IE46310B1 - Bottle-orienting and conveying apparatus - Google Patents

Abstract

The bottle transport equipment has a guide mechanism (10, 12) directing the incoming bottles forward, with their mouths towards the front or the rear. An inverting mechanism (13) works with the guide mechanism, being situated downstream of it, and distinguishes bottles with mouths towards the front, inverting these so that instead they face to the rear. Downstream of the inverter mechanism is an extractor mechanism (23, 32) receiving all bottles passing through it. The inverter mechanism has grips (14) engaging by friction with opposite sides of the incoming bottles.

Description

The invention relates to bottle-orienting and conveying apparatus.

According to the invention there is provided bottle-orienting and conveying apparatus comprising: supply means adapted to receive randomly oriented bottles and to discharge them therefrom in a pressurized column of bottles in random open-end-leading and open-end-trailing dispositions; guide means adapted to receive bottles from said supply means and to advance said bottles in random open-end-leading and open-end-trailing dispositions, said guide means including a chute positioned downstream of said supply means for receiving said pressurized column of bottles and a pair of spaced, driven, contra-rotating timing rollers positioned adjacent the downstream end of said chute and frictionally engageable peripherally with opposite sides of the leading bottle in said column so as (in use) to successively discharge bottles from said chute in a timed sequence; means adapted to frictionally grip opposite sides of each bottle, after its discharge from the timing rollers, and to accelerate the bottle away from the timing rollers; and means, downstream of the entry to said gripping and accelerating means, adapted to distinguish bottles of open-end-trailing disposition from bottles of non-open-end-trailing disposition, and to alter each non-open-end-trailing bottle into an open-end-trailing bottle as the bottle moves through the gripping and accelerating means.

A 6 3 1 ϋ In the accompanying drawings:Fig. 1 is a fragmentary, front elevational view of an assembly in which is incorporated apparatus embodying the invention; Fig. 2 is a fragmentary, plan view, taken in the direction of the line 2-2 in Fig. 1, of a portion of the assembly illustrated in Fig. 1; Fig. 3 is an enlarged, cross-sectional view, taken along the line 3-3 in Fig. 6, of a portion of the apparatus; Fig. 4 is an enlarged, cross-section view, taken along the line 4-4 in Fig. 6, of a portion of the apparatus; Fig. 5 is an enlarged, fragmentary, rear elevational view of a portion of the assembly of Fig. 1; Fig. 5 is an enlarged, fragmentary, frontal perspective view of a portion of the assembly illustrated in Fig. 1; Fig. 7 is a cross-sectional view taken along the line 7-7 in Fig. 6; Fig. 8 is a schematic, cross-sectional view taken along the line 7-7 in Fig. 6; Fig. 9 is a view similar to Fig. 6 of an alternative embodiment of a portion of the orienting means of the apparatus; Fig. 10 is an enlarged, fragmentary, frontal, perspective view of an alternative embodiment of a different portion of the orienting means; and Fig. 11 is a cross-sectional view taken along the line 11-11 in Fig. 10; Fig, 12 is an enlarged, fragmentary, front elevational view of another portion of the apparatus; 6 310 Fig. 13 is a view of the embodiment illustrated in Fig. 12 taken in the direction of arrow X; Fig. 14 is a schematic, fragmentary, frontal view of a varient of the embodiment Of Fig. 13; Fig. 15 through 17 are respective, fragmentary views of partial variations of the embodiment of Fig. 14; and Fig. 18 is an enlarged, schematic view of the bottle-dragging means of Fig. 14.

Referring now to the drawings, and more particularly to Fig. 1, there is illustrated a bottle orienting and conveying apparatus denoted generally by the reference character 10.

The apparatus 10 includes a lower frame portion 12 and an upper frame portion 14 secured to and upon the frame portion 12. The upper frame portion 14 supports a platform 16 to which is secured an upstanding bracket 18. Pivotally connected to the bracket 18 is a bottle-container or supply unit 20 having a base flange 22 which can be adjustably tilted about a pin 24 interconnecting the base flange 22 to the bracket 18.

The angular orientation of the base flange 22 relative to the bracket 18 may be selectively fixed by means of a clamping screw 28 which extends through an arcuate slot 26 formed in the bracket 18 and is threadedly constrained in a threaded aperture ( not shown) formed in the base flange 22 behind the bracket 18. Thus, the orientation of the supply unit 20 can be altered from one of a horizontal disposition (not shown) to one of a tilted disposition as illustrated in Fig. 1. - 4 46310 The supply unit 20 may be, for example, a conventional tank-like device for containing a large number of plastic bottles randomly predisposed therein, for example, by hand or conveyor belt delivery. The unit 20 is equipped with appropriate mechanism (not shown) for discharging the bottles in succession, one-by-one, through an outlet port 30 into a chute or conduit 32. The unit 20 may be, for example, of the type which utilizes a rotating cone or plate (not shown) to discharge the bottles in succession, under slight pressure, through the port 30, A typical version of the unit 20 is, for example, sold under the trademark CENTRIFEED by the firm Tangen Drives, Inc. of Clearwater, Florida, U.S.A.

