DE2835129A1 - CONTAINER FEEDING DEVICE FOR A CONTINUOUSLY OPERATING CONTAINER PRINTING MACHINE - Google Patents

Description

Patent Attorneys D: ρL-ing. Curt WaIIach OOOC1 OQ Οίρ ..- lng. Günther Koch

Io60 I Ζ » _g_ Dipl.-Phys.Dr.Tino Haibach

Dipl.-Ing. Rainer Feldkamp

D-8000 Munich 2 Kaufingerstraße 8 Telephone (0 89) 24 02 75 Telex 5 29 513 wakai d

Date: .. 1 0- AUG. 1978

Our reference: 1Ö332 H / Bu

Sun Chemical Corporation, New York, N.Y., USA

Container feeding device for a continuously operating container printing machine

The invention relates to a container feeding device for continuous working can printing machines.

U.S. Patents 3,563,170, 3,766,851 and 3,976,187 teach high speed continuous can printing machines described in which the cans are held on freely rotating mandrels or spindles during printing are. The loading of the mandrels or spindles with the cans or cans to be printed is carried out continuously rotating wheel with curved seat surfaces or pockets to accommodate unprinted cans on its circumference a supply station is provided. Typically there is a combination between the supply station and the pocket wheel a screw conveyor and a star wheel are interposed to transfer the unprinted cans to the pocket wheel before they are sent at an appropriate distance between the pockets To bring distance. ./.

909808/0981

At very high operating speeds of, for example, more than 800 cans per minute, the risk increases that Cans are damaged by the conveyor screw or get jammed in it. So you already have the use tried a gravity feed chute to feed the cans directly into the pockets of the pocket wheel. The attempts in this direction have been successful to a certain extent, but at very high operating speeds the can movement becomes gravity-fed working feed chute irregularly, so that the cans hit against each other. This often makes the cans direct damaged or it comes to disturbances in the feeding of the cans into the pocket of the pocket wheel, whereby the synchronism is disturbed and the pocket wheel can damage the cans.

The invention is intended to avoid these difficulties of the known devices with direct delivery of the cans onto a pocket wheel via gravity-operated chutes. In particular, the invention is based on the object of creating a pocket wheel of such a construction in cooperation with the gravity _{feed chute that a continuous movement at a constant speed is ensured in the chute s} instead of the infecting _s vibrating and / or otherwise uneven feed = movement j like them was characteristic of the known designs.

According to the gist of the invention, the one aimed at becomes uniform Feed flow achieved by the sequential connects adjacent pockets of the pocket wheel to one another by means of an introduction or lead-in surface, which is designed as an arc segment of uniform radius and merges tangentially into the two pockets »In addition, is the gravity feed chute designed and arranged so that in each case at which a

909808/0911

Can has taken its seat in a pocket of the pocket wheel, the center of the next neighboring can, which is still in the chute, lies on a line which is from the center, around which the arc segment forming the lead-in or lead-in area is drawn, through the center of the just charged Bag runs.

The invention is thus a for

high speeds suitable baffle feeder for loading unprinted cans into the pockets of a continuous Circulating pocket wheel created, which works satisfactorily at high external working speeds and at the one Continuous advance of the cans in the feed chute at a constant speed is guaranteed.

According to a preferred embodiment of the invention, there is provided that a can, which has just taken its seat in a pocket, with the next one upstream still the can in the chute is in contact at one point, which corresponds to the point of tangency between the lead-in or lead-in area and the newly loaded pocket.

In the following, exemplary embodiments of the invention are described with reference to the drawing; in this show

Fig. 1 in front view of a continuously operating

Can printing machine with a baffle feeder according to one embodiment of the invention,

FIG. 2 shows, in an enlarged partial view, the area of the feed device from FIG. 1,

Fig. 3 to 6 each sectional views in section along the

Arrows 3-3, 4-4, 5-5 and 6-6 in Fig. 2, with Direction of view in the direction of the indicated arrows,

