Patent Publication Number: US-4646509-A

Title: Method and apparatus for packing elongated food material such as pickle spears

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention relates to an apparatus for packing elongated articles such as cucumbers or pickles, sliced into the form of spears, into a container with the sliced surfaces of the food material facing outwardly. 
     Elongated food material such as cucumbers and pickles are often packed in glass containers, i.e. jars, as spears which are obtained by slicing the material along its length into a plurality of sectors. Thus, for example, a pickle may be sliced into five sectors or spears. It is customary to position the spears of a plurality of pickles ajacent the wall of the jar in order to fill all available space adjacent to the wall. A demand has developed for packing spears of substantially large cucumbers or pickles, for example those of nearly two inches in diameter. Such large cucumbers or pickles are typically sliced in half, i.e. two spears. Accordingly, there has developed a need for an apparatus to pack spears resulting from such large cucumbers or pickles each of which has been sliced into two spears. 
     2. Description of the Prior Art 
     Prior art machines for packing food material sliced into spears with their sliced surfaces facing outwardly are shown in the applicant&#39;s U.S. Pat. No. 3,468,098, which issued on Sept. 23, 1969 for &#34;Spear Packing Apparatus&#34; and in the applicant&#39;s U.S. Pat. No. Re. 27,852, which issued on Dec. 25, 1973 for &#34;Spear Packing Apparatus&#34;. Briefly, U.S. Pat. No. 3,468,098 and U.S. Pat. No. Re. 27,852 show machines for packing cucumbers or pickles, each sliced into a plurality of spears, such as five spears. 
     The apparatus of U.S. Pat. No. Re. 27,852 includes a guide which extends into the upper portion of a jar adjacent the mouth thereof. The guide directs the spears sliced from one cucumber or pickle, for example five spears, to positions adjacent the wall of the jar. Since five spears only fill a portion of the jar adjacent the wall thereof, empty spaces remain between the spears. An actuator connected to each of the jar and the guide then simultaneously rotates the jar and the guide so that the spears of the next pickle to be packed can be placed in the empty spaces between the spears of the first pickle already packed in the jar. 
     SUMMARY OF THE INVENTION 
     An object of the invention is to provide means for guiding elongated articles such as spears sliced from cucumbers or pickles into containers where the guiding means is rotated with respect to the apparatus in response to the rotation of the container. 
     Another object of the invention is to provide means for coupling a guiding means when disposed in the interior of the container to the bottom of the container for rotation therewith. 
     A further object of the invention is to provide means for biasing the guiding means to a predetermined circumferential position with respect to the apparatus in response to the downward movement of the guilding means upon removal of a container from engagement therewith. 
     These and other objects, features and advantages of the present invention will become apparent and more readily appreciated from the following detailed description of a preferred exemplary embodiment of the invention, taken in conjunction with the accompanying drawings. 
     The invention comprises an apparatus and a method for packing elongated articles into containers. The apparatus and method of the invention are particularly adapted to pack cucumbers or pickles sliced into spears into glass jars with the spears disposed vertically adjacent the side wall of the jar. 
     The machine of the invention includes means for rotatably supporting the container at a filling station in substantially an upright position for movement about a vertical axis. There is provided means for delivering spears in a predetermined array to the mouth of the container. In the array, the longitudinal axes of the spears extend substantially vertically and are spaced apart symetrically with respect to one another to form intervals between the spears. 
     The machine of the invention includes a guiding means which is adapted to extend downwardly through the mouth of a container and into the interior thereof when the container is at the filling station. The guiding means enables the array of spears to be delivered into the container in a predetermined arrangement in which each spear is disposed substantially vertically adjacent to the side wall of the container in circumferential locations corresponding to those of the array and with a space between each spear. The guiding means is pivotally mounted about a vertical axis correspsonding to that of the rotational axis of the container at the filling station. 
     Means are provided for turning the container about its vertical axis through a predetermined arcuate increment to position unoccupied circumferential locations of the spaces within the container adjacent to locations within the container already occupied by spears. 
     Means are also provided for indexing the guiding means about its pivotal axis through a predetermined arcuate travel corresponding to the predetermined arcuate increment through which the container is moved. 
