Abstract:
A transfer type of product filling machine includes a stationary deadplate positioned under a moving line of openbottom transfer receptacles. Containers moving in a separate line under the deadplate in synchronism with the line of transfer receptacles are progressively filled as the transfer receptacles pass over either a continuously tapered or a stepped termination of the deadplate to prevent bridging of loose materials or individual items across the container openings by abrupt dumping of the materials into the containers. The stepped type of deadplate termination also facilitates exact count filling of a single container from a plurality of intermediate receptacles, each holding an integral fraction of the total count fill, and speeds the filling operation by providing a plurality of filling locations.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to container filling machinery and particularly to a machine amd method for transferring a predetermined quantity or number of items from an intermediate receptacle to a final container. 
     2. Description of the Prior Art 
     My U.S. Pats. No. 3,517,708 issued June 30, 1970; No. 3,621,891 issued Nov. 23, 1971; and No. 3,696,581 issued Oct. 10, 1972 describe rotary-drum machines for filling intermediate receptacles with predetermined amounts of materials for transfer to ultimate containers, and their disclosures are incorporated in this application by reference. 
     In these prior machines, elongated rake members spaced circumferentially around a horizontal or inclined drum mounted for rotation about its axis each have a plurality of inward-projecting tines for picking up portions of materials such as food products in the bottom of the drum as the drum rotates and for carrying the portions to a predetermined release point near the top of the drum for discharge onto a chute or shaker tray for delivery into a line of intermediate receptacles extending through the drum. The receptacles are fastened to an endless conveyor that includes means for shaking the receptacles as they are filled to eliminate voids and to obtain a uniform packing density in each receptacle corresponding to a predetermined package amount. After being filled, the intermediate receptacles are transported by the conveyor to a separate station outside the drum where their contents are transferred to a line of ultimate containers on a second conveyor that is synchronized with the movement of the receptacle conveyor. 
     The present invention is directed to an improvement over the transfer apparatus disclosed in my copending application Ser. No. 588,205 filed on June 19, 1975, which is a continuation of application Ser. No. 423,123 filed on Dec. 10, 1973 now abandoned. That application discloses means for delivering a predetermined number of items of substantially uniform size from a drum-type filling machine to a line of containers. The delivery means comprises a plurality of open-bottom intermediate receptacles transported by an endless conveyor from a filling station inside a revolving drum loader to a delivery station outside the drum. 
     A stationary base plate or deadplate is positioned under the receptacles and extends from the filling station to the delivery station. The receptacles have flat bottoms that rest on and slide over the base plate between the filling and delivery stations; so that no transferred material drops through the open bottoms of the receptacles until the base plate terminates at the delivery station. 
     The base plate of my prior application ends abruptly at right angles to the line of travel of the intermediate receptacles. It has been found in certain filling situations that sudden delivery of all the materials in an intermediate receptacle may cause the materials to bridge across the opening of the final container below. The bridged material prevents the remainder from entering the container, resulting in short fills and a product cleanup problem at the final fill location. This becomes a particular problem when the final container has a relatively small opening in relation to its capacity or when the product items are angular or irregular in shape. 
     Another problem arises when several small intermediate receptacles are needed to assure an exact integral multiple count fill in each final container. This situation occurs with items of non-uniform shape or of a statistical size variation great enough to cause an inexact fill in a given transfer receptacle unless it is sized to hold only a predetermined small numer of the items, the small number being an integral fraction of the total count fill desired in the container. 
     For example, it might be desired to fill a jar With one dozen bouillon cubes, but the largest receptacle pocket that will consistently hold only a predetermined number of cubes may be one that is sized to hold only three cubes. Then four transfer receptacles, or four separate pockets in one receptacle, will be needed to carry the cubes to fill one container. Having only a single transfer position in this situation complicates the synchronization of the receptacle and container lines and also limits the speed of the conveyor line to a fraction of the speed of the receptacle line. 
