JPH11503696A - A device that simultaneously pulls out both bottom panels of a carton in a carton loading device - Google Patents

Abstract

(57) [Summary] A device (10) for loading a plurality of containers into a basket-shaped bottom opening carton (3) is a container supply mechanism, a carton supply device (30), and a carton for drawing each carton from the carton supply device. A feeder (50), a carton timing transfer assembly (60 or 260) for receiving each carton (3) from the carton feeder and starting to convey each carton in a parallel and synchronous manner above each container; A gripping member (82) assembly for opening the carton (3), a passage for receiving both bottom panels extending in a direction orthogonal to each carton, and an incline for conveying each carton while tilting the carton downward at the top of the container set; A belt assembly (90) and a mounting member positioned at the lowermost position when the mounting member rotates are provided with a handle portion top of each carton. A mounting assembly for engaging the handle portion top of each carton to case (120), a bottom panel closure mechanism (130,140,182) placed in a position to fasten the two bottom panels together, and provided with a.

Description

Description: FIELD OF THE INVENTION The present invention relates to a bottom-loading basket type carton for articles such as beverage bottles. BACKGROUND OF THE INVENTION A conventional method and apparatus for loading bottles from the bottom into basket-shaped cartons is described in U.S. Pat. U.S. Patent No. 2,276,129 to Currie et al. 2,603,924; U.S. Pat. U.S. Pat. No. 3,521,427 to Helms. U.S. Patent No. 3,627,193 to Arneson. U.S. Pat. No. 3,698,151 to Helms. U.S. Patent No. 3,751,872 to Calvert et al. U.S. Pat. No. 3,747,294 to Rossi. U.S. Pat. No. 3,805,484 to Focke et al. U.S. Pat. No. 3,842,571 to Ganz. U.S. Pat. No. 3,848,519 to Walter. 3,924,385; U.S. Patent No. U.S. Patent No. 3,940,907 to Crouch et al. U.S. Pat. No. 4,915,218 to Lashyro et al. U.S. Pat. No. 4,919,261 to Schuster. 5,234,103 and U.S. Pat. No. Re. 27,624. SUMMARY OF THE INVENTION The present invention provides a method and apparatus for continuously opening a basket-type bottom loading carton to load articles. An apparatus for loading a plurality of containers into a basket-type bottom-loading carton according to a preferred embodiment of the present invention comprises a first container infeed conveyor; a plurality of containers arranged in close proximity to the first container infeed conveyor for several columns. A dispenser for counting / dispensing each of the rows of containers into a plurality of container sets each having a predetermined number of containers; and a second member having a member engaged with the last container of each container set. A plurality of container holding conveyors having a plurality of container holding members for holding each set of containers; a carton supply device for drawing each carton from the carton feeding device; each carton from the carton supply device And a carton timing transfer assembly for receiving each of the cartons and starting to convey them in a parallel and synchronous manner above each of the containers; and both bottoms of each carton. A gripping member assembly for gripping the flanks and opening the carton by pulling the bottom panel outwardly with respect to the centerline of the carton; receiving the bottom panels extending crosswise of each carton facing each other. An inclined belt assembly comprising a pair of elongated slender endless belts for forming a path and transporting each carton while inclining downwardly above each set of containers; a groove engaging the top of the handle of each carton. A plurality of members having a plurality of members, and the plurality of members are disposed so as to act on each carton placed on each of the container sets by rotation. A sealing assembly configured to engage the top of the handle of each carton; and a position for securing the bottom panels together. And a two-component lug assembly for placement. Other advantages and features of the present invention will be apparent from the following description, the accompanying drawings, and the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a carton suitable for loading by an apparatus for a bottom-loaded basket type carton according to a preferred embodiment of the present invention. FIG. 2 is a plan view of a blank for forming the carton shown in FIG. FIG. 3 shows the carton shown in FIG. 1 in a folded state. FIG. 4 shows a container for storing the carton of FIG. 1 folded as in FIG. FIG. 4A shows a container for storing the carton of FIG. 1 folded as in FIG. 3, configured to be used with the carton automatic loading function of the hopper of the apparatus shown in FIG. is there. FIG. 5 is a perspective view showing a loading device for a bottom loaded basket type carton according to a preferred embodiment of the present invention. FIG. 6 is a perspective view showing a hopper in the apparatus shown in FIG. FIG. 7 is an elevation view of the hopper shown in FIG. 6 with at least one carton loaded. FIG. 8 is a perspective view showing a carton supply mechanism of the apparatus shown in FIG. FIG. 9 is a plan view showing an engagement portion with a carton in the nip belt assembly of the device shown in FIG. FIG. 10 is a perspective view showing a grip hole insertion assembly of a timing transfer unit used with the apparatus shown in FIG. FIG. 11 is a perspective view showing the grip hole insertion member for the assembly shown in FIG. FIG. 12 shows a modification of the handle portion of the carton shown in FIG. FIG. 13 is a cross-sectional view of the grip hole insertion assembly shown in FIG. 10 with the insertion member inserted into the handle of the grip hole of the carton and a stop guide rail that facilitates insertion of the insertion member into the carton. . FIG. 14 is a view showing a part of the front end of the main part of the grip hole insertion assembly shown in FIG. FIGS. 15 and 16 are schematic diagrams showing the panel gripping assembly of the apparatus shown in FIG. 5 in an activated state. FIG. 17 is an elevational view of the apparatus shown in FIG. 5 showing the ends of the nip belt assembly and panel gripping assembly engaged with the carton. FIG. 18 is a plan view showing a layout of the panel gripping assembly of the apparatus shown in FIG. FIG. 19 is a side elevational view of the apparatus shown in FIG. 5 showing the panel gripping mechanism engaged with the cam track. FIGS. 20, 21, and 22 are views showing the cooperating state of the opening operation roller and the opening operation inclined member in the panel gripping assembly of the apparatus shown in FIG. FIG. 23 is a perspective view of the bottle conveying conveyor of the apparatus shown in FIG. FIG. 24 is a rear elevation view showing the bottle gripping part of the bottle apparatus shown in FIG. FIG. 25 is a plan view of the bottle gripping conveyor of the apparatus shown in FIG. FIG. 26 is a side elevation view of the tilt / mount assembly of the apparatus shown in FIG. FIGS. 27 and 28 are end elevation views of the apparatus shown in FIG. 5 as viewed from the inclined belt portion. FIG. 29 is a perspective view showing a modified example of the inclined block of the device shown in FIG. FIG. 30 is an elevational view showing a case where the carton mounting assembly in the apparatus shown in FIG. 5 is constituted by planetary gears. FIG. 31 is a perspective view showing a bent piece sticking assembly of the apparatus shown in FIG. FIG. 32 is a plan view of a bending block of the bending piece sticking assembly shown in FIG. FIG. 33 is a side elevation view of a bending block of the bending piece sticking assembly shown in FIG. 31. FIG. 34 is a side elevation view of a bent block of the bent piece sticking assembly shown in FIG. 31. FIG. 35 is a side elevation view of a bent block and a seal block of the bent piece sticking assembly of the apparatus shown in FIG. FIG. 36 is a plan view showing the bottom panel alignment assembly. FIG. 37 is a perspective view of a bottle stabilizing assembly for the device shown in FIG. FIG. 38 is an end view of the bottle stabilizing assembly shown in FIG. 37 engaged with a carton package. FIG. 39 is a perspective view showing a second modification of the timing transfer segment of the apparatus shown in FIG. A preferred embodiment method and apparatus 10 will be described below as a preferred embodiment of the Detailed Description Carton present invention is suitable especially loaded into the bottom loading basket cartons 3 of such carton shown in Figure 1. Although the method and apparatus according to the present invention are not applied only to the carton 3 described below, the features of the present invention become very clear by describing the handling and loading of the illustrated carton 3 as an example. FIG. 2 shows a blank 906 of the carton 3. FIG. 3 is a plan view showing the carton 3 shown in FIG. 1 in a folded state. Carton 3 is disclosed in U.S. Patent Application No. 08 / 326,987. This U.S. application was filed by the assignee of the present application. In order to understand the present invention, the carton 3 and the blank 906 for forming the carton 3 will be described below. First, reference is made to FIGS. The illustrated carton 3 is generally adapted to accommodate two rows of bottles. The example of the carton 3 described here illustrates the use of the present invention. In this case, the carton 3 has two bottles in each row and two bottles in each row. The ones stored in the rows, that is, the ones for six packs and the eight packs. However, in the present invention, the number of bottles in one row may be different from those in these examples. Both sides of this carton have the same configuration. Thus, the features described for the side (side) shown in FIG. 1 apply to the other side which is not visible in FIG. Cutouts are formed in the side walls 920 and 930, respectively, and thereby substantially form lower side wall bands 921 and 931 and upper side wall bands 923 and 933. These lower bands 921, 931 and upper bands 923, 933 are bendably connected to end walls 940, 942, 950, 952 by corner tabs 922, 923, 924, 934, respectively. These corner tabs 