     A feature of the invention is that the means for indexing the guiding means includes means for coupling the guiding means to a bottom portion of the container so that the turning of the container indexes the guiding means through its predetermined arcuate travel. An advantage of this arrangement is that the guiding means caan be indexed in synchronism with the turning of the container without the need of a separate drive for the guiding means. 
     In one embodiment of the invention, the means for coupling the guilding means to the container comprises suction cups mounted on the guiding means and having the concave portion thereof adapted to face and contact the bottom portion of the container. 
     Another feature of the invention is that the guiding means is mounted on a stationary shaft which enables the guiding means to rotate with respect to the shaft. Means are provided for biasing the guilding means to a predetermined circumferential position with respect to the shaft in response to the container disengaging the guiding means. One embodiment uses a detent mechanism to accomplish this. Another embodiment uses a clock-spring mechanism to orient the guiding means. As a result, the biasing means positions the guiding means to guide the next array of spears in response to the removal of a container adjacent thereto. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective view of the rear portion of an apparatus constructed in accordance with teachings of the invention; 
     FIG. 2 is a fragmentary perspective view of the front portion of the apparatus of the invention; 
     FIG. 3A is a fragmentary vertical section view showing a side of the upper portion of the apparatus of the invention for slicing cucumbers into a pair of spears for packing in a jar; 
     FIG. 3B is a fragmentary vertical section rotated 90° with respect to the section of FIG. 3A and showing a pair of spears being directed into a jar; 
     FIG. 4 is a fragmentary perspective view of a means for pushing spears into a jar; 
     FIG. 5 is a horizontal section view, taken along the line 5--5 in FIG. 3A and showing a cutting element for slicing a cucumber or pickle into two spears; 
     FIG. 6 is a horizontal section view taken along the line 6--6 in FIG. 3B and showing chutes for directing the spears to a desired orientation before being packed into a jar; 
     FIG. 7 is a horizontal section view taken along the line 7--7 in FIG. 3B and showing the lower end of the chutes where the spears are oriented in a reverse position; 
     FIG. 8 is a fragmentary vertical section view showing a means for rotating a jar at a filling station; 
     FIG. 9 is a fragmentary vertical section view of the apparatus of the invention for supporting and elevating a jar for packing; 
     FIG. 10 is a fragmentary vertical section view of a jar having its top portion in contact with the engaging means and showing the means for moving the engaging means; 
     FIG. 11 is a plan view showing a rack and pinions for rotating the jars; 
     FIG. 12 is a horizontal section view taken along the line 12--12 in FIG. 10 and showing the lower end portion of the chutes, the deflector for the spears, and the guiding means; 
     FIG. 13 is a horizontal section view taken along the line 13--13 in FIG. 10 and showing the guiding means, the spears positioned within the jar, and the biasing means; 
     FIG. 14 is a horizontal section view taken along the line 14--14 in FIG. 10 and showing slots in the bottom portion of the guiding means; 
     FIG. 15 is a fragmentary perspective view partially in section showing the deflector, the guiding means, and a detent biasing means of the apparatus of the invention; 
     FIG. 16 is an exploded fragmentary perspective view partially in section showing the biasing means including a clock-spring biasing means for the guiding means; 
     FIG. 17 is an elevational view of a mechanism for raising and lowering the jar to the filling position; 
     FIG. 18 is a perspective view of a still intact cucumber or pickle sliced into two spears; and 
     FIG. 19 is a perspective view of a cucumber or pickle sliced into two spears with the sliced surfaces thereof disposed opposite to one another. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The apparatus and method of the invention for packing elongated articles, such as spears sliced from cucmbers or pickles, is described hereinafter in accordance with its preferred embodiment and with reference to the accompanying drawings. 
