing members 165 sacks the sacks towards the first end of the trough 160. The spikes 13 of the wheels 11 and 12 grip the first sack and force it against the sack pressing device 170. The large sacks come into contact with the edge flanges 189 and the brush-like elements 191 of the outer ramp member 176, whereby this member rotates upwards while maintaining a guiding contact. The small tabs initially come into contact with the edge flanges 186 of the inner ramp member 175. As the sack begins to press against the edge flanges 186, the rods 171, 172 and 173 move to the left in Figure 13 and extend the springs 184. Thereafter, the rods 172, 173 and 174 begin to move upward as the spikes 13 engage the sack at location 15 and pull it further under the sack press 170. When the inner ramp member 175 (and also the outer ramp member 176 in the case of a large sack) presses down against the sack, these two sets of spikes 13 tear the sack open. Thereafter, the sack pressing device 170 returns to its rest position at just the right moment to begin its handling operation on the next filled sack.

Figure 15 shows the relative position of each of the alternative structural arrangements of Figures 10 to 14 in the first embodiment. This figure also shows some small further variations of the first embodiment. The guide rods 75, 76 and 78 in Figure 4A have been removed, as have the cam rod 80 and the vertical support 81. Figure 15 shows the addition of two fixed steel rings 195, each ring resting outside the spikes 13 of the respective wheels 11 and 12 in their vicinity. Each ring 195 remains in place so that its lower edge is welded to the upper edge of a fixed 18 92671 curved steel curtain 196, which in turn is welded to a ramp 52. The ring 195 is oriented so that its upper edge extends past the track formed by the upper ends of the prongs 13 in the vicinity. The heavy rubber mat 197 extends from below point 15 to the ramp 52, with each end of the mat 197 partially extending upward along the lower edge of the respective curtain 196. This system effectively prevents goods falling from opened sacks from getting under the wheels 11 and 12. Another change from the first embodiment of Figure 4A is the replacement of the plate 82 with a heavy rubber flap 198.

By using the alternative constructional arrangements shown in Figures 10 to 15, an improved operating speed of the bag opening device has been achieved.

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Claims (33)

A device for removing the contents of a filled plastic bag, characterized in that the device comprises: (a) two wheels (11, 12), one wheel moving in the first plane of rotation and the other wheel in the second plane of rotation, the second wheel being adapted to rotate clockwise and the second wheel is adapted to rotate counterclockwise, and each wheel rotates at approximately the same angular velocity and is oriented so that the first and second planes are approximately coplanar and have one proximal location (15) where the two wheels (11,12) are located Tangentially spaced; (b) a plurality of spikes (13) spaced apart along the circumference of each wheel (11, 12) so as to extend from the same side of the plane of rotation of each wheel and in a direction substantially perpendicular to that plane of rotation; (c) means (35, 170) for pressing the sack (87) over the spikes (13) moving past the proximal location (15) so that these spikes pass through the first surface of the sack, with the two wheels (11,12) the subsequent spacing of the existing spikes as the spikes move away from a proximal location causes tear lines on the first surface of the bag; (d) vibrating tensioning means (60) located in the vicinity of the circumference of each wheel (11,12); and (e) vacuum collecting means (73) located in the vicinity of the circumference of each wheel (11, 12); wherein the tangential spacing of the wheels (11,12) and the spacing of adjacent spikes (13) on the same wheel are such that when the spikes of the two wheels move away from a proximal location (15) the tear lines formed on the first surface of the sack (87) are close enough to coincide to form a single integral hole in said surface, wherein all or a substantial portion of the contents (86) of the sack (87) are adapted to fall through this 2o 92671 hole, and wherein the oscillating tensioning means (60) is adapted to discharge any remaining sack through the combined tensioning and vibrating action; contents, and wherein the vacuum collecting means (73) is adapted to recover the emptied bag. Device according to claim 1, characterized in that the oscillating tensioning means (60) comprise two rollers (124,128), each mounted so that the axis of rotation of each roller is parallel to the axis of rotation of the other roller and extends generally horizontally, the two rollers being arranged rotate in opposite directions and are spaced apart so that their cylindrical surfaces (125,129) are in contact with each other along a traction line, the traction line being positioned so that the sack (87) attached to the spike (13) moving past the other end of the rollers is drawn on the traction line, wherein the oscillating tensioning means (60) also comprises an oscillating member extending in front of the pair of rollers and provided with first and second portions, the first portion (137) defining one edge of the oscillating slot (138) in the obstacle in front of the traction line, wherein the sacks coming to the draw line are pulled through the gap, and the second portion (140) defining an oscillating guide member,. whose