922, 923, 924, and 934 form slanted corners at the intersections of the side walls 920, 930 and the end walls 940, 942, 950, 952, respectively. In addition, the cutouts form central portions 928 and 938 left as they are on both side walls 920 and 930. A central cell is formed on each side of the carton by cell bands 925, 935, corner tabs 926, 936, and cell centers 927, 937, respectively. The cell corner tabs 926 and 936 are foldably connected to the cell bands 925 and 935, and the cell central portions 927 and 937 are formed integrally with the side walls 920 and 930. Raised panels 960, 962, 970, 972 extend between the bottom of the carton 3 and the handles formed from the handle configuration panels 980, 982, 990, 992. In FIG. 1, the handle flap 984 can also be seen. The cutting lines existing between the cell central portions of the side walls 920 and 930 and the respective handle forming panels 980, 982, 990 and 992 terminate at cutting curves 986, 988, 996 and 998, respectively. The cutting lines between each upper band 923, 933 of each side wall 920, 930 and the corresponding central cell section terminate at cutting curves 987, 989, 997, 999, respectively. In the folded state (FIG. 3), this carton 3 has nicks 929, 939 deliberately provided at the oblique corner tabs on the cutting line between the side wall and the central cell. ing. This feature is not clear when the carton is fully assembled, but can be seen in the blank 906 of FIG. 2 and the folded carton 3 of FIG. The blank 906 is essentially symmetrical with respect to the perforated fold line that divides the handle configuration panels 980, 982, 990, 992 of the carton in half. One of the two bottom walls 910 and 912 is wider than the other, and the bottom wall 912 is a larger bottom wall for convenience. The other bottom wall is conveniently the smaller bottom wall 910. Each side wall 920, 930 has a cutout, or cutout, so that the lower side wall bands 921, 931 and their adjacent corner tabs 922, 932 and the upper bands 923, 933 and their adjacent. Corner tabs 924 and 934 are formed. The central cells are formed by central cell bands 925, 935, central cell corner tabs 926, 936, and central cell central portions 927, 937 integrated with the respective side walls 920, 930. Each connecting portion 929, 939 connects the upper side wall band 923, 933 and the center cell corner tab 926, 936. End walls 940, 942, 950, 952 are connected to the side walls 920, 930 via side wall corner tabs 922, 930, 924, 934. A riser panel is connected to each end wall 940,942,950,952 along a perforated fold line. Support tabs 961, 963, 971, 973 for attachment to the bottom wall panels 910, 912 are foldably connected to the lower edges of each riser panel 960, 962, 970, 972. Further, a carton suitable for loading according to the present invention has a plurality of tabs connected along a fold line to the lower edge of each end wall 940, 942, 950, 952 without departing from the spirit of the present invention. It may be. The central cell bands 925, 935 are connected to the lower part of each handle panel 980, 982, 990, 992 along a perforated fold line. Each of these handle component panels 980, 982, 990, 92 has a grip hole 981, 983, 991, 993 formed therein. The cutting lines separating the central cell bands 925, 935 and the associated cell corner tabs 926, 936 from these handle configuration panels terminate at cutting curves 986,988,996,998. A cutting line separating the upper band 923, 933 and its associated corner tab 924, 934 from each cell band 925, 935 and its associated cell corner tab 926, 936 forms a cutting curve 987 in each side wall 920, 930. , 989, 997, 999 respectively. The handle flaps 984, 994 are respectively connected to the handle forming panels 980, 990 along the perforated folding line, and are located in the grip holes 981, 991 formed in the handle forming panels 980, 990, respectively. The cutting curves 986, 987, 988, 989, 996, 997, 998, 999 ensure that the carton and its blank are not directly stressed at the end of the cutting line. As already mentioned, the methods and apparatus described below are generally particularly suitable for loading into cartons having the features described above. The cartons 3 can be folded, transported, loaded into an apparatus described below, further assembled, and loaded with a bottle by the above-described components. Although there are several types of bottles that are suitable for being handled and loaded according to the invention, the invention is particularly suitable for loading the illustrated carton 3 with so-called molded PET bottles. The carton 3 is mounted on the apparatus according to the present invention in a folded state in which the bottom wall panels 910 and 912 are bent upward until the bottom wall panels 910 and 912 contact the side wall surface as shown in FIG. In this state, the carton 3 is easily loaded into the device according to the invention, and subsequently, the device is started up and the bottle is loaded. However, since the support tabs 961, 963, 971, and 973 are exposed, they may be damaged during the movement in this state. Therefore, the present invention is provided with preparation means for loading the carton 3 into the apparatus. As means for preventing the support tabs 961, 963, 971, 973 from being damaged while the carton 3 is being conveyed to the loading section, and as means for facilitating the operation of loading the carton 3 into the apparatus (described later), The carton 3 is stored upside down in a container such as a box shown in FIG. In this state, the handle portion of the carton is located downward, and the lower end portion is directed upward. The end walls 2 and the side walls 4 of this container 5 for the carton 3 extend above the exposed and projecting support tabs 961, 963, 971, 973 and thus the support tabs 961, 963, 971, 973. Is protected from damage during transport to the loading position. The container 5 is placed close to the hopper 30 of the apparatus and turned upside down, and the carton 3 is placed on the chute of the hopper 30 with the bottom part down, and is put into a state of being operated by the apparatus. FIG. 4A shows a container 205 for a folded carton 3 according to another form. In this container 205 as well, the end walls 202 and the side walls 204 extend above the projecting tabs of the carton, but each end wall 202 has a slot 208 extending between the projecting tabs. Is formed. The container 205 in which the slot is formed is used in connection with the automatic loading function (described later) of the hopper. This container 205 shown in FIG. 4A has openings on the respective end walls that are located on the same axis. This opening is used as a means for inspecting the container of the carton.If the openings of the carton which are formed in a normal state are aligned with each other and penetrate straight through without any interruption, the cartons are properly configured. It is said that it is. For example, referring to FIGS. 2 and 3, this carton has a portion between the bands 921 and 923 and 931 and 933 facing each other, which becomes an opening if the carton is a regular one. Understand. The carton and blank can also be configured such that the opening remains unobstructed when the carton is correctly folded. Therefore, when the openings 203 are aligned so as not to be obstructed, the path to be formed by the openings is not obstructed, and thus each carton is a regular carton. That the container is suitable for use with a probe or sensor. Overview of Apparatus and Method Referring first to FIG. FIG. 5 shows an overview of the device 10 according to a preferred embodiment of the present invention. The device 10 is configured on an elongated frame. The moving directions of the bottle 1 and the carton 3 are from left to right in the figure. Briefly, the bottles travel in two rows on the device 10 along a substantially straight path. As the bottle travels along each determined path, the cartons (these cartons are folded) and the bottom wall panel is folded upwards so as to abut flatly on the sides of the folded cartons. Moves to the carton supply device 50 along the hopper 30. The supply device 50 moves the individual cartons 3 from the hopper 30 to a timing section 60. A timing-transport section counts and sends out the cartons at a predetermined speed at set intervals. In one embodiment, the timing transfer unit comprises two consecutive assemblies. The first segment in these two assemblies is the timing section 60. In this timing section, each carton is separated from the suction cup 54 of the supply device 50 and is conveyed to a downstream device of the device 10 at a predetermined timing and speed. Here, in what is generally referred to as a timing segment of the timing transfer section, a passage is formed between a pair of belts oriented in the vertical direction. That is, this segment is the nip belt assembly 70. The longitudinal nip belt 72 is a pair of opposed endless belts which sandwich or "nip" the handle of each carton (the top of the carton) and remove the cartons from the device. 