Communicating With the chute 32 of the unit 20 is a chute 34 defined by an elongate upper member 36 and an elongate lower member 38. The members 36 and 38 are secured to one side face of a bracket 40 which is supported in upstanding relation upon a lower platform 42 of the frame portion 14. The condutis 32 and 34 have substantially the same dimensions and are adapted to guide the advancement of bottles discharged from the port 30 of the unit 20, such as the bottles 44, 46 and 48. The chute 32 is closed on four sides, whereas the members 36 and 38 are provided, preferably, with respective elongate lips 37, 39 preferably running their full length up to the chute 32(Fig. 4).

The bottles may be either flexible or rigid and they may be either of shoulder-and-neck or full-width-neck 6 310 construction. The bottles may have a round, oval or rectangular cross-section so long as the diameter d(Fig. 4), in the case of round bottles, or the vertical height h (Fig. 3), in the case of oval or rectangular bottles is slightly less than the height H (Fig. 1) of the conduits or chutes 32 and 34. The bottles, therefore, are capable of sliding loosely along the chutes 32 and 34 as a train of randomly oriented bottles, each bottle pushing the next as a result of the force exerted by the unit 20 against the last of the bottles issuing from the port 30.

Associated with the chute 34 is a pair of timing rollers 52,54. The assembly of the timing rollers 52,54 and chute 34 constitutes a guide means for receiving and advancing a train of successive, randomly oriented, bottles having each an open end and a closed end. The timing rollers 52,54 function to control the rate of advancement of the bottles outwardly of the chute 34 and into contact with a bottle-gripping roller 62 of a bottle-orienting mechanism shown generally at 60.

The mechanism 60 serves to successively* transversely grasp each of the randomly oriented bottles in the train of bottles, accelerate each of the bottles upon their movement into the bottle-oribnting means, selectively reorient those bottles having an open-end leading disposition (such as the bottles 44 and 46) into an open-end trailing disposition, and deliver all of the bottles passing therethrough to a take-off means, shown generally at 63. 6 310 The take-off means 63 serves to remove uniformly oriented bottles from the bottle-oriented bottles from the bottle-orienting mechanism 60 and includes a vertically oriented chute 64 defined by a pair of parallel, spaced members 66 and 68 affixed to the upstanding bracket 40.

The members 66 and 68 are spaced from one another by the distance T corresponding to the height H of the chute 34.

The chute 64 is associated with a conveyor means denoted generally by the reference character 65 in Fig. 1 for transferring the appropriately oriented bottles to various stations(not shown) at which such bottles are treated further, filled, and stored for eventual distribution.

The timing rollers 52 and 54 and the roller 62 are each provided, preferably, with elastomeric bottle-contacting surfaces and are'each rotatably journaled (in a manner as will be described below) in the upstanding bracket 40. The latter said rollers are also all commonly driven by a single drive means 70 in the form of a motor supported on and affixed to the platform 16. The aforementioned rollers 52,54 and 62 are all coupled to a pulley assembly 69 (Figs.3 and 5) including a toothed drive pulley 72 which in turn is driven by a toothed output pulley 74 of the motor 70. The pulleys 72 and 74 are coupled with one another by means of, for example, an endless toothed, positive drive belt 76. It will be understood that the upstanding bracket 40 (in Fig. 1) is cut away along the irregular, generally U-shaped, line 78 for illustrative purposes in order to <16 3 16 schematically expose the drive means 70 for viewing.

As each of the bottles is manipulated into an open-end-trailing disposition by the mechanism 60, each is permitted to fall one-by-one downwardly into and along the chute 64. The chute 64 guides each of the bottles into respective bottleconstraining spaces isolated from one another by means of equidistantly spaced spoke-like elements 71 (Fig. 2) extending radially outwardly from the periphery of a wheel 75 journaled upon the platform 42 (Fig. 1) adjacent to the chute 64. As illustrated in Fig. 1, the left member 68 of the chute 64 terminates in close proximity to the platform 42, whereas the right member 66 of the chute 64 terminates short of the platform 42 by a distance corresponding to the axial thickness of the wheel 75. As a result, the periphery of the wheel 75 can extend partially into the chute 64 beneath the lower end 73 of the riqht member 66 so that the spoke-like elements 71 project into the chute 64 as shown.

As further illustrated in Fig. 1, the wheel 75 is mounted upon a shaft 77 which is freely journaled at its lower end in an appropriate bearing support 79. The bearing support 79 is attached to and rests upon a lower platform 80 of the lower frame portion 12. Affixed to the shaft 77, is a toothed pulley 82 which when rotated is adapted to transmit rotation to the shaft, the latter which in turn transmits rotation to the wheel 75. The pulley 82 is driven by a drive means 84 in the form of, for example, a motor having a toothed output drive pulley 86 coupled with the pulley 82 6 310 through the intermediary of an endless chain or band 88.