     Referring to FIG. 1, the packing apparatus 19 of the invention includes a number of the elements of the apparatus shown in each of the U.S. Pat. No. 3,468,098 and the reissue U.S. Pat. No. Re. 27,852, both of which are incorporated herein by reference. The apparatus includes a product feed conveyor 20 having a plurality of transversely extending pockets 21. Whole cucmbers or pickles 22 are inserted into the pockets 21 with an end of each pickle 22 placed against wall 23 which extends along the upwardly inclined portion of conveyor 20. As seen in FIG. 1, ends of the pickles 22 may extend beyond the end of the pockets 21 disposed opposite wall 23. As conveyor 20 moves in the direction of the arrow A in FIG. 1, past blade 24, the blade cuts away any excess length, i.e., tips 22a, to provide pickles 25 with a standard predetermined length. 
     The packing apparatus as shown in FIG. 2 consists of four essentially identical packing units 26-29, which are commonly driven for simultaneous operation. Since each of the packing units 26-29 is substantially identical to the others, hereinafter only the construction of packing unit 26 is described. 
     Referring now to FIG. 3A, packing unit 26 comprises a filling station which includes slide 30 leading into a hopper 31. Hopper 31 contains two sets of rollers 32, 33 which project through openings in the side of hopper 31 to engage the sides of a pickle 25. The rollers 32, 33 ensure that the pickle 25 is centered above slicing knife 34 which is located between the lower set of rollers 33 and the bottom of the hopper 31. Above the hopper 31 is a pushing means 35 which corresponds to that shown in the U.S. Pat. No. 3,468,098 and U.S. Pat No. Re. 27,852. In the illustrated construction, the pushing means includes two assemblies 35a (FIG. 4) each of which includes pusher 35b and a pair of cables 35c connected to the pushers by ball joints 35d. Cable 35c supports a string of plastic bead-like elements 35e within tubular housing 35f (FIG. 3A). Housing 35f is moved upwardly by means (not shown) to the position shown in FIG. 3A to enable a pickle to enter the hopper from slide 30. Thereafter, housing 35f is lowered, which movement causes pushers 35b to push a pickle through hopper 31 in engagement with rollers 32 and 33. 
     Below the knife 34 at the bottom of the hopper 31 there is disposed means for delivering a plurality of elongated articles, i.e. spears 36, in a predetermined array. The delivering means includes twisted chutes 37 which are connected to the bottom portion of the hopper 31 and into which the spears 36 pass after being sliced by knife 34. In the illustrated construction, there are two chutes 37 since each pickle 25 is being sliced into two halves, i.e. two spears 36. At the top 37a of the chutes 37 (FIG. 3A), the spears 36 have their sliced sides facing each other (FIG. 5). Approximately half-way down the chutes 37 at mid-portion 37b (where FIGS. 3A and 3B are separated), the spears 36 are rotated to the position as shown in FIG. 6. At the bottom portion 37c of the chutes 37 (FIG. 3B), the spears 36 are positioned back-to-back away from each other (FIG. 7). As shown in FIG. 7, spears 36 are spaced apart symetrically with respect to one another to form intervals 36a therebetween. 
     The spears are forced downwardly with respect to housing 35f and through the chutes 37 by a means (not shown) which moves pushing assemblies 35a to adjacent the bottom ends of the chutes. 
     As shown in FIG. 2, empty jars 40 are advanced into the apparatus of the invention in the direction of the arrow B in FIG. 2 by a conveyor (not shown). In a manner similar to that shown in the reissue U.S. Pat. No. Re. 27,852, rams 41 mounted on carriage 42 are cyclically reciprocated to cause the end portion 41a of each ram to advance an empty jar 40 onto a means for rotatably supporting a container or jar, namely support 43. Support 43 can be a plastic turntable 115 mounted on ball bearing 116 to enable a jar to be rotated thereon (FIG. 17). Guide rods 44 (FIGS. 2 and 9) position a jar 40 onto the support 43 and stabilize the jar while it is being raised and lowered on support 43. 
     FIG. 17 also shows the mechanism for simultaneously raising (and lowering) the jar 40 in the four units 26-29 from the conveyor level to the filling position. An actuator (not shown) vertically raises a lift bar 102, which extends horizontally below the four units 26-29. The lift bar 102 rotatably supports horizontal shaft 104 which has a gear 106 mounted on each end of the opposite ends of shaft 104. Only one gear 106 is shown in FIG. 17. Vertically extending racks 108 (only one shown in FIG. 17) are engaged with each of gears 106. The engagement of the racks and gears enable shaft 104 to maintain lift bar 102 horizontal as it is moved vertically. 
