DE1812960U - BOW ARCH. - Google Patents

Description

The! Price increase concerns a bow offshoot, which it arches fed by a conveyor in the form of an aligned Stack of sheets, with oscillating plates arranged on both sides of the stack, which periodically move inwards (on moved towards the stack) and outwards (away from the stack)

Such sheet depositors are used, for example, in cross cutters, i.e. in machines which have one of a Cut the roll or the like unwound paper web into individual sheets, which are then deposited on the stack · Sheet depositors are also used in other machines, for example for printing machines or the like

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The sheets to be deposited can also consist of a material other than paper, for example plastic or metal * With the previously known bow offshoots difficulties arise with regard to the precise alignment of the edges of the stack. These difficulties occur in particular when the arches are too soft (not sufficiently rigid) in relation to their size or when a relatively large friction occurs between the arches, for example as a result of relatively rough or "sticky" surface texture of the sheets or as a result the weight of the same. The vibrating plate is in this palle push back the protruding sheet edge when you move inwards, but the sheet as a whole is not in its correct position is shifted, but only a corrugation is created near its edge, which disappears again, when the swing plate moves outward away from the stack. A misaligned stack will cause high additional costs, since the stack has to be aligned by hand or in some other way or a trimming the edges is required, which also results in a loss of material.

In order to avoid this disadvantage, it has already been proposed to provide a Yibrator, which rapid vibrations (30 vibrations per second or more) that act on the stack. However, this measure was unsuccessful

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"Either the generated vibrations were too weak to have any effect at all, or - with a considerably increased amplitude of the vibrations - the result was that the alignment of the stack was worse instead of better. This disadvantage stems from the fact that the pulses generated were too act on the stack at any time, so that the already aligned sheets "swim * ¹ " due to the generated vibrations and migrate out of the stack} This undesirable effect occurs especially when the sheets have a smooth surface or when air is trapped between them is·

The hiring is based on the task of eliminating these laughable parts and creating a sheet offshoot that too Allows safe alignment of the sheet edges under difficult conditions, and it is also easy to use Construction, cheap to manufacture and safe to operate.

The essence of the innovation is that the vibrating plates are provided with a device through which they at the end of their inward movement a brief mechanical shock is given · This mechanical shock takes place preferably in IO ^ m of a hard blow, which on the Oscillating plates are exerted when they have finished their inward movement.

Further details of the innovation can be found in the following

Description of an embodiment and from the claims.

FIG. 1 is an end view of a sheet feeder according to FIG ! fire

»Figure 2 is a side view of this sheet feeder.

, Figure 3 is an end view on a smaller scale with schematically drawn actuating device for the oscillating plates *

Figure 4 is a plan view of a rapping device

Fig. 5 is a section along 5-5 of Fig. 4

Fig # 6 is a partial cross section of a vibrating plate.

Fig »1 and 2 show a rectangular plate 2, which on their four corners is suspended by means of the chains 4. These chains are in a known manner with a (not shown in the drawing) Connected drive device through which the plate 2 can be raised or lowered * The raised and lowered Plate 2 carries a removable sub-frame 6 on which the individual sheets are placed in the form of an aligned stack 10 will.

The sheets to be deposited are guided onto the stack by means of a conveyor belt. Fig. 2 shows one above the incoming Arches arranged, downwardly inclined endless belt 14, which the arches forwards (to the right of Fig * 2) and after below directs * The arches come to rest when they are with one

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A plurality of stops 18 (cf. also Pig * 1) come into engagement, which on a rod 20 arranged in the transverse direction "are attached. The stops 18 align the leading edges of the sheets.

Above the stack 10, two horizontal shafts 22 and 24 (FIG. 1) are arranged, which are parallel to the direction of movement of the arches extend * The shafts 22 and 24 are supported in bearings 26 (Fig. 2), with fixed horizontal ones Rods 28 (Mg · 2) are connected, which are transverse to the direction of movement of the arches are arranged * With the shafts 22 and 24 clamping sleeves 30 and 32 (Fig * 1) are connected, which according to carry arms 34 and 36 pointing downwards. The oscillating plates 38 and 40 are connected to the arms 34 and 36.