The drive means 84 is adapted to effect continuous rotation of the output pulley 86. Thus, the pulley 82 and wheel 75 are continuously rotated in unison at a prescribed rate such that the spaces between adjacent ones of the spoke-like elements 71 are moved in succession across the chute 64 for receiving the bottles descending from the chute 64, and moves the bottles horizontally along an arcuate path to a conveyor belt 92 illustrated in phantom in Fig. 2. The belt 92 moves in the direction of arrow A linearly substantially at the same rate at which the spoke-like elements 71 are rotated by the wheel 75, and is thus capable of extracting the bottles from between the spoke-like elements 71. In this respect, as illustrated in Fig. 2, a bottle 90 illustrated in phantom is disposed between the spoke-like elements 71a and 71b, When the bottle 90 reaches the position illustrated in Fig. 2, in the course of counterclockwise rotation of the wheel 75, the bottle 90 moves onto the conveyor belt 92.

Once the bottle 90 rests upon the moving belt 92, continued movement of the belt 92 with the spoke-like elements 71a and 71b effects withdrawal of the bottle 90 for advancement to a processing station (not shown) where it can be filled or otherwise treated.

Referring now to Fig. 3, there is illustrated the details of construction of the pulley assembly 69 for rotating the bottle-gripping roller 62 and the timing rollers 52 and 54. As shown, the drive pulley 72 of the pulley assembly 69 is 6 310 affixed to a shaft 94 which in turn is journaled in a bearing assembly 96 supported by the frame portion 40.

As a result, the drive pulley 72 and the shaft 94 are rotatable together relative to the frame portion 40.

Affixed to and adapted to rotate with the drive pulley 72 and the shaft 94 is a second, but larger, toothed pulley 100 which, by means of respective endless toothed belts (as will be discussed below), transmits rotation to the timing rollers 52 and 54. The bottle-gripping roller 62, however, as illustrated in Fig. 3, is affixed to an extension 94a of the shaft 94 and is caused to rotate as the shaft 94 rotates.

Illustrated in Fig. 4 is the mechanical drive arrangement for the timing rollers 52 and 54. As shown, the roller 52 is affixed upon a shaft 102 which in turn is rotatably journaled in a bearing assembly 104 secured to the frame portion 40. At the opposite end of the shaft 102 is a toothed pulley 106 which is operatively associated with the pulley 100 (Fig. 3) via an endless toothed band.

Similarly, the roller 54 is affixed to a shaft 108 rotatably journaled in a bearing assembly 110 secured to the frame portion 40. At the opposite end of the shaft 108 is a toothed pulley 112 which, like the pulley 106, is operatively associated with the pulley 100 via an endless toothed band. It will be seen, that the respective peripheries of the rollers 52 and 54 are closer to one another than is the spacing H (Fig. 1) between the members 36 and 38. The rollers 52 and 54 are, thus,capable of engaging the diametrally opposite side portions of the bottles advancing therebetween (Fig. 4).

Referring now tQ Fig. 5, there is illustrated the operative association of the various pulleys with one another and with a pair of endless bands or belts denoted, respectively, by the reference characters 138 and 140. This association of parts exists on the rear side face of the frame portion 40 that is opposite of the side face thereof illustrated in Fig. 1. The endless belt 138 is operatively associated with the driven pulley 100 and with the driven pulleys 106 and 112 of the timing rollers 52 and 54, respectively. The belt 138 is also operatively associated with a pair of toothed tension control pulleys 142, 143 freely journaled on respective brackets 144 and 145, the bracket 144 having a pair of slotted openings 146 to provide for adjustability of the pulley 142 relative to the frame portion 40.

The endless belt 140 is operatively associated with the driven pulley 72 that transmits rotation to the bottlegripping roller 62, and with the drive pulley 74 of the motor drive means 70. It is the drive pulley 74 that moves the belt 140, the latter in turn transmitting rotation -to the pulleys 72 and 100 in unison to drive the roller 62 and the timing rollers 52 and 54.

Although not shown, the belt 140 is provided with teeth on the inner one of its opposite faces to provide for positive drive of the toothed pulleys 72 and 74 it engages, whereas the belt 138 is provided with teeth on both of its opposite pulley-engaging faces to provide for positive drive of the toothed pulleys 106 and 112 it engages.

As viewed in Fig. 5, the drive pulley 74 is rotated clockwise and, thus, it moves the belt 140 in the direction of arrow B. The belt 140, thereby, rotates the pulleys 72 and 100 in unison clockwise. In turn, as a result, the belt 138 is driven in the direction of arrow C. Since the belt 138 contacts the left side of the pulley 112 and the right side of the pulley 106, the pulley 112 is caused to rotate clockwise, whereas the pulley 106 is caused to rotate counterclockwise. Accordingly, the upper pulley 106 of the timing roller 52 rotates in an opposite direction from that of the lower pulley 112 of the timing roller 54.

The timing rollers, thus, rotate in opposite directions to cooperatively control the advancement of the bottles along the chute 34.