     For each unit 26-29, the lift bar 102 is provided with a bushing 103 mounted thereon and retained by snap-ring 103. Lift shaft 112 is slidably supported with respect to lift bar 102 by bushing 103. Lift shaft 112 extends vertically adjacent guide bar 113. Retainer 114 is clamped to the guide bar 113 and lift shaft 112. Spring 117 surrounding lift shaft 112 abuts bushing 103 and retainer 114. Accordingly, the spring provides a resilient link between the lift bar 102 and lift shaft 112. Bearing bottom 118 is supported by lift shaft 112. The bearing bottom moves within the cylindrical interior of guard 119 which is mounted on tie bar 120. 
     Pull rods 121 are connected at their upper ends to tie bar 120 and slidably extend through bushings 102a and 102b on lift bar 102. Springs 123 disposed between bushings 102b and stops 124 mounted on pull rods 121 provide a resilient coupling between the pull rods and the tie bar 120. Uprights 61 slidably extend through bushings 125 in bed plate 126. Support 43 (FIGS. 2 and 9) comprises dead plate 127 and turntable 117 (FIG. 17). Dead plate 127 is mounted on bed plate 126. Within the opening 127a of the dead plate is disposed about turntable 115, mounted on ball bearings 116. Bolt 128 retains turntable 115 with respect to lift shaft 112. 
     As the lift bar 102 is elevated, it transmits force through bushing 103 to spring 117 and thereby to retainer 114 which transmits the force to lift shaft 112. The lift shaft then elevates turntable 115 with respect to dead plate 127, thereby raising the jar 40. When the upper portion 40a of the jar intersects resilient ring 69 as shown in FIG. 8, thereafter plate 66 is elevated by the jar and with the plate, uprights 61 which are attached to plate 66 by set screws 62. Further upward movement of jar 40 causes plate 66 to be elevated until it abuts the bottom portion of bushings 63 mounted on fixed center plate 60 as shown in FIG. 8. It should be noted that upward movement of lift bar 102 does not initially move tie bar 120. Thus, as lift bar 102 is initially elevated, the lift bar simply slides along pull rods 121. It is only when the top portion of the jar abuts the resilient member 69 that plate 66 begins to move upwardly. This movement is transmitted to uprights 61 which are connected to plate 66 by set screws 62. In turn, uprights 61, connected to tie bar 120, move the tie bar upwardly. As tie bar 120 (FIG. 17) moves upwardly, guard 119 passes through opening 126a in bed plate 126. 
     When the upper portion 40a of the jar abuts the resilient member 69 (FIG. 8), the compression of the upper portion 40a with respect to the resilient member is limited by the spring characteristic or constant of spring 117 (FIG. 17). Thus, the spring 117 can compress and prevent excessive force from being applied to the jar which could otherwise crush the jar when plate 66 abuts bushings 63 of center plate 60 (FIG. 8). 
     When lower plate 66 contacts bushing 63, the jar 40 is in the filling position. Pin 74 engages socket 72b in pinion 72. The jar 40, plate 66, uprights 61, tie bar 120, pull rods 121 and lift shaft 112 no longer rise (FIG. 17). Any further elevation of the lift bar 102 simply compresses spring 117 to insure a tight seal of the jar&#39;s upper portion 40a on the resilient ring 69. The apparatus, therefore, can accommodate a range of jar heights because the spring has a range of compression. 