10 is moved to a predetermined linear conveyance path toward the downstream side. In another embodiment of this timing transport, the timing function and the transport function are not as clearly distinguishable as those described above. In the second embodiment, the carton 3 is engaged by a grip hole formed in a handle portion of the carton and is conveyed thereby. Timing and transport operations are performed by reciprocating grip hole insertion members attached to the plurality of cam engagement rods. These rods slidably engage the endless chain. When each carton 3 is in the hopper 30, its bottom wall panel 910, 912 is folded upward so as to be in flat contact with the side of the carton 3. . The bottom wall panels 910, 912 of these cartons will move downward from their flat contact with the sides of the carton when the carton moves away from the hopper 30. As the carton 3 passes through the timing section, the bottom wall panels 910, 912 are pulled outward and are opened for loading. While the cartons 3 are being pulled and opened along the transport path of the apparatus 10, each bottle is moving along the transport path below the cartons. In the lower transport path (bottle transport path), star wheels 105 provided on both sides of the apparatus 10 divide the rows of the bottles 1 into a predetermined number for loading. The grouping is performed, for example, such that the number of bottles in each row is three or four. One means for transporting the bottles after being grouped by the star wheels 105 is an endless chain with a plurality of lugs. A plurality of bottle gripping members 113 (moving, for example, attached to an endless chain) are provided immediately downstream of the star wheel 105 to maintain the spacing of each bottle set in alignment. As each bottle 1 further moves along the length direction of the device 10, the distance between the bottles 1 and each bottle set is set by the bottle gripping member 113. At the same time, each carton 3 moves to a position where its bottom wall panels 910, 912 are captured by a pair of downwardly sloping belts 92, 94 and 93, 95. An upper conveyor mechanism, such as an endless chain assembly 100 provided above, is arranged above a handle located in the center of each carton 3. These upper conveyor mechanisms are arranged in parallel with the inclined belt assembly 90. A plurality of block members 102 attached to the upper chain engage with the top of the handle of each carton 3. The inclined belt assembly 90 and the upper chain assembly 100 move each carton 3 in front of, ie, downstream of, the two rows of bottles. The operation of moving the inclined belt assembly 90 and the upper chain assembly 100 downward is performed by the push-down wheel assembly 120. The push-down wheel assembly 120 is provided with a plurality of block members 122 for pushing down the top of the handle of each carton 3 so that each carton is completely pushed down toward each bottle set. As each carton 3 moves further forward from this depressed wheel assembly 120, a plurality of side lugs 134, each attached to a package conveyor 130, for example, an opposed endless chain 132, disengage the carton 3 / package 7 rear panel. And push them further forward along the device 10. As each carton 3 moves along the package conveyor 130, the bottom panel fasteners 140 fold the carton's support tabs 961, 963, 971, 973 and bottom wall panels 910, 912 to provide support tabs 961, 963. , 971 and 973 are folded to a position where they contact the bottom wall panels 910 and 912 to close the bottom of the carton 3. The bottom wall panels 910, 912 are pulled together so that they are properly aligned and held in place until the bottom of the carton 3 is closed by a rotary punching mechanism. The carton thus loaded and completely closed is discharged from the device 10. Bottle Feeding Conveyor Referring to FIG. 5, each bottle is fed into the apparatus 10 by a feed conveyor assembly 20. As the supply conveyor, those usually used in the beverage packaging field can be used. In the preferred embodiment shown, the conveyor assembly 20 includes a partition wall 22 that separates the conveyed bottles into two rows. Conveying means, such as endless belts or chains, move over the apparatus 10 to load each bottle into a respective carton 3. Different endless chains or belts and combinations of different endless chains or belts are used as the conveying means. Each carton 3 and bottle 1 move simultaneously along different transport paths in part of the path of the apparatus 10. That is, the carton 3 moves in the transport path arranged above the transport path for the bottle 1. As will be described later, these two transport paths become one when each carton 3 reaches above the set of bottles 1. Hopper Assembly As shown in FIGS. 5, 6 and 7, means suitable for loading each of the cartons is constituted by a hopper assembly 30. This hopper assembly 30 according to the preferred embodiment is essentially a conveyor driven chute. 6 and 7 are views of the hopper assembly 30 from its "loading" port side, i.e., from the end where the carton is placed for transport to the next assembly of the apparatus 10. FIG. In this hopper assembly, the opposing side walls 31, 32 form the chute. A pair of belts 37, 38 provide a transport means for the carton 3. Both belts 37, 38 can be moved by known driving means on a plurality of rollers mounted on support rods 41, 42 or similar structures. Further, these roller rods 41, 42 are mounted on tracks 43, 44 or similar structures. These tracks 43, 44 are also fixedly or movably mounted on the support rod 36, like the side wall tracks 33, 34. These tracks 33, 34, 43, 44 are attached along the longitudinal direction of the side walls 31, 32 and the roller rods 41, 42. Referring now in particular to the elevation view shown in FIG. 7, a folded bottle carton 3 suitable for being handled by the apparatus 10 and the hopper assembly 30 is loaded by the hopper, where the side wall of the hopper 30 is placed. The state which contact | abutted on 31 and 32 and the belts 37 and 38 is shown. The hopper 30 is adjustable so that it can store cartons 3 of different sizes, for example, cartons 3 for six packs or eight packs. This adjustment is made by moving the tracks 33, 34, 43, 44 along the support rod 36. Arrows 45 and 47 indicate the direction in which the trucks are moved in or out depending on the size of the carton 3 to be stored. For example, a six pack carton 3 would be shorter than an eight pack carton. Therefore, the two trucks and the side walls and belts respectively attached to the trucks are located closer in the case of the six-pack carton than in the case of the eight-pack carton. The both side walls and both roller rods may be moved, but one side wall and a set of belts are fixed, and the other set, for example, only the set with arrows 45 and 47 is moved. This can simplify the configuration. As shown in FIG. 7, the belt is in a position for each carton 3 to engage in close proximity to the projecting tabs 961, 963, 971, 973 of the carton. When the carton 3 is loaded into the hopper 30, the conveyor belts 37, 38 fold each of the folded and upright cartons along the side walls 31, 32 of the hopper to the "exit" end of the hopper. Move up to Operation of the hopper Each carton 3 is loaded into the "loading" port of the hopper with the bottom facing down. Referring again to FIG. 4, the front cartons 3 are loaded into the container 5 with their tops down so as to facilitate the work of loading a large number of cartons 3 into the front hopper 30 all at once. In this way, each carton 3 is loaded into the hopper 30 from the bottom simply by turning the container over. When the folded carton 3 is delivered, the carton tabs 961, 963, 971, and 973 are not damaged during transportation by storing the folded carton 3 in the container 5 in such an upside down state. Can be By packing the carton 3 upside down in this manner, the carton 3 can be conveniently transported without damaging the support tab, and the loading into the hopper 30 is facilitated. The hopper chute is angled with respect to the main body of the elongated device 10 in order to minimize the floor area occupied by the device while maximizing the length of the hopper. Carton Feeder Referring to FIG. 5, as described above, the apparatus is laid out in a substantially straight line, and the bottle 1 and the carton 3 are partially separated from each other in a vertical conveying path. And then the loaded carton travels along a single path, the rest of the apparatus 10. Referring to FIGS. 5 and 8, the carton supply device 50 separates each carton 3 from the hopper 30 and delivers it to a member in a linear carton conveying path disposed above the bottle path. The carton feeder 50 is a rotary assembly having three suction cup support mechanisms 52 arranged at intervals. Each cup support mechanism 52 supports a plurality of suction cups 54, and the suction cups 54 suck and separate the folded cartons 3 one by one from the outlet end of the hopper 30. Each of these mechanisms 52 rotates about a shaft 59 in a direction indicated by an arrow 57. For example, each support mechanism 52 can be rotated around the shaft 59 by a support fastening rod 53 in a sliding state. As one preferred example, one end of each fastening rod 53 is fixed to a member corresponding to the shaft 59, and the other end is attached to each of the support mechanisms 52. The rotation of the support mechanism 52 is performed by means well known in the mechanical field. For example, U.S. Pat. 4,625,575, No. 5,019,029, No. 5,102,385, and No. Any track cam mechanism using a drive shaft, a cam rod, a curved shallow and deep cam track, and a cam roller disclosed in US Pat. No. 5,104,369 can be used. These patents are hereby incorporated by reference. In this preferred embodiment, three cup supporting mechanism parts 52 are provided. However, the number of the mechanism parts 52 may be smaller than that, or four or more. The three mechanisms rotate each carton 3 in a horizontal plane and move it to the timing unit 60 or 260 of the device 10. In FIG. 8, the suction cup 54 is not shown to clarify other features. However, each nozzle 55 provided with each cup 54 is illustrated. These suction cups 54 are arranged at intervals so as to abut on a surface effective in handling each carton 3. The suction force for operating the suction cup 54, that is, the negative pressure, is applied by a general pneumatic device. The guide 56 is associated with a timing structure used to separate the carton 3 from the suction cup support mechanism 52. Two third configuration example of the timing transport section the timing transfer unit (timing-transport section) will be described. First, a first configuration example will be described with reference to FIG. As described above, the timing transfer unit transfers each carton 3 from the supply device 50 to a downstream device of the device 10. The timing transfer creates a predetermined gap between the cartons and moves them at a predetermined speed. In this way, the time interval is generated between the cartons, so that the carton 3 starts synchronous movement corresponding to each set of the bottles when the carton and the bottle 1 move downstream. -Timing transfer unit: The timing transfer unit according to the first configuration example of the first embodiment executes the timing operation and the transport operation in two different segments, that is, the timing assembly 60 and