Referring now to Fig. 6, there is illustrated a perspective view of the frontal face of the frame portion 40. This view best shows the association of the timing rollers 52 and 54 with the bottle-gripping 4t33iO roller 62 and with the remainder of the bottle-orienting mechanism 60. The pulley-and-drive arrangement illustrated in Fig. 5 causes the roller 52 to rotate clockwise, and the roller 54 and roller 62 each to rotate counter5 clockwise.

As further illustrated in Fig. 6 (and also in Fig. 4), the timing roller 52 projects slightly through a cut-out 160 formed in the upper plate member 36, whereas the lower timing roller 54 projects slightly through a cut-out 162 formed in the lower plate member 38. As a result, the respective peripheries of the rollers 52 and 54 are frictionally engageable with bottles advancing under pressure offered by the supply unit 20 downwardly along the chute 34. Since the bottles have a thickness corresponding to (but slightly less than) the width of the chute 34, the rollers 52 and 54 are adapted to slightly pinch the bottles advancing therebetween. 6 310 As still further illustrated in Fig. 6 (and in Figs. and 8), the remainder of the bottle-orienting mechanism 60 includes an inverting means or lever 200 constructed and arranged to selectively engage the downstream end portion of each open-end-leading bottle for selectively inverting each such open-end-leading bottle to an ppen-end-trailing disposition. The lever 200, which may also be considered a bottle-catching moans, is affixed to a block 202 that is pivotally arranged via a ball-bearing assembly 203 on an axle-stub 204. The stub 204 is affixed to a bracket 206 which in turn is affixed to the frame portion 40 via a bolt 208 that is arranged in a vertical slot 207 of the bracket 206. Between the block 202 and the bracket 206, there is interpositioned a second block 2T0 that functions to limit the angular swing of the block 202 and thereby, of the lever 200. The block 210 is provided with a cut-out 212 that extends along the periphery thereof, for example, over approximately forty-five degrees. The block 210 can be angularly positioned and fixed on the stub 204 via a clamping bolt 214 to fix the relative position of the cut-out 212.

The block 202 is provided with a cantilevered rod 216 that projects into the cut-out 212 (Figs. 7 and 8) of the block 210. The rod 216 is engageable with the end walls 212a and 212b of such cut-out 212 to define and limit the maximum angular swing of the block 202. The block 210 is 6310 provided with a coil spring 218 (Fig.8) that at one end is connected to a pin 220 affixed to the block 210 (or alternatively to the bolt 214) and at its other end is connected to the rod 216. The spring 218 has an at-rest, unexpanded, condition in a bifurcated portion 210a of the block 210 such that the rod 216 is constrained against the left wall 212a of the cut-out 212, and the lever 200 is constrained in the position 200A shown in phantom in Fig. 8. However, the spring 218 can be expanded when the lever 200 is forced angularly in a clockwise direction to the respective illustrated positions 200B and 200C thereof. The rod 216 in turn moves correspondingly first to a position midway in the cut-out 212 and then into engagement with the right wall 212b, the spring 218 in the meantime continually exerting a force against the rod 216 to urge and return the lever 200 to the at-rest position 200A thereof.

The lever 200 has an L-shaped configuration as illustrated in Figs. 6 and 8, or alternatively, a J-shaped configuration as illustrated in an alternate embodiment thereof in Fig. 9 and denoted by the reference character 200‘. The L-shaped lever 200 is used, for example, in conjunction with bottles advancing along the chute 34 having a wide mouth corresponding in size to the size of the body thereof.

On the other hand, the J-shaped lever 200'is used, for example, in conjunction with bottles advancing along the 6 319 chute 34 having a narrow mouth stemming from a tapered neck 44' of reduced diameter. As shown in Fig. 6, the L-shaped lever 200 terminates in a bent arm 220 projecting in a direction generally longitudinally of the chute 34, whereas, as shown in Fig. 9, the J-shaped lever 200' terminates in a hook-like, bent arm 220' projecting in a direction generally laterally of the chute 34.

Referring once again to Fig. 3, this time in conjunction with Figs. 6 and 9, the bottle-gripping roller 62 includes a hub 230 affixed to the drive shaft portion 94a, and a pair of flexible, bottle-gripping discs 232 that are also, by convential means, affixed to the shaft portion 94a and separated from one another through the intermediary of the hub 230. The hub 230, thus, provides for an annular space between the discs 232 into which freely projects a tongue 234 of the member 38 of the chute 34 (Figs. 6 and 9) and a tongue 236 of the member 66 of the chute 64. Such tongues 234 and 236 are spaced from the hub 230 and the discs 232 so as not to frictionally interfere with the rotation of the roller 62. It will also be seen in Figs.6 and 9, that the member 68 of the chute 64 includes a bent flange 238 that is inclined away from the axis of rotation of the roller 62, whereas the tongue 236 of the member 66 is bent towards the axis of rotation of the roller 62.