     Still another problem results when it is necessary to fill a container having a small opening in relation to its volume, such as a small mouth jar, or a narrow deep box, such as a dry cereal box, with a predetermined amount of loose materials. In order to rapidly fill a transfer receptacle having the appropriate volume, it is desirable to make the receptacle relatively shallow with straight sides. This results, however, in a mismatch between the large opening area of the transfer receptacle and the small opening area of the final container, and some means is required to channel the flow of material from the receptacle to the container to prevent spilling. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to provide an apparatus and method for transferring a predetermined amount of solid materials or a predetermined number of items progressively from a moving line of intermediate receptacles to each container in a moving line of final containers to prevent bridging of materials across the opening in the container by too rapid a transfer. 
     It is another object of the invention to provide an apparatus and method for transferring a predetermined number of items from each of a plurality of separate pockets in a moving line of transfer receptacles at an equal plurality of spaced transfer locations to a single container in a moving line of containers. 
     Another object of the invention is to provide an apparatus and method for transferring a predetermined number of items from one pocket in each of a plurality of parallel columns of pockets in a line of moving transfer receptacles to a single container in a line of moving final containers. 
     Another object of the invention is to provide an apparatus for transferring loose materials from a moving line of open bottom, straight sided transfer receptacles to a moving line of open top final containers in which the opening in the top of each final container is smaller in at least one dimension than the opening in the bottom of each transfer receptacle. 
     These and other objects are achieved in a machine of the type described above that includes a plurality of transfer receptacles each having at least one open pocket for receiving materials at an intermediate filling region and means for conveying the transfer receptacles in a closed path from the intermediate filling region to a final filling region extending over a line of moving final containers, in which the improvement comprises the provision of a stationary deadplate positioned for slidable contact underneath each open pocket of each transfer receptacle and extending with decreasing width along the path of the transfer receptacles in the final filling region for progressively uncovering the openings of the pockets to allow the materials to drop into the containers. 
     The width of the deadplate may decrease either continuously with distance along the path of the transfer receptacles or discontinuously, that is in stepwise fashion, depending on the type of filling operation. When a container is to be filled with a predetermined amount (i.e. weight or volume) of loose materials from a single receptacle, a deadplate with continuously decreasing width allows the materials to flow gradually from the receptacle to the container below, without bridging across the container opening. 
     On the other hand, when a container is to be filled with a predetermined total number of items from a plurality of receptacles or receptacle pockets, each holding a fraction of the total number of items, a stepped deadplate will allow progressive discharge from predesignated ones of the receptacles at successive step locations into the same container. 
     In the latter arrangement, the receptacles or receptacle pockets are arranged in a plurality of columns extending parallel to the path of the receptacles. The width of the deadplate decreases in steps equal to the number of columns, and the line of containers extends diagonally with respect to the path of the receptacles directly below the midpoint of each step. The movements of the two lines are synchronized so that a given container will appear successively beneath each of the deadplate steps as preselected ones of the receptacle pockets in successive columns are respectively uncovered by the same steps. Since each step provides a separate filling position, the stepped deadplate arrangement allows a container filling rate several times faster than would be possible with only a single deadplate termination point. 
     The stepped deadplate arrangement also permits filling different sizes of containers with different numbers of the same kind of items from the same receptacle sizes. For example, in the bouillon cube filling situation described above, one size of container could be filled with one dozen cubes by delivering three cubes successively from one proper sized receptacle pocket at each of four step locations, the receptacle pockets being arranged in four parallel columns. Larger containers each could be filled, for example, with two dozen cubes from the same receptacle line merely by providing that each container receives the contents from two successive receptacle pockets in each column. 
     If the container openings are large enough to cover the area under two adjacent receptacle pockets in a column, then the linear speeds of the receptacle and container conveyors can be equal. If the container opening is smaller than this area, however, it will be necessary to adjust the relative speed of the two lines to keep the container under each step filling location long enough for two successive receptacle pockets to discharge their contents into the opening of the container. 
     Alternatively, a plurality of funnel means may be provided to transfer the contents from one or more adjacent receptacle pockets to a single container when the openings of the receptacle pockets cover a larger area than the opening of the respective final container. The funnel means are mounted on conveying means for transporting the funnel means through the final filling region in synchronism with the transfer receptacles, each funnel means being positioned below the deadplate directly underneath a corresponding one or more receptacle pockets for guiding their entire contents into a single container. 