FIG. 7 shows a schematic representation to illustrate essential points of the invention in FIG

idealized representation. 909808/0981

The illustrated in the overall view of Fig. 1 continuously operating machine cylindrical for printing container from that in the application P 28 26 304.9 of June 15, 1978, the same applicant (corresp. US n. S / N 8O7 _s 26O of 16. June 1977) described type. It has a feed conveyor device 15 which receives the unprinted cans 16, which are open at one end, from a supply station (not shown) and places them in arc-shaped cradles or pockets 17 along the circumference of spaced apart rings 13 _s I ¹ * (FIG. 3) stores j which form the circumferential area of a pocket wheel 12. This pocket wheel 12 is firmly connected to a carrier wheel 18, which in turn is keyed on a horizontal drive shaft 19 for continuous rotation. Horizontal spindles or mandrels 20 (FIG. 3) are also arranged on the wheel 18, the individual mandrels 20 each being aligned horizontally with corresponding individual pockets 17 in a short area extending downwards from the feed device 15. The unprinted cans 16 are each transferred from the individual pockets 17 to a mandrel 20, namely by a separate spring arm 42 _s which is arranged on a slide 43, which in turn is fastened to the slide 43 through the cooperation of a stationary cam 44 Cam followers 45 _S 46 is driven in the horizontal direction, via an axial channel which extends up to the end face of the mandrel receiving the can 16, a negative pressure is generated and the can is thus drawn into its final position on the mandrel 20.

The cans 16 are printed in their attached state on the mandrels 20, in that the cans are brought into engagement with a continuously rotating image transfer mat 21 of a multicolor press indicated as a whole by 22. After that itfird on the individual cans _s while they are on the mandrels 20 are ₉ applied a lacquer protective film. By the cans are brought into contact with the periphery of an application roller 23 in a direction indicated as a whole by 24 in contact Laeklerstation "

Then those with the printing and the protective coating are provided Cans or cans 16 are transferred from the mandrels 20 to suction cups (not shown) on the circumference of a transfer wheel 27. This rotates continuously around a shaft 28 as the center. The cans or cans carried by the transfer wheel 27 Bushings 16 are finally deposited on substantially horizontal pins or pegs 29 attached to an output chain conveyor 30 are arranged, which leads the cans 16 through a (not shown) curing oven.

The loading of the individual mandrels 20 with a can 16 takes place at a time in which the mandrel 20 is in the Located near sensors 63,64, which determine whether the respective Mandrel 20 carries a sleeve 16 in the proper position. If the sensors 63,64 determine that a mandrel 20 is not or not is properly loaded, as is detailed in the above-mentioned application P 28 26 304.9 of June 15, 1978 the same applicant described this mandrel 20, which was not or not properly loaded, on its way through the printing zone, in which normally the pressure mat 21 comes into abutment against the cans 16 located on the mandrels 20, in a "non-printing" position, in which this mandrel 20 at a distance as it moves through the printing zone from the circumference of the pressure mat 21 lies.

The feed conveyor device 15 consists of inner plates 51, 52 and 53 (Fig. 3 and Fig. 4) and outer plates 54, 55 * which are held at a parallel distance from one another by four units, each of which has a bolt 56, spacer bushings 57j58,59 _s 6O, a washer 6l and a nut 62 include (Fig. 4). Four columns 63 extend from the machine frame in the horizontal direction; these are received in mutually aligned openings in the plates 51 to 55 in order to position the conveying device 15 in its operating position. The conveyor device 15 is placed on the columns 63 by means of flanges 64 , 65

909808/0981

positioned and locked in the operating position.

The inner plates 51> 52,53 are provided with horizontally aligned curved slots which cooperate with one another to form a gravity feed chute 70 through which the cans 16a, 16b etc. (FIG. 2) slide into the pockets 17 of the pocket wheel 12 . During the down-sliding of the dosages L6A _s L6B etc. through the chute 70, the axes of the cans I6a, etc. L6B directed horizontally and perpendicular to the sliding direction. In the loading area 71j where the lower or exit end of the chute 70 meets the pocket wheel 12, the ring 13 runs through the space between the plates 51 and 52 and the ring 14 runs through the space between the plates 52 and 53 (Fig. 3).

Downstream of the loading area 71, the inner plates 51 to 53 form a curved retaining surface 99 _S which runs somewhat outside of the cans 16 guided upwards by the pocket wheel 12. The distance between the upstream end of the surface 99 and the can 16a _s which has just left the chute 70 _s is substantially greater than the distance between the surface 99 and the cans located downstream of the can 16a. This enlarged distance is provided in order to avoid damage to the can 16a if it changes its direction of movement abruptly in the loading area 71, and at this point the can 16a may jump up in an uncontrolled manner. To dampen this high Springer the can L6A are slightly yielding elastic devices in the form of brush sections 97 _S 98 (Fig. 6) provided as a stop, which the can L6A hold in the feed portion 71 in its seat on the pocket wheel 12th

The bristles of the brush portions 97 are disposed _S 98 of a rod 96 radially from in a triangular configuration. The rod 96 is pivotable on the plates 51 and 55 ./.

arranged, and is held in a certain selectable angular position by means of a manually operable locking device 95 by hand lever 9H.