Referring now to Figs. 10 and 11, there is illustrated an alternative embodiment 62' of the bottle-gripping roller 62 6 310 The embodiment 62' includes a hub 240 affixed to the drive shaft portion 94a in a manner akin to that of the hub 230 of the roller 62. In this instance, however, the hub 240 is associated with a second hub 242 (Fig. 10) that is freely journaled on an axle-stub 243 affixed to the frame portion 40 to idle or rotate freely in response to the rotation of the hub 240. The hubs 240 and 242 are coupled to one another through the intermediary of a flexible, endless, belt-like, conveyor 244 that is fit snugly over the hubs 240 and 242 and causes the hub 242 to rotate in response to the rotation of hub 240.

The conveyor 244 is provided with a pair of flanged walls 246 (Fig. 11) that define cooperatively an annular bottle-receiving space therebetween. The walls 246 each includes a plurality of finger-like, bottle-gripping, segments 248 (Fig. 10), adjoining ones of which, on the same run, from the base of the conveyor 244, separably flare away from one another as they move onto the hubs 240 and 242 beyond the generally horizontally-oriented runs 246a thereof.

In the alternate embodiment 62' as in the first described embodiment 62, the member 38 of the chute 34 has a tongue 234 that projects into the annular space between the conveyor walls 246, and the member 66 of the chute 64 has a tongue 236 that projects also into the annular space 3/0 between the walls 246. Such tongues 234 and 236 are out of contact with the conveyor 244 so as not to frictionally interfere with the movement thereof.

Initially, the supply unit 20 is filled by hand with many bottles which in succession are discharged under pressure by the supply unit 20 through the port 30 as a train of bottles into the chutes 32 and 34 in communication with one another. During this period, the drive means 70 causes the drive pulley 74 to turn, thereby transmitting rotation to the identically sized timing rollers 52 and 54, and to the larger bottlegripping roller 62. The timing rollers 52 and 54 act as a brake with respect to the train of bottles advancihg along the chute 34 and serve to feed the bottles one-by-one in a timed sequence to the roller 62 (Fig. 6), and force in succession each leading bottle between the flexible discs 232 thereof (or between the flexible finger-like segments 248 of the conveyor 244 in Fig. 11). The trailing bottles are prevented from being dislodged from between the plate members 36 and 38 by the elongate lips 37 and 39 which, preferably, run the full length of the chute 34 up to the chute 32 (Fig. 4).

As shown in Fig. 5, the diameter of the pulley 100 is substantially twice the size of the diameter of the pulley 72 and, thus, the peripheral speed of the pulley 100 is substantially twice the peripheral speed of the pulley 72. Thus, the endless belt 138 associated with the pulley 100, and the pulleys 106 and 112 associated with the endless belt 138, are driven at the same peripheral speed as the pulley 100 which is substantially twice as fast as the belt 140 associated with the pulleys 72 and 74. However, the portions 232' of the discs 232 (Fig. 3), or the portions 246' (Fig. 11) of the conveyor 244, which grip the bottles in succession have respective diameters which are greater than twice the size of the diameters of the timing rollers 52 and 54. As a result, these effective bottle-gripping portions 232' (and 245') have rotary speeds which are greater than the rotary speeds of the timing rollers 52 and 54. Accordingly, the bottles are advanced by the bottle-gripping roller 62 at a faster rate than they are advanced by the timing rollers 52 and 54. Thus, the bottles can be said to be accelerated away from the chute 34 by the roller 62, and can be said to be braked by the timing rollers 52 and 54.

The timing rollers 52 and 54, thus, function to slow down the rate of advancement of the bottles discharged into the chute 34 to provide sufficient time for the bottlegripping roller 62 and the lever 200 to invert those bottles of open-end-leading disposition (such as the bottles 44 and 46 illustrated in Fig. 6) to ones of open-end-trailing disposition (such as the bottle 48 illustrated in Fig. 6), Generally, those bottles having a open-end-leading disposition are inverted in the manner schematically illustrated in phantom in Fig. 6 (and Fig. 9) wherein, for example, the bottle 44 is discharged by the timing rollers 52 and 54 from the chute 34 to initially engage, with its open-end, the arm 220 (Fig 6) of the lever 200 (or the bent hook 220' in Fig. 9) adjacent to the bottlegripping roller 62. In this disposition of the bottle 44, the portion of the bottle 44 behind the open end thereof is frictionally held by the discs 232 of the roller 62 (or the finger-like segments 248 of the conveyor 244 in Fig. 10) and is frictionally moved by the latter so that the open-end of the bottle swings upwardly by the lever 200 along the bent flange 238 to the disposition shown in phantom and denoted by the reference character 44a More specifically, in the instance of the embodiment of the lever 200 illustrated in Fig. 6 which includes the bent hook 220 projecting in the direction generally longitudinally of the chute 34, as the bottle 44 is frictionally gripped by the opposing, flexible discs 232 and accelerated toward the lever 200, the leading, wide, open-end or mouth of the bottle 44 is caught by the bent hook 220. Continued movement of the bottle 44 forwardly by the opposing, flexible discs 232, which continuously retain their frictional hold on the bottle 44, results in the swing of the lever 200 from the position thereof illustrated in solid line to the position thereof illustrated in broken line. Such swing extends angularly over approximately forty-five degrees as a result of the - 20 46310 cooperation of the cantilevered rod 216 with the walls 212a and 212b of the cut-out 212 (Fig. 8).