     The conveyor means for the funnels may be the same as the conveyor that transports the transfer receptacles, or it may be a separate conveyor that follows a different path than that of the receptacle conveyor except in the final filling region, where the receptacle conveyor, the funnel conveyor, and the final container conveyor all converge. In either arrangement, the funnel conveyor means preferably may include means for moving each funnel means vertically from a first level to a second level with respect to a corresponding final container after the paths of the funnel means and the containers converge. At the first level, the bottom of the funnel is higher than the top of the container to allow the funnels to clear the containers when the two lines converge. At the second level, the bottom of the funnel is surrounded by the top of the container to insure that no materials spill over the edge of the container. 
     Even with the use of funnels and graduated filling, some types of materials may still bridge across the container openings or cause voids inside the containers. Consequently, the present invention further includes a method and means for shaking the containers as they pass under the deadplate in the final filling region to prevent bridging and voids as the containers are filled. 
     A preferred shaking means includes an eccentric motor drive for transmitting oscillatory motion through crank arms to a shaft mounted in bearings below and parallel to the line of containers in the final filling region. Guide rails on either side of the line of containers, which are connected to the oscillating shaft by generally U-shaped brackets, impart a lateral shaking motion to the containers as they move through the final filling region. 
     The same eccentric drive motor can be used also to actuate a shaking mechanism for the transfer receptacles as they pass through the intermediate filling region to assure that each receptacle is properly filled and to remove any excess material from the tops of the receptacles. 
     The source of items for filling the receptacles in the intermediate filling region preferably includes an open-ended drum mounted for rotation about either a horizontal or slightly inclined axis. The items are delivered to the bottom of the drum, preferably by means of a chute through one of its open ends. Shelf members circumferentially spaced around the inside of the drum carry items, as the drum rotates, from the bottom to a discharge point near the top of the drum. At the discharge point, the items are released, preferably onto a chute or shaker tray from which they are delivered to the receptacles. 
     Before each receptacle enters the intermediate filling region, it comes into sliding contact with the stationary deadplate. Items then cascade from the chute or tray over the top of the receptacle and fall into individual pockets of the receptacle, if it is subdivided into rows of pockets. The receptacle is simultaneously shaken to aid the filling process and help orient the items in the pockets. The shaking continues for a short distance after the receptacle leaves the intermediate filling region to dislodge any excess items remaining on the top. 
     A conveyor then transports the receptacle, still sliding along the deadplate so that no items are lost from its open bottom, to a final filling region outside the drum. The final filling region extends above a line of open top containers, with the width of the deadplate progressively decreasing as described above. 
     Additional features and advantages of the invention will become apparent from the following description of the preferred embodiment as disclosed in the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective view of the preferred arrangement of the deadplate in the final filling region showing also a cut away drum-type machine for filling the receptacles. 
     FIG. 1A is a closeup perspective view of a deadplate termination arrangement similar to that of FIG. 1. 
     FIG. 2 is an overhead view of the final filling region of the embodiment of FIG. 1. 
     FIG. 3 is a partially cut away side view of the final filling region of the embodiment of FIG. 1 showing the means for synchronizing the movement of the containers with the movement of the transfer receptacles. 
     FIG. 4 is an end view of the final filling region taken along the lines 4--4 of FIG. 3. 
     FIG. 5 is a perspective view of an alternative embodiment of a final filling arrangement according to the invention. 
     FIG. 6 is a mechanical schematic of the arrangement of receptacle, funnel and final container conveyors of FIG. 5. 
     FIG. 7 is a mechanical schematic of another arrangement of receptacle, container, and separate funnel conveyors. 
     FIG. 8 is an end view of the conveyor arrangement of FIG. 7. 
     FIG. 9 is a top view of an alternate embodiment having laterally adjustable deadplate sections in the final filling region. 
     FIG. 10 is a side view of the embodiment of FIG. 9. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to the drawings, FIG. 1 shows a perspective view of a complete filling apparatus incorporating the improvement of the present invention. A drum-type filling machine 11 of the type fully described in my prior patents incorporated by reference above includes a horizontal open-ended drum 12 supported for rotation about its own axis in a frame, that is not shown to avoid unnecessary detail. 