In Fig. 2 the pocket wheel 12 is shown in an angular position, in which a can 16a has just completely assumed its position in a pocket 17a. ■ Ideally, the introductory or introducing surface 75 between pocket 17a and the upstream adjacent next following pocket 17b Circular arc tangent with respect to both pockets 17a and 17b. Furthermore, the line connecting the centers of the Cans I6a, l6b through the center, around which the inlet area 75 is formed.

It has been shown that, for practical implementations, the center around which the lead-in arc 75 is formed lies on one or the other of two quadrature lines, which are described with reference to FIG. 7, in which point b represents the center point, around which the lead-in surface 75 is formed. The point b lies on a quadrature line q which runs through the axis of rotation 19 of the pocket wheel 12. The line q is also at right angles to the other quadrature line p, which runs through the center point 19 of the pocket wheel and the center point c _s around which the arc segment forming the upstream pocket 17b is formed. The centers of all pockets 17 are uniformly spaced along a circle of radius a, such that the angular distance θ between adjacent pockets is 360 ° divided by the number of pockets. The line s in FIG. 7 runs parallel to the line ρ and is therefore also at right angles to the line q.

Thus the right triangle c, b, 19 is given by the equation:

X ² + a ² = (R + r) ²
reproduced, where R is the radius of the arc for the introductory »

909808/0981

Area 75 and r the radius of the individual pockets Arcs mean.

Furthermore, the center point of the pocket IJa is denoted by e; the right triangle e _s b _s g is then given by the following equation:

(Xa sin ©) ² + (a cos8) ² = (R- = r) ² "

In a practical embodiment, the pocket wheel 12 has, for example, 2H equally spaced pockets 17 on a guide circle with a radius of 20 inches. The diameter of the receiving pockets is essentially equal to the 2 _a 6 inch diameter of the bushings, this leads to a position of the center point b _s around which the lead-in surface 75 is formed _s on the quadrature line q at a distance X = 10.753 inches from the axis of rotation 19 of the pocket _{wheel 12 seconds} with a radius of the lead-in surface 75 of 212.407 inches.

In the timing in which the can L6A fully their consumption = seated in the pocket 17a occupies _s touches the can located in the chute 70 upstream of the can L6A lob the can L6A in a point t _s in which the arc of the introduction surface 75 tangential to the arc the pocket 17a runs. At this point in time, the center point f of the sleeve 16b is on a _{line running through the points b s} e and t.

Referring to Figure 2, it can be seen that the downstream end 85 of the lead-in surface 75 is connected to the pocket-forming arc 17 rather than a sharp point having a curve of small radius of curvature. _{This ensures a smooth engagement between a can s} leaving the slide 70 and coming into abutment against the inlet surface 75, for example the can 16b. It can also be seen that the downstream part 75a of the inlet surface 75 is slightly worn

to create clearance for the initial contact between the lead-in surface 75 and the sleeve 16b, and the danger to it reduce the fact that the sleeve l6b is pushed away from the pocket wheel 12 even temporarily.

When using a form chute in an arrangement according to the invention for the direct supply of cans to a likewise according to the invention designed pocket wheel, feed speeds of more than 1,000 cans per minute are possible. As a result of essentially Continuous canister movement in the chute at a constant speed reduces the risk of clogging and / or damage to the cans over known prior art gravity feeders Technology quite considerably.

It is readily apparent to those skilled in the art that the dimensional relationships given above correspond to idealized conditions. For practical purposes, useful results can still be achieved with deviations between 5 and 10 % from the specified ideal dimensional relationships.