     In FIG. 9, jar 40 is shown positioned on support 43 adjacent to guide rods 44. The opening of the jar is then in a position of alignment with the means for guiding an array of spears, namely guide 45. Guide 45, as shown in FIGS. 9, 15 and 16 has a cone-shaped body portion 45a disposed above a cylindrical portion 45b. Guide 45 includes indentations 45c (FIG. 9) which extend vertically with respect to the cone-shaped body portion 45a. In addition, the guide includes indentations 45d extending along cylindrical portion 45b with the indentations 45c and 45d being aligned with one another. As shown in FIGS. 12, 13 and 14, the illustrated construction has (by way of example) six indentations 45d in the cylindrical portion which are in alignment with six corresponding indentations 45c (not shown) in the cone-shaped body. Further by way of example, the six indentations are semi-circular because a pair of chutes 37 (FIG. 12) delivers spears 36 which comprise half-slices of a cucumber or pickle (FIGS. 18 and 19). It can be seen in FIGS. 12 and 13 that the guide 45 serves to position the spears substantially vertically adjacent to the side wall 40b of the container and in circumferential locations which correspond to those of the predetermined array of spears defined by the bottom portion 37c of the chutes (FIG. 3B). 
     Guide 45 is pivotally mounted on vertically extending shaft 46 which is connected to deflector 38 (FIG. 9). The deflector 38 is mounted upon the bottom end portion 37c of the chutes (FIG. 15). A positioning means is located at the bottom portion 45e of the cone-shaped body 45a (FIGS. 9 and 15). One embodiment of the positioning means for guide 45 comprises a detent mechanism. In this embodiment, the bottom portion 45e of cone-shaped body portion 45a has a plurality of downwardly facing conical recesses 45g which are disposed in a circle centered about the vertical axis of the cone-shaped body portion 45a. Each of the recesses 45g is contiguous to the recesses adjacent thereto. In addition, each recess 45g is radially aligned with a different one of indentations 45c and 45d of the guide 45. Attached to lower end 46a of the shaft is carrier 50 upon which is mounted cone-shaped pins 51 which are disposed at a radial distance from the center of shaft 46 which corresponds to the radius of the circle of the recesses 45g in the bottom portion 45e of the cone-shaped body portion. Carrier 50 is secured on shaft 46 by nut 49. 
     Whenever there is no jar 40 in engagement with guide 45, for example as shown in FIG. 9, guide 45 descends vertically along shaft 46. Whereupon the cone-shaped pins 51 act as a detent mechanism or a biasing means by entering two oppositely disposed recesses 45g of the plurality of recesses in the bottom portion of the cone-shaped body, thereby positioning the guide with respect to shaft 46. As shown in FIG. 14, each of recesses 45g are in alignment with indentations 45d. Accordingly, whenever pins 51 are nested in recesses 45g, the guide 45 is maintained in a predetermined position with respect to the bottom portion 37c of chutes 37. This predetermined position is shown in FIG. 12. As a result, spears 36 can be advanced downwardly from the chutes into contact with deflector 38 and then into the indentations 45c and 45d of the guide. 
     FIG. 16 shows an alternate embodiment of the positioning mechanism using a clockspring. In this embodiment, coneshaped portion 145a of guide 145 has a groove 148 extending circumferentially for a portion of the circumference of the bottom 145e of the cylindrical portion 145b of the guide 145. This groove 88 extends for a length greater than the rotational index movement of the guide 145 (120° in the illustrated construction). A disc 89 is fixedly mounted on the lower end 146a of the shaft 146. Pin 89a extending from the upper face of disc 89 travels in groove 148. The disc 89 is positioned to enable guide 145 to rotate about shaft 146 with bottom 145e in sliding contact with the top portion of disc 89 with the uppermost portion of cone-shaped body portion 145a disposed adjacent the bottom portion of deflector 38. The disc 89 is fixed on the shaft 146 in a predetermined circumferential orientation such that the pin 89a contacts the end of groove 148 when indentations in guide 145 corresponding to those of guide 45, indentations 45c, 45d are aligned with the chutes 37 and deflector 38. 
     A clockspring 90 has end tab 90a thereof mounted in slot 91 in the bottom of the end plate 46a of shaft 46. The clockspring has an outer loop 90b engaged with pin 93 on carrier 186. After winding of the spring 90, the carrier 186 is inserted in the bottom of the cylindrical portion 145b of the guide 145 with pin 94 engaged with groove 95. 