     Materials or items to be packaged are introduced into the drum by means of a chute (not shown) through one of the stationary end plates 13 or 14. A variable speed reduction unit 15 driven by an electric motor 16 rotates the drum and also supplies power through a drive chain 17 to an eccentric shaker device that will be described below. As the drum revolves in the direction shown by the arrow, the materials are raised by means of shelves 18 spaced circumferentially around the interior of the drum to a discharge point near the top of the drum, where a flap or dam 18a is swung inboard about pivot journal 18b by lever arm 18c, having a follower 18d that rides in a cam track (not shown) fastened to the outside of stationary end plate 13 to allow the materials to slide off the shelves onto a chute or shaker tray 19. Shaker tray 19 is mounted by four parallel pivot legs 19a on two longitudinal rails 19b, 19c joined by end bars 19d, 19e that in turn are adjustably attached to end plates 13, 14 by bolts 19f through slots 19g. 
     From the lower lip of the shaker tray the items cascade onto a line of transfer receptacles 20 in an intermediate filling region A. The receptacles are coupled to an endless link conveyor line that extends in a straight path through the drum, passes around an idler sprocket wheel 21, doubles back in a straight path along the outside of the drum through a final filling region B, and then passes around a drive sprocket wheel 22 to re-enter the drum. 
     In the embodiment of FIG. 1, the receptacles 20 are subdivided into transverse rows and longitudinally extending columns of cylindrical, open-bottomed pockets 20a. In the particular embodiment illustrated, there are four pockets in each row and four rows in each receptacle, but any other pocket matrix can be chosen, depending on the receptacle size and desired individual pocket size. The size of each pocket is chosen to hold a predetermined amount of the material being transferred, the amount being a fraction of the total amount desired in each final container. 
     As described earlier, the subdivided receptacles shown in FIG. 1 are particularly suited for count filling operations in which a specified number of items is to be placed in each final container. The individual pockets in each row will normally be the same size and will hold a fraction of the total number of items for each container equal to the reciprocal of the number of columns of pockets. The pockets in one or more columns may be of a size different than those in the other columns, however, so as to hold different numbers of items. Thus, the arrangement of FIG. 1 is suitable for filling a final container with a total number of items that is not evenly divisible by the number of columns of pockets. For example, a count fill of ten items per container could be accomplished with four columns of pockets, the pockets in three of the columns holding three items each and the pockets in the fourth column holding only one item. 
     In the straight portions of the path of the transfer receptacles, the conveyor links are guided in a channel member 24 inside the drum filler and in a channel member 25 outside the drum filler. Channel member 24 is mounted by stationary guide structures 26 and slide arms 26a which provide lateral oscillatory motion of the channel in response to reciprocation of connecting rod 27 which is driven by eccentric 28 coupled to shaft 29. Shaft 29 is journalled in a pillow block 30 and carries a counterweight 31 which balances the shaking forces of the oscillation, channel 24. Shaft 29 is driven by speed reducer 15 through sprocket 17, chain 17a and sprocket 17b attached to shaft 29. 
     As discussed earlier, lateral shaking of the transfer receptacles as they pass through the cascade of items in the intermediate filling region assists in orienting the items properly in the pockets and in dislodging any excess items left on the tops of the receptacles before the receptacles leave the drum. In this way, the extra items fall back into the drum and are recirculated up to the shaker tray. 
     Before entering the drum, the bottoms of the receptacles slidably engage a stationary plate or deadplate 32 that prevents any materials from escaping through the open bottoms of the receptacle pockets. After leaving the drum, the receptacles 20 continue around sprocket wheel 21 on a semicircular extension 33 of deadplate 32 and then onto a straight terminal portion 34 of the deadplate in final filling region B. It is the form of this final deadplate portion 34 and its function that is the principal feature of the present invention. This feature will be described in more detail in connection with FIGS. 2 and 5. 