function is to move against the bag entering the slot (138) to prevent the pieces in the bag from entering the slot. Device according to Claim 2, characterized in that the oscillating element (132) and the two rollers (124, 128) are driven by the same drive device. Device according to claim 1, characterized in that at least one part of the vacuum collecting means (73) is arranged so as to be immediately adjacent to the vibrating tensioning means (60) and downstream of these tensioning means with respect to the direction of rotation of said wheel (11, 12). • «92671 21 Device according to claim 2, characterized in that at least one part (150) of the vacuum collecting means (73) is arranged so as to be immediately adjacent to and downstream of a pair of rollers (124, 128) with respect to the direction of rotation of said wheel. Device according to claim 1, characterized in that the fixed ring (195) rests in the vicinity of the circumference of each wheel (11, 12), the diameter of each ring being slightly larger than the diameter of the circle formed by the spikes (13) of each wheel, and the spikes of each wheel moving inside said ring in its immediate vicinity, and the ring (195) is mounted on the device such that the upper edge of the portion of the ring extending in the vicinity of the tensioning means (60) extends in the immediate vicinity of the upper end of the tines (13) moving past the tensioning means. Device according to claim 1, characterized in that the squeezing device (170) for the sacks (87) comprises a tensioned elastic structure consisting of a plurality of articulation devices (171.172.173.174), one of the articulation devices being provided with plate means for pressing against the sack. Device according to claim 7, characterized in that the resilient structure consists of four articulated devices (171.172.173.174) hinged in one series in a substantially box-like configuration, the outer end of each outer joint device being hinged to the device body, the resilient structure being normally supported by the device body in the rest position, and is tensioned by a spring device (184) so as to return to this rest position after movement, whereby the sack initially comes into contact with the plate means and moves the resilient structure out of the rest position, and the spring device then acts to press the pins (13,12) ) at a nearby location (15) and then returns the resilient structure to the rest position. • · 22 92671 Device according to claim 4 or 5, characterized in that the vacuum collecting means have a second part (151) arranged downstream of said first part (150) with respect to the direction of rotation of said wheel (11, 12), said second part of the vacuum collecting means comprising two fixed vertical pipe sections (155,156), one above the track of the spikes (13) and the other below this track in a fixed position, and that air is forced out of the lower pipe section (156) and sucked into the upper pipe section (155) at the same flow rate to develop an upward air column spikes moving past a fixed station. An apparatus for opening a filled plastic bag, characterized in that said apparatus comprises: (a) two endless loops (90, 91), one loop moving in the first plane of rotation and the other loop moving in the second plane of rotation, the second loop being adapted to rotate clockwise and the second loop is adapted to rotate counterclockwise, and each loop rotates at the same angular velocity, and the two loops are oriented such that the first and second planes are nearly coplanar and have at least one proximal location (107) where the two loops are located tangentially spaced apart; , (b) a plurality of spikes (102) spaced apart on each loop (90, 91) so as to extend in each case from the same side of the plane of rotation of that loop and in a direction substantially perpendicular to that plane of rotation; and (c) means (96) for placing the sack on these prongs (102) moving past a proximal location (107), the subsequent spacing of the spikes of the two loops (90,91) as they move away from the particular proximal location causing tear lines on the surface of the spike-resting sack; wherein the tangential spacing of the loops (90,91) and the spacing of adjacent spikes (102) in the same loop are 92671 23 such that when the spikes of the two loops move away from a particular proximal location (107) the tear lines on the surface of the sack resting on the spikes are sufficiently close to each other merge to form a single continuous hole in this surface, whereby the contents of the sack fall out through this hole. The device of claim 10, further comprising: (d) means (95) for transporting the filled bag to a particular proximal location (107). The device of claim 10, further comprising: (d) means (105) for collecting the contents of the sack after the contents have fallen out of the sack. The device of claim 10, further comprising: (d) means (104) for detaching the bag from the one or more spikes (102) after the contents of the bag have fallen out of the bag. The device of claim 10, further comprising: (d) means (95) for transporting the filled bag to a particular proximal location (107); and (e) means (105) for assembling the contents of the bag after the contents have fallen out of the bag. Device according to Claim 11 or 14, characterized in that the transport means is a downcomer (95) oriented at such an angle that the sacks slide freely along it, the lower end of the downcomer ending above a particularly close location (107). 