     When guide 145 of FIG. 16 is rotated incrementally with jar 40 during the filling operation, the guide moves clockwise when viewed from below in FIG. 16. Each incremental rotational movement of guide 145 moves end loop 90b of clockspring 90 since the loop is engaged to pin 93 on carrier 186 which rotates with the guide. Since tab 90a of clockspring 90 is held stationary by slot 91 in the end 146a of shaft 146, clockspring 90 becomes incrementally wound or tightened each time pin 89a advances along groove 148. When the jar is lowered after filling and disengaged from the guide, the clockspring then drives the guide counterclockwise as viewed from below in FIG. 16 to its rest position in which the guide 145 is ready to receive spears at the commencement of the next filling cycle. 
     As shown in FIGS. 1, 8 and 11, fixed base plate 60 extends along the length of the machine and is provided with openings 60a (FIGS. 8 and 11) through which the lower end portions 37c of the chutes extend. Upper plate 64 (FIG. 8) is supported with respect to base plate 60 by sleeves 65. The upper plate 64 supports the lower end portion of the chutes 37c. 
     As shown in FIGS. 8 and 9, lower plate 66 contains a circular opening 66a in which is rotatably mounted the means for engaging the container at the filling station when the top portion 40a of the container is positioned at a predetermined level with respect to the apparatus. The means for engaging the container includes carrier 68 which is fixedly disposed in circular opening 67a of ring 67. Ring 67 is pivotally mounted in circular opening 66a with the shoulder 67a abutting the lower surface of lower plate 66. Ring 67 which is attached to carrier 68 is pivotally mounted within circular opening 66a by means of snap ring 67a. Resilient member or ring 69 is clamped in position on the carrier by retainer 70. When lower plate 66 is moved vertically by container 40 abutting resilient member 69, and comes into contact with bushings 63, resilient member 69 is then disposed at the predetermined level within the apparatus at which the top portion 40a of the container is engaged to the resilient member 69. 
     As shown in FIG. 8, pinion 72 having teeth 72a is rotatably mounted with respect to base plate 60 by snap ring 73. The rotational movement of pinion 72 is coupled to carrier 68 and thereby resilient ring 69 by means of pin 74, mounted in carrier 68 by screw 74a and engaged with socket 72b in pinion 72. Pin 74 is engaged with socket 72b of the pinion 72 when lower plate 66 is elevated. 
     As shown in FIG. 11, each of pinions 72 at stations 26-29 is driven in rotation by rack 75. As shown in FIG. 2, the rack is slidably supported by blocks 76 extending downwardly from base plate 60. The rack 75 is driven by actuator 77 which can be a pneumatic or hydraulic actuator. When the actuator 77 is in its rest position (to the left as viewed in FIG. 11) sockets 72b in pinions 72 are in alignment with pins 74 extending from carriers 68. The actuator 77 includes two cylinders 78 and 79 with wall 80 separating the cylinders (FIG. 11). Cylinder 78 includes piston 78a attached to piston rod 78b which in turn is attached to a frame member 81 of the apparatus 19. Accordingly, the application of pressure to cylinder 78 enables the actuator 77 together with the rack 75 to be reciprocated with respect to frame member 81 since piston rod 78b is attached to the frame member. Cylinder 79 of the actuator 77 includes piston 79a attached to piston rod 79b. Coupling 82 connects piston rod 79b  to rack 75. 
     Upon applying pressured fluid to cylinder 79, piston 79a and thereby piston rod 79b can reciprocate rack 75 with respect to actuator 77. With the arrangement of actuator 77, which comprises the means for moving the engaging means to turn a rotatably supported container engaged therewith, there can be two predetermined movements of rack 75 which enable the rack to rotate the pinion 72 with two predetermined rotational motions. Thus, applying pressured fluid sequentially to the right side of cylinder 78 and to the left side of cylinder 79 (as viewed in FIG. 11) enables the rack to be moved through two predetermined strokes extending to the right. By applying pressured fluid to the opposite side of each of the pistons, actuator 77 can be returned to adjacent frame member 81, thereby moving the rack to the left. 