     As shown in FIGS. 1 and 2 above the semicircular portion 33 of the deadplate, the endless link conveyor line 23 is formed by U-shaped receptacle support members 23a which are pivotally connected by means of hinge pins 23b and intermediate links 23c. The intermediate links 23c conform to the shape of cogs 21a on sprocket wheel 21, as shown in FIG. 2, for positive transmission of the wheel torque to the conveyor line. At the outer end of each arm of the U-shaped members 23a there is an upright mounting pin 23d (FIGS. 1, 2 and 4). Each receptacle 20 carries a pair of vertical mounting holes 20b, spaced apart by a distance equal to the spacing of pins 23d of each support member and sized to slidingly fit the pins. It is an easy and quick matter, therefore, to replace receptacles of one size of pockets by receptacles of another size, depending on the product and the number of items desired in each final container 35. 
     A line of such final containers 35 moves along a linear conveyor 36 supported in a guide channel 37 underneath the terminal portion of the deadplate for filling from the pockets 20a of the receptacles 20. Conveyor line 36 is in the form of a single flexible sheathed cable and the containers are supported in an upright position by stationary guide rails 38, 39 and 40, 41, respectively ahead and following the final filling region B (FIG. 1). 
     Within the final filling region B, a movable side rail 42 is supported at each end by arms 43 which are clamped at their lower ends to a shaft 44 rotatably journalled in bearings 45 (FIG. 3) directly underneath and parallel to conveyor line 36. Side rail 42 fills a portion of the gap between outside rails 38 and 40 (FIG. 1). A similar gap between rails 39 and 41 is closed by a screw-type container synchronizing means 53, shown in and described in connection with FIGS. 3 and 4, which is supported also from shaft 44 by support arms 46. 
     The entire container side support assembly in the final filling region is oscillated laterally about shaft 44 by means of a crank arm 47 having one end clamped to the shaft and the other end coupled through a connecting link 47a to work arm 48 connected to eccentric 28 with connecting rod 27 (FIGS. 1 and 3). The oscillating assembly in turn shakes the containers as they pass under the terminal portion of the deadplate to prevent bridging or voids as the containers are filled progressively from the transfer receptacle pockets. 
     The function of the terminal portion 34 of the deadplate in progressively distributing items from preselected pockets to each final container is illustrated in FIG. 1A and FIG. 2. The arrangement in FIG. 1A is the same as in FIG. 1 but is presented to illustrate the operation of the stepped plate more clearly. Starting at a point where the straight terminal portion 34 joins the semicircular portion 33, the width of the deadplate progressively decreases in longitudinally spaced steps 49, 50, 51, and 52, the last step marking the end of the deadplate. The width of each step is equal to the spacing between adjacent columns of receptacle pockets 20a and the midpoint of each step lies under the centerline of each corresponding column of pockets. In addition, it will be apparent from FIG. 2 that the midpoint of each step lies directly over the centerline of container conveyor line 36, so that the direction of the conveyor line is skewed in relation to the path of the receptacles through the final filling region. 
     The longitudinal spacing between successive steps 49 through 52 is chosen preferably to coincide with the spacing between a preselected number of rows of receptacle pockets. In FIG. 2, a step occurs at every sixth pocket row, but any other spacing could be chosen, as desired. The containers also are spaced equally along the container line, and the relative speeds of the receptacle and container lines are preselected so that a container will always be in position under a receptacle pocket as that pocket slides over its respective step. Again in FIG. 2, the containers are spaced so that the distance between three containers is equal to the distance between six receptacle pockets. Therefore, if each container is to receive the contents of one pocket in each column at the step location corresponding to that column, the container line will have to run at twice the linear speed of the receptacle conveyor. On the other hand, if each container is to receive the contents of two adjacent pockets in each column at the step location corresponding to that column, then the linear speeds of the container line and receptacle conveyor will be equal. Other possible combinations of step spacing, container spacking, row spacing, and relative receptacle and container line speeds provide a high degree of flexibility of count fill per container and item size for a given filling machine and deadplate arrangement. 