The shafts 22 and 24 perform a reciprocating angular movement so that the oscillating plates 38 and 40 follow each other inwards (towards the stack) and outwards (away from the stack), whereby they move the vertical in the two end positions Position of Fig * 1, in which they are with the edges of the Stack 10 located sheets come into engagement, and assume the position indicated by dotted lines in FIG. 3, in which they have a certain distance from the stack.

The drive of the swing plates can for example be in the in the type indicated schematically in FIG. 3. The shaft 22 is here connected to a lever arm 42, which is supported by a push rod 44 is controlled. The bumper 44 is mounted at 46

and carries a roller 58 at its lower end. A spring 60 in conjunction with a sleeve 62, the push rod 44 seeks to push downwards · The roller 58 stands with a cam disk 48 in engagement, which is mounted on a shaft 52. the Shaft 52 is continuously driven by a motor 56 via a gear 54. The cam 48 has a protruding one Part 50. The bumper 44 remains at rest until the protruding part 50 of the cam 48 engages the roller 58 * Once if this is the case, the projection 50 lifts the roller 58 and thus the bumper 44, so that the oscillating plate 38 moves outward. As soon as the projection 50 leaves the roller 58 has, the spring 60 presses the push rod 44 downwards, so that the wing plate 38 returns to its vertical position returns in which it engages the stack 10

The oscillating plate 40 on the other side of the stack is driven synchronously with the visual oscillating plate 38 in the same way. For this purpose, the shaft 24 is connected to a lever 70 which is actuated by a push rod 72 in the same (in FIG Drawing not shown) way is operated.

As far as described so far, these are known parts of an arch offshoot.

According to the invention, the vibrating plates 38 and 40 with a Device provided by which they are given a brief mechanical shock at the end of their inward movement. The preferred embodiment of such a device is

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an electrically "actuated tapping device 74 (Pig · 1 and 2). This device contains a coil and an armature, which acts like a hammer, and a sharp one on the vibrating plate Impact when engaging the stack at the end of its inward travel. Preferably for each of the Oscillating plates used two rapping devices 74, as in FIG Pig. 2 shown.

Each of the rapping devices 74 (Pig x 4) contains a coil 78 (Pig x 4), a laminated U-shaped core 76, a ϊ-shaped anchor 80 and U-shaped guide pieces 82 through which the armature 80 is guided and its outward movement (to the left of the pig * 4) is limited inside the coil 78, which limits the inward movement (to the right of Pig # 4) of the armature 80 when the latter is energized the coil 78 is moved to the right of the Pig * 4. The core 76 is connected to a rectangular base plate 86, which is fastened to the oscillating plate by means of screws 88

At the left end of the Pig · 4, the anchor 80 has two spaced eyelets 90 and 92 (see * also Pig »5)» The eyelets 90 and 92 have bores into which a pin 94 is inserted. A tension spring 96 is with the pin 94 on the one hand and connected to a bracket 98 on the other hand, which is attached to a U-shaped bracket 100. The bracket 100 is Arranged in the form of a bridge over the rapping device 74 j its ends 102 are by means of the screws 104 and the nuts 106

connected to the vibrating plate. The spring 96 seeks to pull the armature to the left of FIG. If coil 78 receives current, so the anchor 80 is pulled to the right of Figure 4 and comes engages stop 84 with a sharp blow. If the coil 78 is de-energized, the armature is retracted by the spring 96 drawn to the left of FIG.

* 3 shows schematically how the knocking devices are actuated when the vibrating plates come into engagement with the stack. I _n Fig. 3 are shown only two knock devices 74, each vibrating plate includes a tapping device * Is understood that is used in practice, a plurality of knock devices for each of the vibrating plates, for example two, as shown in FIG. 2. The coils of all of these rapping devices are connected in parallel.

In Fig. 3, the knockers 74a and 74b are parallel switched; they are in series with a current source 112 and a normally open switch 114. The switch 114 has an actuator 116 which is actuated by a lock 118 which is arranged on the shaft 52 is controlled. The cam-118 is designed in such a way that it actuates the member 116 and thus closes the switch 114 when the oscillating plates are with it the stack 10 come into engagement. As soon as the switch 114 closes, the coils 78 of the knocking devices receive power. The switch 114 is only briefly closed by the cam 118, every time the vibrating plates with the

Stack come into engagement.