the transport unit. The transport section is a nip belt assembly 70 here. The timing assembly 60 includes a plurality of conveyor driven carton support fingers for engaging the cartons 3 to move the cartons at predetermined intervals and further inserting the cartons into the nip belt at predetermined intervals. I have. The carton support conveyor 60 is configured by a pair of an upper endless chain 61 and a lower endless chain 63. Each of the timing chains 61 and 63 has a plurality of lugs or fingers. These fingers come into contact with some parts of the folded carton 3 when the carton 3 is released from the suction cup 54 of the supply device 50. The upper timing chain 61 is provided with a series of upper engaging lugs 62, one of which abuts the rear edge of the handle of each carton. In the preferred embodiment shown, the upper engaging lug 62 abuts the intersection of the handle and the wall panel of the carton 3. A corner portion formed at the intersection is appropriate as the contact portion. The lower timing chain 63 includes a pair of lower engaging lugs 64, 65, 66. These lower engaging lugs operate correspondingly to each of the upper engaging lugs 62 of the upper chain 61, thereby firmly holding the carton 3 and guiding it to the nip belt 70. Although there are several effective combinations of the lower engaging lugs, in the illustrated preferred embodiment, each pair is provided with three lower engaging lugs 64, 65, 66. All three lugs 64, 65, 66 support the carton from the bottom. The rearmost lower engagement lug 66 acts particularly effectively to push the folded carton 3 forward. The nip belt assembly 70 receives the folded carton 3 from the supply device 50 and the timing assembly 60. The nip belt assembly 70 opens the carton 3 at the timing section 60 when the bottom panels 910, 912 of the carton 3 are grasped and moved outward to open the bottom of the carton for loading. At predetermined intervals. Referring now to FIGS. 5 and 9, the nip belt assembly 70 includes a pair of endless belts 72 provided on a plurality of rollers 74 each comprising an elongated rod. The belts 72 press against each other in an elongated vertical plane, the direction of movement 71 of these belts relative to the sandwiched carton 3 being downstream of the device. The uppermost part of the handle portion of the carton 3 is sandwiched between the two belts 72, and is transported along a moving path between the two moving belts 72. The upper belt guide 76 directs the top of the handle of each carton 3 to the path between the belts 72. The lower belt guide 78 extends along the length direction of both belts 72. By opening the lower belt guide 78, the support tabs 961, 971, 963, 973 extending below each carton 3 are directed into the guide 78. As shown in FIG. 17, when the top of the handle portion of each carton 3 is conveyed while being sandwiched between the two belts 72, the support tabs 961, 971, 963, and 973 move along the lower belt guide 78. -Timed transport section: Modified embodiment The modified timed transport section according to the modified embodiment forms several intervals between the cartons and transports them in a timely manner. Are different. Similar to the above embodiment, the present embodiment also engages with the folded carton 3 as shown in FIG. As shown in FIG. 10, the present embodiment uses a plurality of insertion members 262 attached to a chain. These insertion members separate the cartons 3 from each other and transport the cartons in synchronization with the downstream members of the apparatus. 11 and 12 show the grip hole insertion member 264 and one side of the grip hole 983 of the handle part of the carton 3 (the other side is also the same). The grip hole 983 is formed in a U-shape, and a U-shaped flap 984 is attached to an upper portion thereof so as to be able to bend. The insertion member 262 has a U-shaped and tapered projection 264 that corresponds to the shape of the grip hole 983 and the flap 984. The distance between the grip hole flap 984 and the sides of the grip hole 983 is somewhat elongated at the upper corners of the grip hole 983, which can be a suitable contact point. The upper corner of the U-shaped projection corresponding to this part of the insertion member 262 is dimensioned accordingly. The front portion 266 of the inner bottom surface of the insertion member 262 is formed with a chamfered slope to more easily fit the grip hole flap 984. As shown in FIG. 10, each of the insertion members 262 is attached to two endless chains 276 that move in a direction indicated by an arrow 277 in the figure. Each rod 270 to which these insertion members are attached is attached to a plurality of rollers 269 on each track 268. These tracks move along the closed circulation path of the endless chain 276. When passing through the lowermost portion of the circular track of the endless chain 276, the rods 270 to which the insertion members 262 are attached are moved outward (in the cross direction) of the chains 276 to the stop guide 56 and the guide rail 278. Move towards. A mechanism suitable for causing the movement of the rod 270 in the cross direction uses a cam follower (see FIG. 13) provided on the rod 270. The cam follower intersects a bar or rail that operates by a cam in a known manner, and operates at a predetermined position along the rail. A plurality of rollers 269 having V-shaped grooves cooperate with corresponding roller engaging members having V-shaped edges so that the rods 270 can reciprocate in a direction indicated by an arrow 275 in FIG. Has become. Referring again to FIG. 8, the insertion member 262 first engages with the carton 3 hooked by the carton supply device 50, and the cup support mechanism 52 of the supply device 50 first moves outward. The insertion member 262 is moved so as to face the insertion member 262 that has moved. The stop guide 56 attached to each of the mechanism sections 52 of the supply device supports the handle portion of the carton 3 when the insertion member 262 attempts to mount on the guide. The inserts 262 and the stop guide 56 of the feeder cooperate to promote the inserts to be fully inserted into the gripping holes of the carton and are attached to the chain so that each carton 3 Provides a positive reaction force when transferring to the downstream side. FIG. 13 shows a state where the insertion member 262 is engaged with the handle portion of the carton 3 while being guided. At this time, the carton 3 is urged toward the insertion member 262 by the guide rail 278. ing. The cooperative operation and interaction by the insertion member 262, the carton 3 and the stop guide 56 of the supply device are the same as described above. Referring again to FIG. 10, once the carton 3 has been engaged in the supply device 50 by the insert member 262, the insert device 262 enters the groove of the stop guide rail downstream. An elevation view is shown in FIG. 14 so that the above features can be more clearly understood. This figure is a view in which a protruding portion, that is, a nose portion 264 is viewed from the front of the insertion member 262. -Timing transfer section: second modified embodiment In a second modified embodiment of the timing transfer member, as shown in FIG. 39, the intermediate stop guide 280 is provided with the support mechanism section 52 and the channel-shaped guide rail 278. It is provided between. In the illustrated preferred embodiment, the intermediate stop guide 280 is comprised of two spaced bars. The bars form a channel that allows the support mechanism 52 to enter the intermediate stop guide and between the support mechanism 52 and the channel guide 278 as shown. It has become. The intermediate stop guide 280 is a combination of the functions of the stop guide 56 and the channel-shaped guide rail 278. When the grip hole of the carton is engaged with the grip hole insertion member 262 as described above, Provides a resistive surface for the carton handle section. FIG. 39 also illustrates features of the present invention that can be applied to all embodiments of the present invention. It is a tab guide 282 that receives and guides the support tabs 961, 963, 971, 973 of each carton as it is transported downstream. On both sides of the tab guide 282, a panel lower folding guide such as a bending bar commonly used in this carton field can be provided so as to engage with the panel or flap so as to bend in a required direction. . In the present invention, such a guide bends the bottom panels 910, 912 of the carton downwardly from a substantially upright position as shown in FIG. 3 to a substantially horizontal position, in which the bottom panels are gripped by the panel. It is gripped by a plurality of gripping members of an assembly (described in detail below). Referring to the bottom panel gripping member 5, in a panel gripping assembly 80, a plurality of panels gripping members, ready for loading is made open each carton 3 folded. When each carton 3 moves the timing transfer unit according to any of the above-described embodiments, a plurality of panel gripping members 82 that move on a plurality of conveyors in a transport path positioned below and parallel to the timing unit are formed. Grasp the bottom panels 910 and 912 of the carton 3 and pull out. Each of these carton gripping members 82 is a clamp that grips the bottom panels 910 and 912, respectively. FIGS. 9 and 13 show the carton 3 held by the holding members 82. As shown in FIG. 5, these gripping members 82 are attached to two sets of conveyors (endless chains) 84 and 86. The chains 84 and 86 forming each set are a pair of endless chains opposed to each other, and are located on both sides of each of the folded cartons 3 moving along the timing section. FIGS. 15 and 16 schematically show the opening operation by each member of the gripping assembly. The gripping members 82 in both sets of the gripping chains 84 and 86 move outward with respect to the center line 901 of the carton 3 as indicated by an arrow 81 in the figure. At the same time, the chains 84, 86 rotate toward the downstream indicated by the arrow 83. The plurality of gripping members 82 and chains in the first chain set 84 open each carton 3 by pulling the carton bottom panels 910, 912 outward. The first set of chains 84 and gripping