As the lever 200 swings angularly, the bent hook 220 thereof lifts the wide, open-end of the bottle 44 upwardly and into engagement with the bent flange 238 of the chute 64. The bottom of the bottle 44 is, thereby, caused to pivot frictionally relative to the flexible discs 232 and to move downwardly into engagement with the bent flange 236. Continued rotation of roller 62 moves the bottle 44 to the position shown at 44a and finally the bottle 44 is cammed by flange 236 to the vertical disposition shown at 44b wherein it is released from both the lever 200 and the flexible discs 232 and falls into the chute 64. Once the bottle 44 is released by the lever 200 and the discs 232, the spring 218 (Fig. 8) returns the lever 200 to the position 200A thereof to await the oncoming bottle 46 and convert it, too, from a bottle having an open-end leading disposition to one of an open-end trailing disposition.

It will be understood, that when bottles having an openend trailing disposition, such as that of the bottle 48, are accelerated by the roller 62 (or the alternative embodiment 62' in Fig. 10) into engagement with the lever 200 (or the lever 200' in Fig. 9), the respective leading closed ends thereof simply brush aside the lever 200 ,200' and tilt into contact with the bent flange 236 of the chute 64, whereupon such bottles are cammed /46310 into a vertical disposition and fall into the chute 64.

With respect to the embodiment of the lever 200' illustrated in Fig. 9, it functions, with a slight difference, in a manner described above with regard to the lever 200 (Fig. 6). The difference is that the bent hook 220' thereof, which extends in a direction generally transversely of the chute 34, does not penetrate the tapering, leading open-ends of the bottles reaching it.

On the contrary, the bent hook 220' successively catches the narrow necks 44' of such bottles from their exteriors before swinging them upwardly to reorient their open-end leading dispositions to open-end trailing dispositions.

The bent hook 220' could, in an alternative embodiment, comprise a closed ring (not shown) having a diameter slightly larger than the outside diameter of the narrow neck 44 of the bottles 44.

After the bottles are accelerated into the chute 64, they are in succession removed from the chute 64 by the wheel 75 which in cooperation with, for example, the conveyor belt 92 (Fig. 2) advances the bottles to other apparatus (not shown) at which the bottles may be treated or filled, and packaged or stored.

Referring now to Figs. 12 and 13, there is illustrated still another embodiment of the bottle-orienting mechanism. In this embodiment, the mechanism is denoted generally by the reference characted 300. It includes the aforementioned bottle-gripping roller 62 arranged upstream of the chute 64 defined by the plates 66 and 68, the roller 62 being comprised of the aforementioned discs 232 and the hub 230. The difference between the embodiment of Figs. 12 and T3 and those of Figs. 1-11 is that in Figs. 1-11 there is provided a bottle-catching means or lever 200 downstream of the roller 62 for assisting the latter to invert bottles having an open-end leading disposition. The embodiments of Figs. 1-11 are to be used preferably with bottles having wide and/or elongated open ends.

In the embodiment of Figs. 12 and 13, no such bottlecatching means is provided upstream or downstream of the roller 62. On the contrary, a bottle-dragging means comprised of a pair of pulley-driven endless belts or bands 302 and 304 is provided to cooperate with the roller 62 and effect the necessary bottle inversion of such bottles of the narrow open-ended, bulbous, conical or pyramidal varieties.

The belts 302 and 304 may be toothed or otherwise, and are mounted each on a respective pair of pulleys 306 and 308 which correspondingly may be toothed or otherwise. At least one pulley of each pair 306 and 308 is driven by conventional means ( not shown) at a prescribed rate identical to the other. The belts 302 and 304 are arranged just upstream of the roller 62, the upper belt 302 being substantially longer than the belt 304 and extending beyond and to the left of a vertical centerlIne L (Fig. 12) of the roller 62, The lower belt 304 supports the bottles it advances cooperatively with the upper belt 302, and turns counterclockwise.

The upper belt 302, on the other hand, turns clock5 wise. Thus, the lower run of the belt 302 and the upper run of the belt 304 move in the same direction at substantially the same speed toward the roller 62.

Upstream of the belts 302 and 304 is a second pair of belts 310 and 312, each mounted on a respective pair of pulleys 314 and 316. At least one pulley of each pair 314 and 316 is driven by conventional means (not shown) at a prescribed rate identical to the other. The lower run of the belt 310 and the upper run of the belt 312 are driven to the left toward the roller 62 at a rate that is preferably slower than the rate at which the belts 302 and 304 are driven. In turn, the belts 302 and 304 are driven at a rate that is slower than the rate of the roller 62 at the portions of the discs 232 which grip bottles advancing thereto in succession by the belts 302,304,310 and 312. It will be understood that the runs of the belts 302,304, 310 and 312 cooperatively form a moving extension to the conduit 34 of, for example, Fig. 1, and, as pairs, frictionally grip opposite sides of the bottles they advance toward the roller 62.