     As shown in FIGS. 2 and 9, a jar 40 has been advanced by ram 41 with respect to support 43 to a position adjacent guide rods 44 beneath guide 45. The guide 45 is shown at its bottommost position with respect to shaft 46. In this position, cones 51 are engaged with recesses 45g to index the guide 45 to a predetermined position in which indentations 45c are in alignment with deflector 38 and the bottom portion 37c of the chutes. 
     As shown in FIG. 10, jar 40 has been elevated by support 43 so that top portion 40a of the jar is at the predetermined level and in engagement with resilient member 69. In this position, the means for indexing the guiding means, guide 45, can rotate the jar about the vertical axis thereof. The indexing means includes suction cups 83 which are engaged to the bottom portion 40c of the jar when the jar is at the predetermined level. The suction cups are mounted upon bar 84 which is attached to stud 85, mounted with respect to carrier 86 by nut 87 threaded thereto. The carrier 86 is retained within groove 45h in cylindrical portion 45b of guide 45 by snap ring 88. 
     It can be seen in FIG. 10 that when the jar is elevated to the predetermined level at which the top portion of the jar engages resilient member 69, the suction cups 83 can couple the guide 45 to the bottom portion 40c of the jar. As a result, rotational movement for indexing the guide 45 can be transmitted from the rack 75, through the pinion 72, through pin 74 disposed in opening 72b of the pinion, to carrier 68 and resilient member 69, and thereby to the jar 40 disposed upon support 43. 
     In operation of the apparatus of the invention where the cucumbers or pickles to be packed are sliced into pairs, and where three pairs of slices 36 are to be disposed in a container as shown in FIGS. 12 and 14, the three pickles to be packed in the form of six slices 36 require three cycles of the introduction of pickles into hopper 31 and three cycles of operation of the pusher assembly 35. Thus, with jar 40 in the position shown in FIG. 10, a first pair of slices 36 in response to the operation of pusher assembly 35 advances past deflector 38 and into indentations 45d of the cone-shaped portion 45a of guide to position the slices vertically within the jar (FIGS. 10, 12, 13 and 14). 
     One of cylinders 78 and 79 of actuator 77 shown in FIG. 11 is then actuated to advance rack 75 a single increment. The advancement of the rack rotates pinion 72 clockwise as viewed in FIG. 11. Turntable 115 (FIG. 17) of support 43 facilitates rotation of the jar. The jar and guide 45 engaged therewith are rotated by the rack (FIG. 11) to a position of the guide in which the indentations 45c and 45d thereof are in alignment with deflector 38 in the bottom portion 37c of the chutes to receive the second pair of slices 36. A further incremental motion of the rack is achieved by actuating the remaining one of cylinders 78 and 79. This actuation rotates the jar and thereby the guide 45 to again align the indentations 45c and 45d to receive the final pair of slices. 
     After filling, the jar 40 is lowered in a manner which is the reverse of the raising operation. The actuator connected to the lift bar 102 lowers the lift bar (FIG. 17). Initially the lowering of the lift bar unloads spring 117 (which maintains the jar 40 in contact with the resilient member 69). When the lift bar moves downwardly with respect to pull rods 121, the lift bar eventually loads springs 123. Thus, springs 123 bear against stops 124 and apply a downward force to pull rods 121, tie bar 120, uprights 61 and lower plate 66. The lower plate 66 exerts a downward force on the jar 40 to disengage the top portion of the jar from the resilient member 69 and to move the jar downwardly and out of engagement with the suction cups 83 and to a position below the guide. At this time, pin 74 is withdrawn from socket 72b in pinion 72. 
     Descent of lift bar 102 also results in the lift bar abuting bumper 128. When bumper 128 is abutted, it applies a downward force to lift shaft 112. Finally, when turntable 115 is lowered to the conveyor level shown in FIG. 17, the jar 40 is positioned to be offloaded onto the exit conveyor 99 (FIG. 1). The clearance between the lower plate 66 and the jar 40 allows the jar 40 to be removed without obstruction. 
     Upon lowering jar 40 downwardly from the position shown in FIG. 10 for discharge from the filling station by ram 41, guide 45 slides downwardly by gravity with respect to shaft 46. At the bottom of its travel, guide 45 is indexed into its predetermined position by the indexing mechanism including cone-shaped pins 51 and recesses 45g. In the embodiment of the invention including guide 145, clockspring 90 serves as the indexing mechanism for the guide. 