members 82 open each carton from the fully folded state shown in FIGS. 9 and 13. The chain 84 in the first chain set moves at a speed relatively higher than the moving speed of the carton 3 with respect to each carton 3 when the chain 84 is moved by the transport mechanism of the nip belt 72 or the insertion member 262. . (Subsequently, the movement of each carton 3 performed by the timing transfer section is timed with the movement of each bottle in the transport path parallel to and below these cartons.) As can be seen, the carton 3 is folded to resemble a bellows of an accordion, with the front part projecting outward and the rear part folding inward. As described above, because the first set of chains 84 moves at a relatively high speed, the panels 910, 912 of the carton 3 are pulled forward faster than the panels themselves move forward. With this operation, the carton is raised in a rectangular shape, and in this state, the bottom panels 910 and 912 are located in a position side by side with the center of the carton 3. After the carton 3 has been raised at the portion of the first gripping chain 84, the plurality of panel gripping members 82 in the second set of gripping chains 86 engage the bottom panels 910, 912 of the carton 3 and The carton 3 is further opened to the maximum opened state as shown in FIGS. Also, this second chain set 86 of the gripper assembly delivers the opened carton 3 to the next carton handling section or carton lowering section 90 in the apparatus 10. The gripping members 82 and each chain 84 of this second chain set do not move faster than the carton transport mechanism and are synchronized with the nip belt 72 or insertion member 262 on the downstream side (as indicated by arrow 83). Move towards. The gripping member 82 holds the bottom panels 910 and 912 outward during movement. FIGS. 16 and 17 show the end of the opened carton 3, wherein the carton 3 is fully opened and ready to be delivered to the inclined belt assembly 90. FIG. 17 is an elevational view showing the carton 3 fully opened with the members of the nip belt assembly 70 and the panel gripping member 82 engaged. As shown in FIG. 5, a pair of conveyors in the form of an endless chain 88 operate to pass each carton 3 thus opened from the first chain set 84 through the second chain set 86. To assist. As the carton 3 exits the first chain set 84, a plurality of lugs 89 attached to the chains 88 engage the front and rear portions of each of the opened cartons, and the bottom panels 910, 912. When they are again gripped by the gripping members 82 of the second chain set 86, they serve to keep the cartons open. FIG. 18 shows a planar layout of the gripping member 82, chains 84, 86, 88, and lugs 89. In a preferred embodiment of the present invention, as the gripping members 82 move through the closing circuit by the gripping chains 84, 86, the gripping members 82 are moved outward toward the opposing set of gripping members and then the gripping members. Are moved inward (and thus out of the centerline 901 of each carton) away from the opposing set of. This movement is performed by a cam follower attached to each gripping member 82 that moves in a cam groove or cam track 292. FIG. 19 details the structure of a panel gripping member 82 suitable for use with the panel gripping assembly described above. In this gripping member 82, the upper arm 284 and the lower arm 286 form a plurality of clamping jaws. The two arms are connected to each other by a rotation shaft 283, and are in contact at a sandwiching point, that is, at pads 285 and 287 provided at the ends of the arms 284 and 286. Each of these gripping pads 285,287 is made of a material having a high coefficient of friction on the smooth surface of the carton. A preferred material is rubber. The surfaces of these pads 285, 287 can be corrugated or have a structure with ribs or other protrusions to increase friction. The arms 284 and 286 are urged by a spring 288 in a direction to close the gripping member 82. The arms 284 and 286 are attached to a track 296, and the track is further attached to a gripping member chain 84 or 86 for movement. The arms 284 and 286 cooperate with a plurality of V-grooved rollers 294 attached to the track 296 and a roller engaging member 298 having a V-shaped edge and attached to the lower gripping arm 286. It can move with respect to the track 296. A cam follower 290 is attached to the lower arm 286, and the cam follower 290 is inserted into a cam groove (or cam track) 292 that defines the movement of the arms 284 and 286. 20, 21, and 22 show how the upper arm 284 pivotally opens and closes with respect to the lower arm 286 to clamp and open the bottom panels 910, 912 of the carton 3. . 20 to 22 show the movement of the gripping member 82 when the gripping member 82 is being conveyed by the chain 84 or 86 to which the gripping member 82 is attached. These figures are viewed from the front end of the gripping member 82 toward the rear of the upper arm 284 to which the roller 300 is attached so that the state can be easily understood. When the gripping member moves in the direction indicated by the arrow 301, the rear portion of the upper portion 284 is pushed down and held for a certain time, and then the opening roller 300 returns to the uppermost position by the guide of the opening inclination member 302. The opening inclined member is a flat plate or other structure having a cross section forming a downward inclined leading edge 303 and an upward inclined trailing edge 305. Between these two inclined portions 303 and 305, a flat portion 304 for holding the jaws (arms 284 and 286) of the gripping member 82 in an open state for a short time can be provided. FIG. 20 shows a relative positional relationship between the opening roller 300 and the opening inclined member 302, in a state before the roller 300 comes into contact with the leading edge inclined portion 303. In the state shown in FIG. 21, as the gripping member 82 moves in the direction of the arrow 301, the roller 300 comes into contact with the front edge inclined portion 303 and rotates in the direction of the arrow 306. As a result, the upper arm 284 is pushed downward as indicated by the arrow 307, and the clamp jaw is opened. When the inclined member 302 is provided with the flat portion 304, the jaws of the gripping member 82 are kept open while the roller 300 is in contact with the flat portion. When the roller 300 moves along the trailing edge inclined portion 305, the jaws of the gripping member 82 are closed. Referring to FIG. 2 and FIG. 15, it can be seen that this carton 3 is provided with a plurality of nick members 929, 939 so that the folded carton can be opened in a special way. Call These connecting portions 929, 939 are weakened connecting members extending between the respective center cell corner tabs 929, 939 and the upper side wall bands 92, 3, 933. These connecting portions 929 and 939 delay the separation of the upper side wall bands 923 and 933 from the center cell bands 925 and 935. Due to this delay, the angles formed between the center cell bands 925, 935 and the center cell corner tabs 926, 936 become more acute when the carton 3 is raised. Each gripping member 82 in the first gripping member set further includes a top side 923,933 of the folded carton from both sides for pulling and opening the carton when each gripping member contacts each bottom panel 910,912. A hook-shaped member to be engaged may be provided. This hook-shaped member is, for example, a band hook extending from the top of the gripping member 80. The band hooks contact each top band 923,933 of the carton as the bottom panels are gripped, respectively. The hooks provided on the paired and opposed gripping members 80 in the first gripper are offset to prevent interference with each other. Additional guide structures may be provided to assist in maintaining each carton in a "raised" state and holding its bottom panel in a horizontal position. A suitable guide, not shown, is an L-shaped elongated member extending forwardly with respect to the device. In this case, the right angle formed at the intersection of the vertical side wall and the horizontal bottom panel abuts the right angle corner of the L-shaped guide. Each guide is aligned along the carton and on both sides of the device. Each guide extends slightly outward from the center of the gripping device in the second set of gripping devices, and as described above, when the gripping members are pulled further outward to form the sloping corners of the carton as described above. Allowance is made for the additional width of the resulting carton. Bottle Distribution and Transport As described above, each bottle supplied from the bottle supply conveyor is grouped by the star wheel 105 so as to be loaded into each carton. After being grouped, these grouped bottles are conveyed at timely intervals via a conveyor 106 moving below the bottles and a bottle gripping conveyor 112 abutting on the side of the bottles. As shown in FIG. 23, the bottle transport conveyor 106 includes a pair of endless chains 107 separated from each other, and a plurality of bottle lugs 108 are mounted on these endless chains. The side surface of each bottle lug contacts a pair of bottle support rails 109. These rails 109 function as ledges that support the bottom periphery of each bottle. These lugs 108 abut the last bottle in the bottle row forming the bottle set. Although it is possible to have only one lug in contact with the last bottle in each row, the lugs 108 are configured in pairs, so that contact with the bottle is more stable because the lugs contact the bottle at two points. It will be. Slots or gaps 110 extending longitudinally between the two chain structures provide passageways for the tabs 961, 971, 963, and 973 as each carton is lowered onto the bottle set. This configuration will be described later in detail. Referring to FIGS. 5, 24, and 25, each bottle is maintained in pairs and spaces distributed by the star wheel 105 by a pair of bottle gripping conveyors 112. Each bottle gripping conveyor 112 transports each bottle in conjunction with the above-described bottle engaging conveyor. Each bottle holding conveyor 112 has a plurality of bottle holding members 113 attached to the endless chain 111. Each