GB2103586A - Feeding stacks of sheets - Google Patents

Abstract

A magazine (2) for stamps is provided with an escapement mechanism in the form of upper and lower gripping means (24, 26) which alternately support the pile of stamps, thereby allowing the stamps to be fed at a constant head to a withdrawal rotor (10). The upper and lower gripping may each be constituted by a rubber tube (38) which is inflatable against the side of the pile via a thin pivotal strip (36). Stamps are withdrawn individually from the bottom of the pile to be gummed by rotating gumming device (10), to be attached to a package P, eg a cigarette packet. <IMAGE>

Description

SPECIFICATION Feeding stacks of sheets This invention relates to apparatus for feeding stacks of sheets, in particular stacks of stamps for application to cigarette packets.

In many sheet processing operations sheets of material are held in a vertical stack from the bottom of which they are withdrawn one at a time for the required processing. For example, in cigarette packing machines revenue or closure stamps are withdrawn singly from the bottom of the stack of stamps by a suction device, each stamp next has a layer of adhesive deposited on it and is then applied to the top of a cigarette packet. With such machines, which currently operating at speeds in the order of 300 to 400 packets per minute, it becomes necessary for an operator to manually load a new batch of stamps onto the top of the stack at very frequent intervals.

if it is attempted to increase the height of the stack, so that a larger batch of stamps can be loaded at a time, problems may arise in the regular withdrawal of stamps at the bottom of the stack, in that the suction device may miss a stamp or withdraw more than one stamp.

According to the present invention there is provided apparatus for feeding a stack of sheet, comprising means defining a stack of superposed sheets, means for withdrawing sheets singly from the bottom of the stack, an upper and a lower gripping means for gripping the sides of the stack, and actuating means to cause said upper and lower gripping means to be alternately actuated so that the part of the stack above the gripping means is supported alternately by the upper and lower gripping means, resulting in an intermittent lowering of said part of the stack as sheets are withdrawn by the withdrawal means.

Preferably a sensor is provided a short distance above the upper gripping means to provide a warning to the operator that the stack requires replenishing. If the level in the stack is always maintained above said sensor, and provided the space between the upper and lower gripping means is small, the weight of the stack above the withdrawal means will remain practically constant, thereby providing optimum conditions for withdrawal of stamps at the bottom of the stack.

Each gripping means may comprise a tubular inflatable member disposed along one side of the stack parallel to the edges of the sheets therein; and the actuating means may then comprise a pair of valves connecting each inflatable member to a source of air pressure, and driven cam means operating alternately on the valves to allow pressure in alternate inflatable members to be released. Between each inflatable member and said one side of the stack there may be interposed a thin pivotal member to distribute the resultant gripping pressure along the edges of the respective sheets.

For a better understanding of the invention, and how it may be put into effect, an example of apparatus according to the invention will now be described with reference to the accompanying drawings, in which: Figure 1 is a front view of apparatus according to the invention; Figure 2 is a section taken on the line ll-ll in Fig. 1; and Figure 3 is a detail of a part of the apparatus not shown in Fig. 1.

Referring first to Figs. 1 and 2, there is shown a vertical stack S of rectangular stamps located at each of its two narrower sides in a fixed channel 2 of C-shaped section. Extending downwards from the bottom of the channels 2 are a pair of lower channels 4 similar to the channels 2, but mounted for pivotal movement about a spindle 6 disposed behind the stack S. At the bottom of the lower channels 4 are ledges 8 which support edges of the stack of stamps.

Beneath the stack is a rotor 10 formed with two diametrically opposed raised portions 1 2 to whose arcuate surfaces suction is applicable.

Pivotal movement is imparted to the lower channels 4 (by means not shown) in timed relation with clockwise rotation of the rotor 10, so that as a raised portion 1 2 comes into contact with the underside of the lowermost stamp in the stack S, the bottom ends of the channels 4 are pivoted anti-clockwise at a peripheral speed corresponding to that of the rotor. Thus the portion 1 2 rolls tangentially into contact with the lowermost stamp which is then pulled away from the ledges 8 by suction applied to the rotor 10.

To the right of the rotor 10 is a gumming sector 1 4 rotatable anti-clockwise at twice the angular speed of the rotor but at the same peripheral speed, and adapted to apply a layer of adhesive to a passing stamp held by suction against a portion 1 2.

Extending horizontaily under the rotor 10 is a conveyor (not shown) which moves towards the left at a speed corresponding to the peripheral speed of the rotor. A succession of packets P (only one shown) are carried by the conveyor in timed relation with movement of the portions 12, so that a stamp with adhesive thereon is transferred to each packet P as the lattter moves under a portion 1 2. A stripper finger 1 6 extends into grooves (not shown) in the portions 1 2 to ensure that each stamp is removed as suction is released.

At the junction between the channels 2 and 4 the central parts of the C-shaped sections thereof are bent outwardly to form inclined fingers 1 8 and 20 respectively. These fingers locate against the narrow sides of the stack S as the lower channel 4 is pivotally moved to its extreme positions (part of the extreme right-hand position of one of the lower channels 4 being shown chain-dotted at 4a in Fig.

1).

Mounted from the upper channels 2 immediately above the fingers 1 8 are a pair of brackets 22 which support two stack gripping assemblies 24 and 26, comprising pneumatic tubes 30 and 31 respectively. Since these assemblies are alike, only the upper one 24 will be described.

A tubular member 28 is mounted from the brackets 22 and supports an end portion of the pneumatic tube 30 whose end is closed by a plug 32. The other end of the tube 30 is connected to a source of air pressure (not shown).