     The screw-type means 53 for synchronizing the movement of the line of containers with the movement of the receptacle conveyor, mentioned above, is shown most clearly in the views of FIGS. 2, 3 and 4. The inner support arms 46 carry between their upper ends at approximately the same level as side rail 42 a guide screw 53 journalled in bearings (not shown) for rotation about its own axis. A drive motor 54 is connected through a coupling 55 at one end of its shaft 56 to a transmission system (not shown) for turning drive sprocket wheel 22 (FIG. 1) for the receptacle conveyor 23. The other end of motor shaft 56 is coupled to the shaft of guide screw 53 through a drive sprocket 57, chain 58, first and second intermediate sprockets 59 and 60 mounted for rotation coaxially with shaft 44. Chain 61 and driven sprocket 62 mounted on stub shaft 63 with pinion gear 64 are supported by one of inner support arms 46. Gear 64 meshes with driven gear 65 on the guide screw shaft 53b. 
     Each container 35 fits between adjacent spiral lands 53b of the guide screw, and the overall speed ratio between the motor shaft 56 and the guide screw 53 is adjusted to produce the desired linear speed of container travel in relation to the linear speed of the receptacle conveyor that is driven by the same motor. 
     End portion 53c of land 53b is tapered to adjacent the surface of guide screw 53 in order to facilitate the entry of a container between the lands of the guide screw (FIG. 3). Movable siderail 101 extends adjacent to the path of travel of the containers entering the lands of guide screw 53. Guide rail 101 is supported by uprights 102 which are attached to shaft 103 pivotally mounted in brackets 104. Arm 105 which is also connected to shaft 103 is biased in a direction extending toward guide screw 53 by spring 106. With this arrangement guide rail 101 is urged against the side of the containers opposite the side thereof engaged by the guide screw as the containers enter the guide screw. In the event that a container is momentarily positioned against the outer surface of line 53b of the guide screw, the resilient mounting of guide rail 101 enables the guide rail to deflect and thereby enable the container to be engaged properly with the guide screw without damage to the container. 
     Also indicated in FIG. 4 is the adaptability of the system to containers of various sizes, a small container being shown in dot-dash lines and a large container in solid lines. If desired, different pitch guide screws can be made up for different standard container sizes. In addition, the height of conveyor line 36 and the position of side rail 42 are preferably adjustably by suitable means (not shown). 
     The mounting means for receptacles 20, described above in connection with FIG. 1, is shown more clearly in FIG. 4. Each upright pin 23d carries a locking detent 23e releasably actuated by a plunger 23f to permit quick locking and release of the receptacle block. 
     Referring next to FIG. 5, an alternate embodiment of the invention is shown that is particularly suitable for filling a predetermined amount (e.g. volume) of loose materials gradually from a single receptacle into a container having a different size or shape opening than the opening in the bottom of the receptacle. This embodiment features a terminal portion 34&#39; of the deadplate of the invention that continuously decreases in width to produce a gradual emptying of a transfer receptacle 20&#39; as it passes through the final filling region. 
     Each receptacle 20&#39; in the embodiment of FIG. 5 has a single pocket, although it is possible to use subdivided receptacles with the gradually tapered deadplate of FIG. 5, if desired. Each receptacle is attached to the receptacle conveyor through the upper branch of a C-shaped yoke 70, attached to a respective link of the receptacle conveyor. The lower branch of the C-shaped yoke carries a funnel means 71 having a flared upper opening of a shape and size to receive all the contents from the receptacle 20&#39; above it and a lower opening of a shape and size to fit within the opening in the top of a container to be filled. 
     The illustrated container in this embodiment is a  pg,19 pasteboard box 72, such as a dry cereal box, having four top flaps. The funnel means serves the additional functions in this case of holding the top flaps open and keeping each box in registry with its corresponding transfer receptacle. Consequently, the screw-type synchronizing means is not required in this embodiment, and a simple arrangement of outer guide rails 73, 74 supported by arms 75 and inner guide rails 76, 77 supported by arms 78 suffices both to support boxes 72 and to transmit lateral oscillatory motion from the eccentric drive described previously for preventing bridging and voids in the materials being discharged into the boxes. 