bottle gripping member 113 is a block-shaped member having a series of C-shaped recesses for receiving the bottle 1. The number of C-shaped recesses corresponds to the number of bottles in each row of the bottle set stored in the carton 3. For example, a carton for six packs has three rows in each row, and a carton for eight packs has four rows in each row. In the present invention, a single chain 111 is used to circulate the bottle gripping members 113 and always direct the bottle gripping members 113 toward the center of the apparatus 10. Referring particularly to FIG. 24, which is an elevational view from the rear of the gripping member 113, the upper surface of each gripping member 113 and the end of the gripping member 113 which is rotatably attached to the bottle gripping chain 116 and On the opposite side end, a cam follower 114 is provided. In particular, as shown in FIG. 25, the lower portion of each gripping member 113 is rotatably attached to the gripping member chain 111. The cam follower 114 of each bottle gripping member is engaged with a cam track (or a cam groove) so that the bottle gripping member 113 faces inward when the gripping member 113 moves along the closing path of the chain 111. Maintain the state that was. When the chain 111 rotates the gripping member 113 around the chain wheel 117, the sprocket 116 guides the cam follower 114. Due to the engagement of the cam follower 114 with the sprocket 116 and the rotatable connection 118 of the follower 113 to the chain 111, when the gripping member chain orbits the gripping member around the chain wheel 117, The orientation of the gripping member 113 is maintained. Each carton 3 opened in the carton lowering section is lowered in its course toward the upper part of each set of bottles 1 moving on a transport path located below and parallel to the transport path of these cartons 3. As shown in FIGS. 5 and 26, the lowering of the carton is performed by a combination of the inclined belt assembly 90 and the upper inclined block assembly 100. The carton 3 that has been raised is in an upright state with respect to the bottom panels 910 and 912 extending outside the center line 901 of the carton 3 when passing through the nip belt assembly 70 and the gripper assembly 80. Has become. The carton 3 is directed to the inclined assembly when passing through the gripping members 82 attached to the nip belt assembly 70 and the second gripping chain 86. In the inclined assembly, the developed bottom portions 910 and 912 are respectively left and right. It is received by a pair of inclined belt pairs 92, 94 and 93, 95. As schematically shown in FIGS. 5 and 26 and in detail in FIGS. 27 and 28, each belt pair 92, 94 and 93, 95 of the inclined belt assembly 90 has a carton 3 passing between each belt pair. So they are separated. Here, for convenience, the upper belt 92 and the lower belt 94 constituting one pair are referred to as a “right” inclined belt pair, and the upper belt 93 and the lower belt 95 constituting the other pair are referred to as a “left” inclined belt pair. Each of these four belts 92, 93, 94, 95 is an endless belt. The gap between the opposing surfaces of each pair of belts is intended for insertion. The opposing surfaces of each belt pair 92, 93 and 93, 95 are positioned sufficiently close so that the panels 910, 912 of the carton 3 are firmly sandwiched between each of these moving belt pairs. Thereby, each carton 3 is transported along the device 10 by these moving belts. Although the schematic configuration of the belt assembly 90 has been described above, it will be understood that an endless belt moving means known to those skilled in the art is used. For example, a circulating roller mechanism 91 disposed at both ends of each track of the belt is used. The circulating roller mechanism includes a plurality of additional rollers disposed between both ends of the track so that both belts facing each other (as shown in FIG. 9 showing the plurality of rollers 74 of the nip belt assembly 70). Maintain face-to-face contact. The movement of these belts 92, 94 and 93, 95 is synchronized with the movement of the bottle assembly transport mechanism (ie, the bottle gripping conveyor 112). Each carton 3 is received on the inclined belt such that the carton 3 is put on each bottle set 5. In particular, in the side elevational view of FIG. 26, the optimum inclination angle of the pair of the belts 92 and 94 (and the belts 93 and 95 parallel to the belts 92 and 94 and not visible in FIG. 26) with respect to the horizontal plane of the bottle set 5 A indicates that it is 4 °. Each carton 3 is gradually covered by each bottle set 5 by the inclination of these inclined belts 92, 94 and 93, 95. The lowering operation of each carton 3 is assisted by the upper inclined block assembly 100. In the assembly 100, a series of handle engaging blocks 102 are attached to an endless chain, and the chain engages with each of the inclined belts to be driven synchronously. As shown in FIG. 27, each of the blocks 102 is formed with a groove or slot 103 for receiving the handle of the carton 3. The upper assembly includes the inclined belts 92, 94 and 94 such that the top of the carton 3 or handle top engages the groove or slot 103 as each carton is moved by the belts 92, 94 and 93, 95. It is arranged with respect to 93 and 95, and stabilizes and reinforces the movement of each carton moving downward. The blocks may be spaced apart in synchronization with each other, but in the simple configuration shown, the blocks 102 are adjacent to one another to form a substantially continuous groove or slot. . FIG. 28 shows another configuration example of the inclined belt assembly 90, which is formed between each bottom panel 910, 912 of the carton 3 and a side wall adjacent thereto in order to further stabilize the movement of the carton 3. Guides 98 and 99 are provided at positions where they come into contact with the bending lines. These guides 98, 99 are parallel and extend the same length as the belts 92, 94 and 93, 95 in the longitudinal direction. These guides 98 and 99 further assist the lower part of the carton 3 and thereafter, and in the lower part and thereafter, each carton 3 becomes more stable. For best performance and reliability, especially when the carton is completely laid over the bottle set 5, each carton should be positioned before the carton panels 910, 912 exit the inclined belts 92, 94 and 93, 95. And before the handle portion exits the upper ramp block 102. The carton 3 is completely covered on the bottle set 5 at the mounting wheel assembly 120 located below the inclined belt assembly and the upper inclined block assembly 100. Each carton 3 and bottle set 5 exits the inclined belt assembly 90 and upper inclined block assembly 100 as one unit 6 (FIG. 26). The carton bottle unit 6 is a package in which the fully started carton 3 is almost completely mounted on the bottle set 5 but is not completely mounted. Moreover, the carton 3 is inclined with respect to the bottle set 5 because the carton 3 is installed at an angle with respect to each bottle set 5, but the carton exits the inclined portion. At this time, the last part of the handle of the carton is placed horizontally in contact with the last one of the inclined blocks 102. In FIG. 30, the mounting wheel assembly 120 has a ferris wheel-like structure, and a plurality of mounting blocks 122 are mounted on a rotating wheel or drum 124 such that the blocks 122 (ie, handle receiving grooves) always face downward. ing. Therefore, all of the mounting blocks 122 remain in the same direction even while moving on the rotation track of the wheel 124. Each mounting block 122 is rotatable with respect to the wheel 124 by appropriate means for maintaining the orientation of the mounting block 122 even when the wheel 124 rotates. This configuration is shown schematically in FIG. The means for keeping the orientation of the mounting block 122 constant is shown in detail in FIG. FIG. 30 shows a planetary gear system used for holding the mounting block downward. In FIG. 30, each mounting block 122 is attached by a well-known mechanical method to each "planet" gear 127 that goes around a centrally located "sun" gear 126. Each of the mounting blocks 122 has a handle portion receiving groove or slot 123 similar to the handle portion receiving groove or slot 103 of the upper inclined block 102. Since the handle receiving portion 123 of this mounting block 122 cannot be shown completely in FIGS. 5 and 26, both blocks 102, 122 may look identical in this regard. The rotation of the wheel 124 is synchronized with the movement of the carton bottle unit 6 such that the mounting block 122 engages the handle portion of the unit 6 to which the mounting block 122 is continuously fed. The movement of the wheel 124 and the carton bottle unit conveyor is such that when the handle of the carton bottle unit 6 intersects the angled trajectory of the wheel 124, the handle receiving portion 123 of the mounting block 122 Synchronized to come to the position. Therefore, after the mounting block 122 engages the handle of the carton, the rotation of the wheel moves the block 122 both downward and forward. This completes the placement of the carton 3 with respect to the bottle set 5, and the carton 3 is completely “attached” to the bottle set 5. The unit consisting of the bottle set 5 and the fully loaded carton 3 is designated by the numeral 7 in FIG. Instead of the handle portion of the carton, the panel may be biased so that if the bottle abuts against the mounting block 122, the resistance pushes the mounting block back in the direction of the contact point. . This prevents damage and malfunction when a bottle that is not arranged in the normal state collides with the mounting block 122. 