     OPERATION 
     The preferred embodiment of the invention operates as set forth below. Empty jars 40 are delivered to the apparatus of the invention on input conveyor 98 moving in the direction of arrow A in FIG. 2. After filling, jars 40 are taken away from the apparatus on exit conveyor 99 moving in the direction of the arrow B in FIGS. 1 and 2. Rams 41, moving in the direction of the arrow C in FIG. 2 (the arrow adjacent ram 41), move empty jars 40 from input conveyor 98 onto support 43. In so doing, the empty jars 40 push full jars from supports 43 and deliver the full jars onto exit conveyor 99. Thereafter, support 43 is raised so that the upper portion 40a of each jar engages a resilient member 69 (FIGS. 8 and 10). 
     The first pickle 25 to be packed is then cut into slices, such as a pair of half slices or spears 36 (FIG. 18). The cutting is accomplished by pusher assembly 35 which drives a pickle 25 out of the hopper 31, through knife 34, and into the twisting chutes 37 (FIG. 3A). The resulting spears 36 are pushed down the chutes 37 where they are rotated about their length with the result that the cut portion of each spear 36 faces outwardly. 
     The spears 36 are then ready to be packed into the jar 40. The spears 36 are advanced by the pusher assembly 35 to pass along the deflector 38 into the jar 40 (FIG. 10). The spears 36 descend along the cone-shaped body 45a and into the indentations 45c and 45d thereof to form a predetermined array along the jar wall 40b. The cylindrical portion 45b of the guide including indentations 45d hold the spears 36 against the inside wall of the jar 40b (FIGS. 13 and 14). 
     The apparatus is then made ready for the packing of a second pickle 25. The pusher assembly 35 is retracted upwardly to enable a second pickle to enter hopper 31 (FIG. 3A). Actuator 77 advances the rack 75 to the right (FIG. 11). The rack 75 rotates the pinion 72 and thereby resilient member 69 which rotates the jar 40 resting on the ball- bearing supported turntable 115 of support 43 (FIG. 17). The bottom portion 40c of the jar 40 which is engaged by the suction cups 83 rotates the guide 45, thereby aligning the guide so that the next group of spears 36 can be located between the indentations 45d of the guide adjacent to those occupied by spears 36 from the previous operation of the pusher means 35. 
     The apparatus of the invention can use more than two pickles 25 to fill the jar 40. Thus, the guide 45 can be rotated, by way of example, through an arc corresponding to 360°, divided by the number of chutes 37, and divided by the desired number of pickles 25 to be packed into the jar 40. Thus, in the illustrated construction, the jar 40 and guide 45 are rotated through 360°, divided by two, and divided by three, i.e., a 60° step between operations of the pusher assembly 35, since three pickles 25 are being packed as six sliced half-spears 36. 
     Once the jar 40 has been rotated through the first rotation, the pusher assembly 35 drives another pickle 25 through the knife 34, down the chutes 37, and into the jar 40. Since the guide 45 has been rotated, the spears 36 are positioned between spears 36 of the previous action. The actuator 77 is then operated to rotate the jar 40 and guide 45 once more. Another pickle 25 is then sliced into spears 36 and inserted into the jar 40. 
     Once the filling of a jar is completed, the filled jar 40 is then lowered on support 43 until the bottom portion of the jar 40 is level with the exit conveyor 99. Lowering the lower plate 66 for a portion of the down-stroke stabilizes the jar 40 and releases suction cups 83 from the bottom portion 40c of the jar. The weight of guide 45 causes the guide to descend along shaft 46 thereby enabling the indexing means to position the indentations of the guide 45 to be in the proper position to receive spears 36 when the next jar 40 is raised on support 43. 
     Empty jars 40 from the input conveyor 98 then push full jars 40 onto the exit conveyor 99. The filled jars 40 are then advanced out of the apparatus. If desired, additional spears 36 can be placed adjacent to the central region of the interior of the jar 40 between the pairs of spears packed against the wall 40b of the jar.