24 92671 Device according to claim 12 or 14, characterized in that the sack content collecting means (105) consists of a ramp and a conveyor belt, the ramp being arranged below the endless loops (90,91) for collecting the contents of the sack falling from the sack, and the conveyor belt is arranged so that extends transversely to the bottom of the ramp to assemble the goods coming from the ramp. Device according to claim 13, characterized in that the sack removal device is a vacuum suction mechanism (104). The device of claim 10, further comprising: (d) means (95) for transporting the bag to a particular proximal location (107); and (e) means (96) for pressing the sack against the spikes (102) moving past a particularly close location. Device according to claim 18, characterized in that the conveyor means (95) is a downcomer oriented at an angle such that the sacks slide freely along it, the lower end of the downcomer ending above a particularly close location (107), and the pressing means (96) is a wheel supported by an outer end of a pivoting arm, the inner end of this arm being rotatably mounted on the body of the device. 19,92671 The patent claimed et Device according to claim 10, characterized in that each endless loop is formed by the edge of the wheel (11, 12) and has only one proximal location (15), where the edge of each wheel is tangentially spaced from the circumference of the other wheel. Device according to claim 13, characterized in that each endless loop is a chain (90,91) and has two proximal locations where the chain pairs ·· are spaced tangentially apart, 92671 25 wherein one of the proximal locations is said specific location (107), and another nearby location is the location of the sack removal means. Device according to claim 10, characterized in that each spike (13; 102) is attached to each loop so that the spike is inclined in the direction in which the loop moves at the attachment point. Device according to claim 22, characterized in that each spike (13; 102) is attached to each loop so that it is also inclined towards the inside of this loop. Device according to Claim 10, or 22 or 23, characterized in that each spike (13, -102) has a generally rectangular cross-section. Device according to Claim 10, or 22 or 23, characterized in that each spike (13, -102) has a generally circular cross-section. Device according to claim 10, characterized in that each spike (13; 102) is provided with a boundary edge for contact with the surface of the bag, the boundary edge of each spike being oriented so as to extend perpendicular to the direction of movement of the spike. Device according to claim 20, characterized in that the sack alignment means consist of two elements (45, 49), each of which is generally in the shape of a truncated cone, each element rotating together with a corresponding wheel (11, 12), and each element being oriented so that it rotates with respect to said wheel such that the axis of rotation of the element intersects at the first angle of the axis of rotation of said wheel, the flat ring (50) extending around the larger end of each element, each ring being oriented so that its surface is substantially perpendicular against the axis of rotation of said element, wherein the outer circumference of each ring and the edge of said wheel move in close proximity to each other at a proximal location (15), and the conical inclination of the two elements aligns the bag with a proximal location. The device of claim 27, further comprising at least one rigid member (85) extending transversely to the web of the top of the sacks moving away from the proximal location (15) of the device body, the rigid member causing each sack to pivot so that the spikes (13) the hole provided in the surface of the bag extends in front of the top of the bag. The device of claim 27, further comprising two plates (82), each plate being positioned so as to extend slightly above and perpendicular to the surface of said ring (50) to push any article possibly supported by the ring away from the ring. Device according to claim 27, characterized in that it further comprises two sack tensioning means units (60), each tensioning means unit comprising a tensioning arrangement and a guide rail set, each tensioning arrangement being arranged adjacent to the circumference of said wheel (11,12) and consisting of two adjoining cylindrical members (63, 68) rotating in opposite directions to define a traction line adjacent the wheel edge, said guide rail set guiding a sack attached to the wheel spikes (13) to the traction line of said tensioning means, the cylindrical members of each tensioning means being adapted to remove ice therefrom. Device according to claim 30, characterized in that the contiguous cylindrical members 92671 27 are two cylindrical toothed members (63, 68), and that the traction line is a line of contact determined by the contact of the teeth of the two toothed members. The device of claim 30, further comprising a vacuum suction mechanism (73) positioned to collect each sack after the sack is tensioned by one of the sack tensioning means (60). Device according to claim 30, characterized in that each chain (90,91) extends around the first wheel (98,100) and the second wheel (97.99), respectively, wherein a particularly close location (107) is between a pair of second wheels, and each chain travels along a corresponding fixed track as it moves from said first wheel to said second wheel, the tracks being positioned so that the distance between the chains is greater as they travel along the tracks than when they revolve around either the first or second wheels. ‘♦ 28 92671