I In operation of this embodiment, the belts 310 and 312 grip, in succession, bottles issuing from the conduit 6 3 1 θ 34, and move such bottles to the belts 302 and 304. In turn, the faster moving belts 302 and 304 move such bottles in succession to the roller 62. The rotary speed of the roller 62, and particularly of the portions of the discs 232 thereof which grasp and remove the bottles in succession from the belts 302 and 304, is greater than the speed of the belts 302 and 304. As such, the longer, upper belt 302 exerts a drag on, or frictionally restrains, the upper side portion of each bottle it contacts, thereby causing each such bottle to pivot clockwise relative to the portions of the discs 232 gripping same.

If such a bottle issues from between the belts 302 and 304 in a closed-end leading disposition, the trailing open end thereof pivots clockwise into engagement with the hub 230 of the roller 62 and no further. The roller 62, thus, will in its counter-clockwise rotary course carry such a bottle to the chute 64, whereupon the flange 236 will free the bottle from between the discs 232 and cause it to fall closed-end-first into the chute 64.

On the other hand, if a bottle issues from between the belts 302 and 304 with an open-end leading disposition, such as the bottle 320, the leading open end thereof will be turned clockwise into engagement, or near engagement, with the belt 302, such as at 322. This occurs as a result of the difference in speed between the relatively moving surfaces of the belt 302 and 310 those of the discs 232, the latter moving more rapidly than the former. Thus, the open-end leading bottles, such as the bottle 320, are caused to pivot about a horizontal axis perpendicular to the discs 232. Such pivotal motion is effected until the open end of such bottles engages, or is in close proximity to, the belt 302. Continued rotation of the roller 62 moves the bottle 322 to a position 324 at which the flange 238 of the chute plate 68 is engaged by the bottle. Such engagement cams the bottle into an open-end-up disposition, whereupon the bottle is then cammed free from the roller 62 by the flange 236 to fall into the chute 64, A variant of the embodiment of Figs. 12 and 13 is illustrated in Fig. 14 in schematic fashion. Such a variant is denoted generally by the reference character 400 and includes the aforementioned bottle-gripping roller 62 just upstream of the chute 64. In this instance, however, the bottle-dragging means is provided in the form of a lever 402 pivotally connected at 404 to the frame portion 40. At the opposite end of the lever 402, there is provided a roller 406. The roller 406 is rotatably supported by the lever 402, and includes a peripheral surface having a relatively high coefficient of friction. For example, the roller 406 may be made of rubber or some other elastomeric material. The combined axial extent or width of the roller 406 and 4t33i0 the lever 402 is less than the axial extent of the hub 230 of the bottle-gripping roller 62 (and.thus, of the axial space between the discs 232 of the roller 62). As a result, the end portion of the lever 402 supporting the roller 406, and the roller 406, are together insertable, and fit with substantial clearance, between the discs 232 of the roller 62.

In this regard, reference is now made to Figs. 15 to 17. In Fig. 15, the roller 406 is shown as a single disc element. In Fig. 16, the roller 406 is shown as a pair of identical discs 406A arranged on either side of the lever 402. In Fig. 17, the roller 406 is covered by an elastomeric, endless, drive belt 410.

In each of the instances of Figs. 15 to 17, the elements of the roller 406, are well spaced from the discs 232 of the roller 62 so as not to interfere with the rotation of the latter.

Referring now to Fig. 18, there is shown a drive system for turning the roller 406. The drive system includes, for example, a wheel 412, toothed or otherwise, rotatably arranged at the end of the lever 402 that is pivoted to the frame portion 40. Cooperating with the wheel 412 is, for example, the aforementioned endless belt 410 having, for example, corresponding teeth (not shown) on its internal surface. The belt 410 cooperates with the roller 406 via, for example, a second, correspondingly toothed, wheel 414 that is affixed to the roller 206 and adapted 6 310 to transmit rotation thereto. The structure illustrated in Fig. 18, for example, corresponds to the structure illustrated in Figs. 15 and 16. On the other hand, with respect to Fig. 17, the toothed wheel 414 of Fig. 18 is replaced by the roller 406 itself, the latter having a toothed periphery for cooperation with the toothed belt 410.

In operation of the variants illustrated in Figs. 14 to 18, the toothed wheel 412 is rotated by conventional means (not shown) clockwise to effect rotation of the roller 406 also clockwise. The weight of the lever 402 and roller 406 provides for a normal force against bottles advanced thereto by, for example, the timing rollers 52 and 54. Preferably, the periphery of the roller 406 engaging the bottles is turned more slowly than the portions of the discs 232 of the bottle-gripping roller 62 that subsequently grip the bottles in succession. As a result, the roller 406 retards the advancement of the upper side of each of the bottles relative to the lower side, and causes such bottles to pivot clockwise about a horizontal axis normal to the discs 232.