     As shown in FIGS. 6 and 7, the funnel means can be incorporated into the filling system in two different ways. In the embodiment of FIG. 6, a funnel is mounted directly underneath each receptacle, as in FIG. 5. In the embodiment of FIG. 7, the funnels 71 are mounted on a separate endless conveyor similar to the receptacle conveyor but displaced to one side so that only one side of the funnel conveyor coincides with the final filling side of the receptacle conveyor, as shown. 
     The funnel conveyor has a driving wheel 79 and an idler wheel 80, similar to the corresponding wheels for the receptacle conveyor. The drive wheels of both conveyors are turned in synchronism but in opposite directions in order to coordinate the funnel movement with the receptacle movement in the final filling region. 
     FIG. 8 shows an end view of the embodiment of FIG. 7, to illustrate the respective levels of the receptacles and funnels in the final filling region as well as a preferred arrangement for engaging a funnel 71 inside the opening flaps of a corresponding box 72. As shown in the drawing, funnel 71 is attached by an arm 81 to a sliding bushing 82 that is mounted on a vertical post 83 carried by a link 84 of the funnel conveyor. Link 84 is supported by upper and lower guide wheels 85 and 86, respectively, in an elongated channel 87 that is positioned parallel to the similar outside channel 25 of the receptacle conveyor so that the funnels will follow a path directly under the receptacles through the final filling region. 
     On the side of vertical bushing 82 opposite arm 81 is a follower wheel 88 that rides on a fixed track 89 that is secured to the frame structure of the funnel conveyor by any suitable means (not shown) and extends parallel to channel member 87 through the final filling region. The height of track 89 drops from a first level, at which the bottom of the funnel is maintained by follower wheel 88 above the top of the corresponding box 72 as the funnel conveyor and line of boxes converge at the entrance to the final filling region, to a second level, at which the bottom of the funnel is below the edges of the flaps and surrounded by the box opening, as shown in FIG. 8. The track subsequently rises again at the exit from the final filling region to allow the funnel to disengage from the box. 
     Although FIGS. 5 and 8 illustrate the use of funnel means to channel materials from the transfer receptacles to the final containers in combination with the continuously tapered type of deadplate termination, such means may also be used with the step-type of deadplate termination and with the earlier described arrangement of parallel columns of receptacle pockets. In addition, the arrangement of separate pockets in parallel columns may be used with deadplate terminal portions of continuously decreasing width, if desired. Also the post and bushing funnel support arrangement of FIG. 8 can be adapted to the C-shaped yoke support of FIG. 5 as a means for engaging and disengaging each funnel from a corresponding box or other type of open top container. 
     FIGS. 9 and 10 illustrate still another embodiment of the invention in which separate plate sections 90, 91, and 92 form individually adjustable deadplate steps in the final filling region. Each plate section is suspended at its outer margin from the outer ends of a pair of inverted U-shaped arms 93. The inner ends of arms 93 are anchored to the top of channel member 25. Each arm is laterally adjustable; so that the lateral offset distance of one plate in relation to the previous plate can be varied to suit the particular conditions of the transfer operation. 
     The transfer arrangement in this embodiment is similar to that of FIG. 5; namely, a funnel 71 is spaced vertically below each open rectangular receptacle 20&#39; by a distance sufficient to provide clearance for the deadplate between the two. As shown in FIG. 10, however, there is a different arrangement for introducing each funnel into the top of a corresponding final container 72. 
     The conveyor system for the final containers in this embodiment consists of two endless belt conveyors 94 and 95 in tandem. The end roller 96 of belt 94 is located prior to the final filling region, and the first roller 97 of belt 95 is located after the final filling region. An elevated slide plate 98, with entrance ramp 99 and exit ramp 100, extends between end roller 96 and first roller 97. As is shown in the drawing, the final container boxes leave belt 94 at end roller 96 and slide up entrance ramp 99 and then along slide plate 98. The boxes are pushed along the slide plate by the following boxes moving with belt 94. 
     The speeds of the receptacle line and the final container conveyor lines are synchronized so that a funnel 71 arrives at the entrance ramp 99 coincidentally with a box 72. The box then rises on ramp 99 so that its upper edge surrounds the bottom of the funnel. At the other end of the slide plate, the boxes disengage from the funnels as they slide down exit ramp 100 and onto the second conveyor belt 95.