26 and 27 show a set of bottles 1 arranged in 2 × 3 rows. That is, there are a total of six bottles 1 for each set. However, as already mentioned, the system according to the invention works well when packing other numbers of bottles. In order to emphasize this point, both the six embodiments and the eight embodiments are shown in the description and drawings according to the preferred embodiments. For example, the plurality of bottle gripping members 113 shown in FIG. 5, which is a schematic perspective view, are provided for eight sets. On the other hand, in the other drawings, the carton 3 and the bottle set are shown for six sets. The principles of the present invention are equally applicable to both the six-set and eight-set forms, as well as to other set forms. Referring to FIG. 29, in a variation of the top ramp block, the ramped bottom walls 101a of the block 102a face a groove or slot 103a for receiving a carton handle. Referring to folding and sticking device 5 again, each package (unit), wherein leaving the mounting portion 120 of the device 107 is then engaged with the package lug assembly 130. The package lug assembly 130 mainly includes a pair of endless chains 132 opposed to each other, and a plurality of lugs 134 engaging with each package 7 are attached to each of the endless chains. The closing of the carton 3 of each package 7 takes place at the folding and sticking section 140 of the device 10 while the packages are being moved by the package lugs 134. In particular, FIG. 31 shows a fold-and-stick assembly 140 of the apparatus for loading a bottom-loaded basket carton 10 according to a preferred embodiment of the present invention. The sticking operation will be described later, but in order to make it easier to understand, the glue is applied to the inside of the so-called larger bottom wall panel 912 of the carton 3 (that is, the side facing inward of the carton 3 that has been set up). ) Glue is applied and riser panel support tabs 961, 963, 971, 973 are affixed to the inside of the larger bottom wall panel 912. If the carton does not have the support tabs 961, 963, 971, 973, it is of course unnecessary to fold and stick them. Each member of the bending and sticking assembly 140 is arranged to sequentially bend each part of the carton 3. Reference is made to FIG. 31 and also to FIGS. FIGS. 32 to 35 additionally show any of the previously described figures showing the features of the folding and sticking assembly and panels 910, 912 and support tabs 961, 963, 971, 973. is there. The main part of the folding device 140 involved in folding engages with the corresponding panels and flaps of each carton 3 when each package 7 is moved in the direction indicated by the arrow 71 by the package lugs 134. It is a stationary member. As the package approaches this fold, the bottom panel flaps 910, 912 are tilted to a substantially horizontal position rather than hanging down. The bottom panels 910, 912 are first bent vertically downward at this fold, and then to face the lower part of the carton 3, ready for the subsequent fixing stage. Each support tab 961, 963, 971, 973 is bent to a horizontal position. These support tab bending members are housed inside what is conventionally called a tab bending block 141. As with the carton tilting operation described above, the first of the two bottom panel flaps 910, 912 to be engaged is the larger bottom panel flap 912. This larger panel flap 912 contacts the inclined edge of the first vertical panel folding wedge member 162 and is bent vertically downward. The first vertical panel folding wedge member 162 folds the larger panel 912 to a hanging position, where the panel 912 is sandwiched between the wedge member 162 and the folding block 141. Folding block 141 provides edges and surfaces that separate the support tabs and fold to predetermined locations and spaces to receive the respective support tabs. Each pair of long and short support tabs 961, 971 and 963, 973 at both ends of the carton simultaneously engage with the block 141 (in FIG. 3, the long support tab 961 and the short support tab 971 are present Is the leading edge). In particular, as shown in FIG. 34, when viewed from the front of the support block 141, the right side of the block 141 is shaped to engage with the longer tabs 961 and 963, and the left side is the shorter tab. 971 and 973 are engaged and enter. The horizontal cut surface 142 and the vertical cut surface 143 form a long tab, ie, a wedge-shaped recess 150 for the main tabs 961, 963. The recess 154 for the sub-tab is formed by the inclined cut surface 152 and the vertical cut surface 153. As the carton moves, the main support tabs 961 and 963 are separated from the sub support tabs 971 and 973 along the edge 155. The front main tab folding edge 155 crosses the rear main tab folding edge 144 so as to be continuous. The rear main tab bent edge 144 is formed at the intersection of the main tab vertical cut surface 143 and the main tab upper inclined surface 145. As the carton 3 moves, the main support tabs 961, 971 split upward along the front main tab folding edge 144. The main tab inclined surface 145 and the front main tab bent edge 144 also divide outward and upward, so that the main support tabs 961 and 963 eventually move in contact with the main tab inclined surface 145. It will be. The further movement of the carton eventually brings the main support tabs 961, 963 into contact with the horizontal surface 156 of the folding block. As described above, the main support tabs 961 and 963 are bent to the right of the bending block 141, while the sub support tabs 971 and 973 are bent to the left. The sub-tab recess 154 of the block 141 provides space for the sub-tabs 971, 973 that are initially separated from the main tabs 961, 963 of the carton 3. The minor tabs 971, 973 initially engage the minor tab folding front edge 160. The front edge 160 for folding the sub-tab is formed at the intersection of the vertical cut surface 147 for the sub-tab and the inclined surface 145 for the main tab, and intersects the rear edge 148 for folding the sub-tab. The sub tab bending rear edge 148 is formed at the intersection of the sub tab vertical cut surface 147 and the sub tab inclined surface 149. The sub-tabs 971, 973 are moved outward and upward relative to the carton 3 by this outwardly and upwardly diverging edge 148. When the carton 3 moves further downstream, the sub-tabs 971 and 973 come into surface contact with the sub-tab inclined surface. From the point when the carton 3 starts to move on the folding block 141, each bottle in the carton is supported at its lower part by the support bar 158. When the carton package 7 reaches the horizontal plane 156 of the folding block, the main tabs 961 and 963 and the sub tabs 971 and 973 are bent outward until they come into surface contact with the lower surface of each bottle 1 of each package 7. Have been. When the package 7 is transported further downstream by the conveyor, glue is applied to the larger bottom wall panel 912 extending downward as described above by well-known means such as a glue gun. You. The glue is provided with support tabs 961, 963, 971, 973 which are to be attached to the larger panel 912 when the larger panel 912 is bent upward to a position facing the bottom of the package 7. It is attached to the center of a suitable part to be attached. Gluing is performed at an appropriate position such as a gluing recess 157 shown in the figure. Referring particularly to FIGS. 31 and 35, after gluing to the bottom panel 912, the bottom of the carton 3 will be closed and fixed in the next step. A dead plate 161 following the folding block 141 is a suitable stationary surface on which the package 7 is placed, so that each bottle 1 in the package can be slipped by the package being transported. Has become. As described above, the second vertical panel folding wedge 164 engages the smaller bottom wall panel 910 in the same manner as when the first panel folding vertical wedge 162 has folded the larger panel 912. And fold it down. These large and small bottom panels 912 and 910 are sandwiched between the first and second panel bending wedges and the flat plate 161 respectively. A first panel folding horizontal wedge 166 and a second panel folding horizontal wedge 168 fold each bottom panel 912, 910 to a closed position where they face each other. As shown more clearly in FIG. 35, the first panel folding horizontal wedge 166 is longer than the larger glued panel 912, and the first panel folding horizontal wedge 166 is turned on before the smaller bottom panel is operated. Engage with panel 912 and fold the panel down. Thus, the smaller bottom panel 910 is the outermost position of the two bottom panels. Subsequent to the flat plate 161, a bottom wall sealing plate 170 having a surface 174 is provided. On this surface 174, the support tabs 961,963,971,973 and the larger bottom panel 912 with glue are pressed against each other, whereby each support tab 961,963,971,973 is pressed by the panel 912. Affixed to The package 7 can be mounted on the sealing plate 170 without being caught by the inclined lip 172 provided at the front portion of the sealing plate 170. The inclined lip 172 of the sealing plate 170 is positioned lower than the flat plate 161 and the folding horizontal wedges 166, 168 so that the package can smoothly transition from the flat plate 161 to the sealing plate 170. Further, the plate 170 itself is sufficiently close to the flat plate 161 so that the bottoms of the bottom panels 910 and 912 abut on the inclined lip 172 without being caught. The side walls 176 of the sealing plate 170 press the side walls of the carton 3 inward to a predetermined position, so that the packages 7 to be conveyed are properly aligned during the conveyance. The front of the side walls 176 is also sloped inward to guide the package between the side walls 176 on the sealing plate 170. Method for closing the bottom of the closed carton 3 of the carton are several. For example, the bottom panels 910 and 912 are attached to each other. Another effective closure technique uses a locking mechanism known as "punch lock" in the packaging field. In this locking mechanism, a plurality of male fastening members are provided at the outermost portions of the two bottom panels, and a female opening formed on the inner bottom panel corresponding to the male fastening members and overlaid with the male members. Or a member is provided. If the carton is particularly closed by such punching, the two bottom panels 910, 912 are pulled inward to align the locking positions of the two in order to effectively close the bottom of the carton 3. You can also do so. This is particularly useful and necessary for engaging the male and female structures, and also allows the raised carton 