Inclined tray bottle traying machine

A method and apparatus are provided to sequentially capture the lead bottle from a row of bottles in a multi-pocketed bottle indexing wheel means, and sequentially rotate and push pocketed bottles from said index wheel means to an inclined traying means, automatically collecting said bottles in a gravity compressed hexagonal pattern within said inclined traying means. Inclined traying means includes a means for trayed bottle removal.

FIELD OF THE INVENTION 
The present invention relates to automatic bottle tray loading machines of 
the type adapted to collect bottles in storage trays primarily in the 
pharmaceutical, food and cosmetic industries. 
More particularly, the present invention relates to a novel automatic 
bottle inclined tray loading machine which will collect bottles in a 
gravity compressed hexagonal pattern within a bottle tray to minimize 
storage space and lessen damage due to subsequent bottle tray handling. 
DESCRIPTION OF PRIOR ART 
Prior art including Norquist U.S. Pat. No. 2,698,693 teaches horizontal 
bottle off loading with orthogonal bottle patterning, in a machine that 
uses tangential pusher plates to push a row of bottles into a collection 
area. In similar fashion, International Machinery U.S. Pat. No. 2,909,944 
segregates a row of bottles from a conveyor by using a linear tangential 
force against said bottles in a feed direction perpendicular to said 
conveyor for horizontal orthogonal bottle collection. Gordon U.S. Pat. No. 
3,570,211 and Thornton U.S. Pat. No. 3,618,288 use a similar technology. 
Green et al U.S. Pat. No. 3,708,947 teaches a horizontal bottle traying 
machine with a complex tangential bottle row feeding mechanism, however, 
with hexagonal patterned bottle capability. Smith et al U.S. Pat. No. 
#5,477,663 teaches a complex pick and place mechanism to select a linear 
group of bottles from a row of bottles and transfer said linear group of 
bottles to a tray. 
DESCRIPTION OF PRIOR ART, CONT'D 
The present invention provides a multi-pocketed indexing wheel means to 
sequentially capture the lead bottle from a row of bottles, transport 
individually pocketed bottles to a tangential exit means, and to 
sequentially exit and push said bottles onto an inclined traying means 
where bottles are automatically gravitationally compressed into a 
hexagonal pattern. The present invention provides a tray loader which 
affords bottle control and stability far in excess of prior art. 
Additionally, the tray loader of the present invention comprises a vastly 
simpler machine than that of the prior art, substantially using one moving 
part--the indexing wheel means--to capture and supply bottles to the 
passive inclined traying means. 
SUMMARY OF THE INVENTION 
It is a principle object of the present invention to automatically collect 
bottles in a gravitationally compressed hexagonal pattern in an inclined 
traying means. 
It is a principle object of the present invention to sequentially capture 
the lead bottle in a row of bottles within a multi-pocketed indexing wheel 
means, transport individually pocketed bottles to a tangential exit means, 
and to sequentially exit and push said bottles onto an inclined traying 
means. 
It is a principle object of the present invention to provide a maximum 
filled bottle tray to minimally optimize space requirements for tray 
storage. 
It is a principle object of the present invention to provide a maximum 
filled bottle tray to minimally optimize bottle motion and damage during 
filled tray handling and storage. 
It is a principle object of the present invention to provide a bottle 
traying means with an open narrow lower single bottle entry end, and a 
larger elevated bottle exit end. 
It is a principle object of the present invention to impart an agitating 
force to gravitationally compressed trayed bottles as each new bottle 
enters the open narrow end of the provided bottle traying means. 
According to these and other objects of the present invention, there is 
provided a novel method and apparatus for traying bottles. The method 
comprises sequentially capturing the lead bottle of a row of forward 
resilient moving bottles, as provided from any source, in a multi-pocketed 
indexing wheel means, transporting individually pocketed bottles to an 
exit means, and to sequentially exit and push said bottles from said exit 
means to an inclined traying means wherein bottles are gravitationally 
compressed into a hexagonal pattern for removal and storage.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring now to FIG. 1 which shows an isometric drawing in schematic form 
of a preferred embodiment, apparatus for automatically traying bottles in 
a gravity compressed hexagonal pattern. By a hexagonal pattern, it is 
meant that the bottles are arranged in a multi row array whereby the 
bottles in each row are out of registration with the bottles in each 
succeeding row by a width of one-half of a bottle and such that when 
viewed from above two adjacent bottles in one row, three adjacent bottles 
in the next row and two adjacent bottles in the third row form a hexagonal 
pattern. 
Single inclined tray machine 1 includes a main deck 3 and a lower deck 4 
supported by a machine frame 2 such as corner legs. Bottle infeed guides 5 
receive bottles 10 from an outside source as indicated by the arrow in 
FIG. 1. Bottle infeed guides 5 serve to align a plurality of bottles 10 in 
a single column and feed the bottles 10 one at a time to a multi-pocketed 
index wheel 6. Index wheel 6 comprises a circular member having a 
plurality of spaced cutouts or pockets 16 within and around the periphery 
thereof. Index wheel 16 fits within a circumferential guide 20 having a 
substantially circular opening 17 therewithin. 