If a given one of the bottles has an open-end leading disposition, the bottle will be pivoted until the open end thereof engages, or nearly engages, the roller 406.

Rotation of the bottle-gripping roller 62 counterclockwise will in turn transfer the pivoted bottle from an open-end-up disposition, such as at 420, to the disposition shown at 422, whereupon such bottle will fall into the chute 64 bottom-first. If a given bottle is gripped by the roller 62 bottom-first, the bottle will still be pivoted clockwise by the roller 406, but only until the open end thereof engages, for example, the hub 230 of the roller 62. As such, any bottle having a closed-end leading disposition emerging from the timing rollers 52 and 54 will be transferred without a change in its disposition by the bottle-gripping roller 62 to the chute 64, whereupon it will fall bottom-first thereinto.

It will be understood, although not shown, that springs and/or other control devices may be utilized for urging the lever 402 downwardly toward the train of bottles so as to enable the roller 406 to frictionally retard the advancement of each bottle with a preferred pressure. It will also be understood, although not shown, that an appropriate abutment means is provided to limit the downward swing of the lever 402 to a preferred distance from the bottle-gripping roller 62.

Claims (13)

1. WHAT WE CLAIM IS:1. Bottle-orienting and conveying apparatus comprising: supply means adapted to receive randomly-oriented bottles and to discharge them therefrom in a pressurized column 5 of bottles in random open-end-leading and open-endtrailing dispositions; guide means adapted to receive bottles from said supply means and to advance said bottles in random open-endleading and open-end-trailing dispositions, said guide 10 means including a chute positioned downstream of said supply means for receiving said pressurized column of bottles and a pair of spaced, driven contra-rotating timing rollers positioned adjacent the downstream end of said chute and frictionally engageable peripherally 15 with opposite sides of the leading bottle in said column so as (in use) to successively discharge bottles from said chute in a timed sequence; means adapted to frictionally grip opposite sides of each bottle, after its discharge from the timing rollers, 20 and to accelerate the bottle away from the timing rollers and means, downstream of the entry to said gripping and accelerating means, adapted to distinguish bottles of open-end-trailing disposition from bottles of non-openend-trailing disposition and to alter each non-open-end25 trailing bottle into an open-end-trailing bottle as the bottle moves through the gripping and accelerating means.

2. Apparatus according to claim 1, the apparatus being adapted to orient and convey bottles each of which, tapers from its closed-end portion to its open-end portion; in which the gripping and accelerating means comprises, or co-operates with, a means which (in use) applies an external frictional force to the enlarged closed-end portion of each bottle and which, if the bottle is an open-end-leading bottle, partly rotates the bottle endfor-end into a position in which its axis projects at an angle to the column of bottles advancing towards the gripping and accelerating means.

3. Apparatus according to claim 2, in which the gripping and accelerating means comprises a pair of co-axially spaced flexible disc-like elements rotating (in use) in unison in the direction of advancement of the column of bottles; and the frictional-force-applying means acts on each open-end-leading bottle, as the bottle is gripped between the said elements, and partly rotates the bottle in the opposite rotational direction to that of the rotating disc-like elements, thereby bringing said bottle into a position in which its open end projects generally radially and outwardly from the axis of the rotating elements.

4. Apparatus according to claim 2, in which the frictional force-applying means comprises a roller whose rolling surface confronts, and forms a nip with, the space 40 310 between the disc-like elements; and means to drive the roller (in use) at a peripheral speed less than the speed of the bottle-gripping portions of the disc-like elements and in the opposite rotational direction to that 5. Of the rotating disc-like elements.

5. Apparatus according to claim 4, in which the rollerdriving means comprises a belt-and-pulley drive.

6. Apparatus according to claim 5, in which a further belt-and-pulley drive runs alongside the said roller10 driving belt-and-pulley drive, the belts of each said drive co-operating with one another in use to grip and advance bottles in succession towards the disc-like elements.

7. Apparatus according to any of claims 4 to 6, in which 15 the roller is rotatably mounted towards one end of a lever, the other end of the lever being pivotally secured to a frame part of the apparatus.

8. Apparatus according to claim 7, when appendant to claim 6, in which said other end of the lever carries 20 a pulley which is connected by an endless belt to said roller and which,in use, drives the roller via said endless belt.

9. Apparatus according to either of claims 7 and 8, in which the roller comprises a single disc-like element rotatably affixed to one side of said lever.

10. Apparatus according to either of claims 7 and 8, in which the roller comprises a pair of spaced disc-like elements rotatably affixed one to each side of said lever. 5

11. Apparatus substantially as described herein with reference to, and as illustrated in, Figs. 1 to 11; or those figs, when modified as in Figs.

12. And 13; or modified as in Figs. 14 to 18, of the accompanying drawings. Dated this 20th day of January 1978 CRUICKSHANK & CO. Agents for the Applicants, Youghal House,

13. , Trinity Street, Dublin 2.