3 to be in an optimal condition in which the bottom panels 910, 912 overlap by a predetermined dimension. Help. As shown in FIG. 36, the bottom panels 910, 912 are pressed into a predetermined surface contact alignment with each other by a plurality of lug sets 182 attached to the conveyor of the bottom panel alignment assembly. These lug sets 182 are engaged with a plurality of pull holes (alignment holes or holes) 914 (see FIG. 3) formed in both bottom panels 910 and 912 of the carton 3. Each lug set 182 includes a movable lug member 184 and a stationary lug member 186 that are biased outward. This outward bias is performed by a spring 196 shown in the figure or another suitable biasing mechanism. A pair of lug sets 182 facing each other are attached to a pair of support rods 190. Each pair of these lug sets 182 is attached to a conveyor such as an endless chain 188. The movable lug member 184 in each set is spring-biased outward, and moves inward along the support rod 190 by moving along the cam rail 192. The movable lug member 184 of each lug set 182 is at the retreat position before moving inward along the inclined surface 194. The movable lug member 184 is in the retracted position (that is, before climbing the inclined surface 194), and the lug set 182 is engaged with each of the extending holes 914 of the carton 3 in the initial stage. Each movable lug member 184 has an angular projection 185. The projecting portion corresponds to the vertex of the triangular hole 914, and fits exactly into the vertex. Each of the fixed lug members 186 has a lip-shaped ridge 187. This ridge corresponds to the bottom of the triangular hole 914 and fits exactly into the bottom. As described above, both bottom panels 910 and 912 of the carton 3 are in a state where they face each other while partially overlapping each other when the package 7 exits the folding and gluing section 140 of the device 10. Have been. As each of the movable lug members 184 moves along the front inclined surface 194, the movable lug members 184 draw the both bottom panels 910 and 912 inward to a predetermined position. At this time, each fixing lug member 186 acts to prevent the bottom panels 910 and 912 from being pulled too much inward. The front inclined surface 194 for the movable lug 184 may be formed in two steps by a well-known method, in which case the front and rear movable lug members move inward almost at the same time, and the bottom panels 910 and 912 are moved. The "scissoring" effect of pulling together can be prevented. With this configuration, the cam follower of the front movable lug member engages only with the upper inclined surface. The inclination of the upper inclined surface is steeper than that of the lower inclined surface. Only the cam follower of the rear movable lug member comes into contact with the lower inclined surface of the small inclination. Since the pitches of these two inclined surfaces are different, the inward movement of the front lug member is started after the rear lug member also moves inward. After the bottom panels 910, 912 have been tightened a predetermined amount and held in place by the lug set 182, the punching structure is engaged by a plurality of well-known rotating fingers 200. The rotating fingers simultaneously project upwardly through the alignment assembly 180. The movable lug member 184 can retreat to the outermost position by the inclined surface 195 at the rear end (exit end) of the cam rail 192. Thereafter, each of these completely closed packages 7 is discharged from the device by known means. As shown in FIGS. 37 and 38, when both bottom panels 910, 912 of carton 3 are pulled together, the top of each bottle engages each belt 402 of bottle stabilization assembly 400. These belts 402 rotate at the same speed as the carton in the same direction as the carton transport direction. The bottle stabilizing assembly 400 prevents the bottle from popping out of the carton when the bottom panels 910, 912 are pulled together as described above. Modifications of the above embodiments are possible without departing from the scope and spirit of the claimed invention.

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Date of Submission] May 19, 1997 [Details of Amendment] After the international application specification, page 2, line 22 (Japanese translation, page 2, line 15), the following sentence was added after a line break. `` In another aspect of the present invention, there is provided a tightening device for simultaneously pulling a plurality of panels forming a carton and having an alignment opening while the carton is moving along a predetermined path, the device comprising: Comprising a conveyor operatively synchronized with the carton, and a plurality of pairs of opposing lugs, each lug set being operatively connected to the conveyor, wherein each lug set comprises a fixed lug member, a movable lug member, The movable lug member is reciprocally movable in a direction intersecting with the conveyor with respect to the fixed lug member between a retreat position and a predetermined extended position. The movable lug members are engaged with the respective alignment openings when the movable lug members are in the retreated position, and then the respective lug members are directed toward the corresponding lug sets in the plurality of pairs of lug sets. In the above aspect of the invention, when the fixed lug member is located at the predetermined extended position, the movable lug member is located at the predetermined extended position. And a lip portion that contacts a part of the positioning opening, which prevents the panel from being detached from a predetermined path. The opening may have a triangular shape, and the movable lug member and the stationary lug member may each have a shape corresponding to a part of the positioning opening with which the lug member engages. Further, the positioning opening has a triangular shape pointing inward with respect to the center line of the carton, and the movable member corresponds to the triangular shape. Or as having a corner portions. Furthermore, the fixing lug member may be a structure having a lip extending upward. "2. The claims were amended as shown in the attachment. Claims 1. A fastening device (180) for simultaneously pulling a plurality of panels (910, 912) comprising a carton (3) and having an alignment opening (914) while the carton is moving along a predetermined path; the carton and the synchronous operation to the conveyor (188) comprises comprises a lug sets (182) a plurality of pairs of each lug set facing formed by operatively connected with said conveyor, wherein the respective lug sets (182) has a fixing lug member and (186) and the movable lug member (18 4) respectively, said movable lug member (184) is with respect to the fixing lug member between a departure position and a predetermined extended position (186) is a reciprocable in exchange difference direction of the conveyor (188), and wherein each lug set (182) is initially in the case the movable lug member (184) is located before Symbol retreat position At each of the alignment openings (914) , and then moves inward in the cross direction to the predetermined extended position toward the corresponding lug set in each of the plurality of pairs of lug sets (182) . A fastening device configured as described above. 2. In the clamping device according to claim 1, wherein the fixing lug member (186) is, when the movable lug member is located in said predetermined extended position, the lip portion (187 in contact with a portion of the alignment apertures ) with a tightening only member, characterized in that said panel by said lip portion (187) is prevented from being disengaged from the predetermined path. 3 . 3. The fastening device according to claim 1 , wherein each of the positioning openings (914) forms a triangle, and the movable lug member (184) and the fixed lug member (186) engage with each other. A shape (185, 187) corresponding to a part of the positioning opening (914) . 4 . In the clamping device according to any one of claims 1 to 3, wherein the positioning apertures (914) has a triangular shape pointing inward with respect to the center line of the carton, said movable member ( 184) has a corner (185) corresponding to the triangular shape. 5 . 5. The tightening device according to claim 1 , wherein the fixed lug member (186) comprises a lip (187) extending upward.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), AU, BG, BR, C A, CN, CZ, FI, HU, JP, KR, MX, NO , NZ, PL, RO, RU, SG, SK, TR, US

Claims (1)

[Claims]   1. The panels that form the carton and have multiple alignment openings A clamping device for simultaneously pulling the carton while moving along a predetermined path; ,   A conveyor operating synchronously with the carton;   And a plurality of opposing lug sets,   Each of the lug sets has a fixed lug member and a movable lug member. The lug set is such that the movable lug member is fixed between the retreated position and a predetermined extended position. The conveyor so that it can reciprocate relative to the lug member in a direction crossing the conveyor. Operatively connected to the bearer,   First, each of the lug sets is configured such that each of the movable lug members corresponds to each of the fixed lug members. Engages with each of the alignment openings when in the retracted position, and then For the corresponding lug set in each of the plurality of lug sets, the predetermined A clamping device configured to move inward in the cross direction to an extended position.   2. 2. The tightening device according to claim 1, wherein each of the positioning openings has a triangular shape. And the movable lug member and the fixed lug member It has a shape corresponding to a part of the positioning opening with which the lug member engages. And a fastening device.   3. The fastening device according to claim 1, wherein the alignment opening includes the opening. The movable member has a triangular shape pointing inward with respect to the center line of the carton. A fastening device having corner portions corresponding to the triangular shape.   4. The fastening device according to claim 1, wherein the fixed lug member extends upward. A fastening device comprising a protruding lip.