An electric motor 9 is used to rotate index wheel 6. This may be 
accomplished using a drive sprocket 15, a belt 11, another sprocket 8, and 
a shaft 7 which are operatively connected between motor 9 and index wheel 
6. A switch box 12 may be used to control the operation of motor 9. 
Index wheel 6 includes two active positions, a bottle infeed position 13 
and bottle exit position 19. In operation, a plurality of bottles 10 are 
feed into and aligned within infeed guides 5, the feeding being 
accomplished by the resilient force of each bottle 10 against each other 
as they advance within infeed guides 5. The lead bottle is feed into 
infeed position 13. Rotation of index wheel 6 moves the lead bottle to an 
intermediate position 14 at which time another bottle 10 is feed into the 
infeed position 13. Further rotation of index wheel 6 moves the lead 
bottle 10 to the exit position 19 and the process repeats itself. The 
circumfrential guide in conjunction with the opening 17 and the cutouts 16 
in index wheel 6 retains each bottle 10 within its respective cutout 16 as 
index wheel 6 rotates. A bottle exiting guide 18 is attached to main deck 
3 and arranged relative to index wheel 6 such that when a bottle 10 
reaches exit position 19, contact is made with exit guide 18 which forces 
the bottle 10 out of its cutout 16 and into the entrance to exiting guide 
22. 
Exiting guide 22 comprises a pair of parallel arranged members having a 
space comprising a track 21 therebetween which is approximately equal to 
the width of one bottle 10. As each succeeding bottle 10 exits from index 
wheel 6, it pushes the previous bottle along the track 21 within exiting 
guide 22. Upon reaching the end of the track 21 between guides 20, the 
advancing bottle 10 exits track 21 and enters the tray entrance 26 to 
inclined tray 24. Continued operation of index wheel 6 causes the feeding 
of more and more bottles into index wheel 6 and into the inclined tray 24. 
As shown in FIG. 1, inclined tray 24 is inclined at an angle relative to 
the plane of index wheel 6 and main deck 3. Such inclining causes the 
bottles 10 within inclined tray 24, due to their weight and the natural 
action of gravity, to form a compressed array of bottles toward the 
lowermost point of the inclined tray 24, the lowermost point being the 
entrance 21 to inclined tray 24. The use of delta blocks 27 allows the 
bottles entering inclined tray 24 to spread out to the sides of tray 24 
thus, when an additional bottle is forced into tray 24, it necessarily 
pushes against the gravitational force of the other bottles in tray 24 
causing each bottle to seek a gravity induced patterned position which is 
thereafter maintained by the force of gravity. The patterned array 
comprises the above described array where each row of bottles in tray 24 
are out of registry with an adjacent row by the width of one half of a 
bottle and whereby adjacent bottles 10 in three adjacent rows form a 
hexagonal pattern and whereby the bottles 10 nest within the crevices 
formed by adjacent bottles in each row. Each bottle 10 entering the 
inclined tray 24 imparts an upward agitating force relative to the other 
bottles 10 within tray 24 which due to their weight and the gravitational 
force compresses the array of bottles 10 into the most compact arrangement 
possible comprising the out of registry of each row and the nesting of 
each bottle in the crevice between adjacent bottles in the above and below 
rows. 
From the aforementioned description it will be understood that bottles 10 
received from the bottle entry position 13 of index wheel 6 are pushed 
from the bottle exit position 19, through guides 22 and into the inclined 
tray 24 where the bottles are automatically compressed by gravity. When 
inclined tray 24 is filled, the tray is removed and replaced by an empty 
inclined tray which then becomes filled and the process repeats itself. 
In FIG. 2, another embodiment of the present invention is shown. The 
embodiment of FIG. 2 utilizes two inclined trays 24 in conjunction with a 
single index wheel 6. In this embodiment, the exit position of index wheel 
6 is at the three and nine o'clock positions of index wheel 6. 
Accordingly, stationary exit guides 18 are positioned at the location of 
cutouts 28 and 29 in FIG. 2. In this embodiment, index wheel 6 is capable 
of rotating in a clockwise and a counter clockwise direction. The 
clockwise direction being used to fill tray 24A; the counter clockwise 
direction being used to fill tray 24B. Of course, one tray is filled at 
one time and when filled, the direction of index wheel 6 is reversed to 
fill the other tray. The filled tray is removed and replaced by an empty 
tray while the other tray is being filled. Otherwise the embodiment of 
FIG. 2 is the same as that of FIG. 1. 
FIG. 3 depicts the unique tray 24 used in the two embodiments discussed 
above. Inside member 30 includes a bottom 31, sides 32 and delta blocks 
27. The opening 26 between delta blocks 27 provide for the entrance of 
bottles 10 into inclined tray 24. Outside member 35 includes a back 34, 
sides 33 and a bottom 36. The distance between sides 33 is slightly more 
than the distance between sides 32 such that outside member 35 can 
telescope relative to inside member 30 and vice versa. Inclined member 37 
may or may not be fixedly attached to outside member 35. The advantage 
provided by the telescopic action of members 30 and 35 is that upon inside 
member being filled with bottles 10, the bottles 10 may be transferred to 
outside member 35 for subsequent operations.