The invention has been described above on the basis of a preferred embodiment explained, which can of course be modified in various details without this the scope of the invention is left.

summary

The subject of the invention is a continuously operating can printing device with a gravity effect working feed chute, which unprinted cans or cans feeds directly to a pocket wheel provided with a receiving pocket, from which the cans are transferred to mandrels »

909608/0911

Claims (11)

Claims lJ container feeder 'for a continuously operating Can printing machine, with a continuously revolving carrier wheel with a large number of in the same Pockets arranged at intervals along the circumference, in such an arrangement and shape that they accommodate the can accommodate cylindrical container with their axes parallel to the axis of rotation of the pocket wheel, with a Guide curve feed chute through which the to be printed cylindrical containers side by side with their axes perpendicular to the direction of port movement move in the chute from a supply station to a loading area, where the containers to be printed can be delivered directly into the pockets of the rotating pocket wheel, the pockets having a corresponding profile a circular arc segment of substantially the same radius as the cylindrical containers fed in the chute have, characterized in that each pocket (17b, Fig. 2 and 7) and in the direction of rotation the pocket wheel, the pocket (17a) next to it downstream, by means of a lead-in or lead-in surface (75) are connected in the form of an arc segment of substantially uniform radius (R, Fig. 7) that the center points (c, e, Fig. 7) of the circular arc segments forming the pockets (17b, 17a) on a guide circle with the axis of rotation (19) of the pocket wheel (12) lie as the center point, and that the introduction or introduction surfaces (7b) each at their in the direction of rotation, the downstream end (85, FIG. 2) is essentially tangential with respect to one of the pockets (17) forming circular arc segments extend in a radially outside of the guide circle point and at their against the direction of rotation upstream end essentially tangential with respect to the circular arc segment of the The next pocket run in a point located radially inside the guide circle. ./. 909808/0981 ORIGINAL INSPECTED Container feed device according to claim 1, characterized in that the feed chute (70) is designed and arranged in such a way that in the loading area (71j Fig. 2) a cylindrical container (16a) at the point in time at which it is seated in a pocket (17a ) of the pocket wheel (12) has just fully occupied, with the container (16b) next to it upstream in the chute (70) at the tangential point (t _s Fig. 7) between the pocket (17a) currently in the loading area (71) and the is in contact against the direction of rotation upstream of this pocket extending insertion or lead-in surface (75). Container feeding device according to claim 1 or 2, characterized in that the respective insertion or lead-in surface (75) forming arc segments are formed around a center point (b), which on a (q, Fig. 7) of two quadrature lines which are perpendicular to one another and run through the axis of rotation (19) of the pocket wheel (12) (p, q), the other (p) of the two lines (p, q) passing through the midpoint (c) of the upstream At the end of this lead-in or lead-in surface arch segment (75), the pocket arch segment (17b) extends. Container feeding device according to one or more of the preceding Claims, characterized in that the introduction or introduction surface (75) on its downstream end (85) in the direction of rotation is rounded. Container feed device according to one or more of the preceding claims, characterized in that the introduction or introduction surfaces (75) are each rounded at their outermost end (85) downstream in the direction of rotation and are slightly undercut in the area immediately upstream. ./. 909303/0981 Container feeding device according to one or more of the preceding claims, characterized in that the introduction or introduction surface ■ forming arc segments (75) are each formed around a center point (b), which on an approximately through the Axis of rotation (19) of the pocket wheel (12) going line (q), which in turn is approximately at right angles to a through the axis of rotation (19) and the center (c) of the at the opposite to the direction of rotation upstream end of the Lead-in or lead-in surface forming arc segment (75) located pocket arc segment (17b) going line runs. Container feeding device according to one or more of the preceding claims, characterized in that the center point (b) of the insertion or Lead-in surface (75) forming arc segment at a distance X from the axis of rotation (19) of the pocket wheel (12) which is determined according to the following equations: X ² + a ² = (R + r) ² and (x - a Sine) ² + (a Cos8) ² = (R - r) ² , where a = radius of the center points of the pockets (17) connecting control circle
R = radius of the lead-in or lead-in area (75) forming arc segment r = radius of the arc segment forming the pockets ., '(17)
θ = 360 ° ./. the number of pockets (17) 909808/0981 8. Container feeding device according to one or more of the preceding claims, characterized in that that the respective lead-in or lead-in surfaces forming arc segments (75) each by one other center (b) offset with respect to the axis of rotation (19) are formed. 9. container feeder RACH claim 8 in conjunction with claim 3 characterized in that the _{S s} that the center of each of the insertion or introduction surfaces forming arc segments each located on one of these lines. 10. Container feed device according to one or more of the preceding claims, characterized in that resilient-elastic stop means (97 _S 98, Fig. 6) for preventing movement of the cylindrical container (l6a) out of the pockets (17) of the pocket wheel are provided in the loading area are, 11. Container supply device according to claim 10, characterized in that j that resiliently elastic Stop device a brush arrangement (97,98) is provided is.