A square aperture 34 is formed in the member 28 at the side facing the stack S; and loosely mounted from the upper channels 2 at a position between the aperture 34 and the stack S is a thin T-shaped metallic strip 36 having a layer of rubber formed on its inner surface for gripping the side of the stack S.

The tube 30, which is made of rubber or a similar resilient material, has a thinner wall section at a portion 38 around the aperture 34, so that when air pressure is appied to the portion 38 it distends through the aperture and grippingly engages the adjacent side of the stack S via the strip 36, as shown in Fig.

2. Alternatively, instead of the tube portion 38 having a thinner section, the other portions of the tube 30 outside the member 28 may be of thicker section or may be supported to prevent their distending.

Referring now also to Fig. 3, there are shown a pair of valves 40, 42 respectively connecting the tubes 30, 31 to a source of air pressure. The valves 40. 42 each have slides 44 connected to roller cam followers 46, which are actuated by cams 48 and 50 respectively. One of the cams is driven clockwise at a speed of approximately 30 r.p.m. and drives the other cam clockwise at the same speed through a toothed coupling belt 52.

The shape of the cams 48. 50 is such that each valve 40 and 42 is closed for about 120 of rotation. The points of closure of the valves are 180 out of phase with one other, and before closing of each valve there is a period of overlap of about 60 when both valves are open. In the position shown in Fig.

3 the cams 48, 50 are at the middle of such overlap position, the valve 40 having been opened by the cam 48 about 30 previously.

In front of each gripper assembly 24, 26 there is connected in the respective tube 30 and 31 a bleed valve 54 incorporating a threaded pointed valve member 56. Adjustment of the member 56 varies the time taken for the portion of the tube 30 or 31, to become deflated after closure of the respective valve 40 or 42.

In operation, stamps are withdrawn from the bottom of the stack S (at a rate of about 350 stamps per minute) by suction being applied to successive raised portions 1 2 of the rotor 1 0, as above described. Thus the level of the stamps in the pivotal lower channels 4 steadily drops.

Commencing from the position shown in Fig. 3 at which both valves 40 and 42 are open so that the stack S is gripped by both assemblies 24 and 26, further rotation of the cam 50 causes the valve 42 to close, allowing air pressure in the tube 31 to be reduced by leakage through the bieed valve 54, until the tube portion 38 of the lower gripper assembly 26 has become deflated. Thereby the Tshaped strip 36 is released, allowing the portion of the stack between the gripper assem biies 24 and 26 to drop along with the lower part of the stack. After some 120 of further rotation of the cam 50, the valve 42 opens, causing re-inflation of the portion 38 of the tube 31, so that the lower assembly 26 again grips the side of the stack.About 60 thereafter the cam 48 closes the valve 40, similarly allowing the air pressure in the tube 30 to be reduced, and the upper gripper assembly 24 to be released, so that the upper part of the stack lowers and becomes supported by the lower gripper assembly 26.

In this manner the gripper assemblies 24 and 26 continue to operate cyclically in the manner of an escapement mechanism, enabling stamps to be fed in a controlled manner towards the bottom of the stack, without allowing the full weight of the stack S to be transmitted to the bottom supporting ledges 8.

When the upper level of stamps in the stack has dripped to just above the upper assembly 24, the operator needs to manually replenish the stack. In order to give some advance warning of this situation to the operator, a stack sensor 58 (e.g. a photoelectric cell) is positioned above the assembly 24. Provided the level of the stack does not drop below the assembly 24, the apparent weight of the stack at the ledges 8 will remain practically constant, fluctuating only at each cycie of operations of the assemblies 24 and 26 due to the weight of stamps therebetween.

It is, of course, possible to allow the level of the stack S to drop to the lower channel 4, but it will then be more difficult to replenish the stamps through the gripper assemblies 24 and 26.

If withdrawal of the stamps from the bottom of the stack is to be inhibited for some time while the machine continues running (e.g. if there is a discontinuity of packets due to some packets being rejected), it is arranged that the drive to the cams 48, 50 is interrupted so that the full weight of the stack does not tend to be transmitted to the ledges 8.

Though the valves 40 and 42 are described above as being operated mechanically by the cams 48 and 50, they may instead be electromechanically operated from an oscillating circuit whose frequency may be coupled to the speed of the machine.

Claims (6)

1. Apparatus for feeding a stack of sheet, comprising means defining a stack of superposed sheets, means for withdrawing sheets singly from the bottom of the stack, an upper and a lower gripping means for gripping the sides of the stack, and actuating means to cause said upper and lower gripping means to be alternately actuated so that the part of the stack above the gripping means is supported alternately by the upper and lower gripping means, resulting in an intermittent lowering of said part of the stack as sheets are withdrawn by the withdrawal means.

2. Apparatus as claimed in claim 1 in which each said gripping means comprises a tubular inflatable member disposed along one side of the stack parallel to the edges of the sheets therein.

3. Apparatus as claimed in claim 2 in which said actuating means comprises a pair of valves connecting each inflatable member to a source of air pressure, and driven cam means operating alternately on the valves to allow pressure in alternate inflatable members to be released.

4. Apparatus as claimed in claim 2 or claim 3 in which between each inflatable member and said one side of the stack there is interposed a thin pivotal member to distribute the resultant gripping pressure along the edges of the respective sheets.

5. Apparatus as claimed in any one of claims 1 to 4 and further comprising a stack sensor disposed above the gripping means to indicate when replenishment of the stack is required.

6. Apparatus for feeding a stack of sheets substantiaily as herein described with reference to, and as illustrated in, the accompanying drawings.