The anchor 80 can, for example, have a weight of 60 g with the coil 78 exerting an initial pull of 1.5 to 2.5 kg on the armature. "This pull increases rapidly up to a maximum of 6 to 8 kg when the armature touches the stop 84 · The movement of the armature is so rapid that it occurs almost instantaneously; the energy transmitted through the armature is about 0.85 mkg · Depending on the conditions of the In individual cases, the weight of the anchor and the energy exerted by it can of course also assume any other value.

The return of the armature does not necessarily have to be done by a spring; it can also be done by gravity or in any other way.

Normally, the vibrating plates are moved inwards after each sheet is deposited. But you can also go slower be moved, for example after depositing every second sheet, without leaving the basic idea of the innovation, there the knocking devices are synchronized with the drive of the oscillating plates and not with the sheet deposit. Likewise can the knocking devices can also be actuated in a different way, for example with every third inward movement of the oscillating plates » Others can also be used to control the knocking devices Means can be used as the cam 118.

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Likewise, instead of the coils 74, other devices can be used which trigger a hammer-like impact. For example, compressed air operated hammers controlled by a valve which is operated mechanically or electrically, or by gravity, spring force or the like # operated hammer, the be held by a claw, which is withdrawn electrically or in some other way at the desired time will·

In Figures 2 and 6, a modified embodiment is shown in FIG Oscillating plates shown. Here, the vibrating plates contain a plurality of bores 120. Fig. # 6 shows one enlarged! partial cross-section of such an oscillating plate 40. The inner surface of the vibrating plate is designated with the reference number 122, and the outer surface with the reference number 124. The inner surface is that surface which comes into engagement with the stack 10. As can be seen from Fig. 6, have the bores 120 on the inside have a conical expansion 120a. The bores 120 are used for the passage of air «If the oscillating plates move inwards, i.e. towards the stack, push the air in front of them. Have the rocker plates no holes so they pump air into the pile so that the top sheets are raised, which is their orientation difficult. The bores 120 allow the air to pass through during the inward movement of the oscillating plates

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is compressed between these and the stack

This disadvantageous effect is reduced by the conical enlargement of the bores 120 «The conical enlargements 120a encourage the air to flow outwards, while the outer, sharp-edged openings encourage the inward movement of the Affect air. In order to support this effect, the movement of the oscillating plates can be adjusted by suitable shaping of the Cam 48 of the Pig »3 can be modified in such a way that the oscillating plates move slowly inwards and quickly outwards. In this way it can be achieved that the air is pumped out of the stack, so that a minimum of air during the Inward movement of the vibrating plates gets into the stack.

Another modification is that valve flaps, for example made of soft leather, on the outside of the Oscillating plates are arranged which cover the bores 120. Such a Yentilklappe is indicated in Pig · 6 is denoted by the reference number 125 · It is at its upper end, for example by pins 126 or by gluing, attached to the swing plate 40. During the inward movement of the oscillating plate (to the right of the Pig »6) it can move the in Pig «6 assume the position indicated by the dotted lines.

The innovation is not limited to the illustrated and described exemplary embodiments, but also includes Modifications within the framework of the S firing concept presented lie.

Claims (16)

Munich, April 12, 1960 Claims for protection 1. Sheet feeder, which is given to him by a conveyor fed sheets in lOrm of an aligned stack of sheets with oscillating plates arranged on both sides of the stack, which periodically move inwards (towards the stack) and to the outside (away from the stack), characterized in that the oscillating plates (38, 40) with devices (74) are provided, through which they are given a brief mechanical shock at the end of their inward movement will. 2. Device according to claim 1, characterized in that the oscillating plates (38, 40) with knocking devices (74) are provided, which exert a sharp blow on the oscillating plates at the end of the inward movement of the same. 3 # device according to claim 1 and 2, characterized in that that the knocking devices (74) are based on mechanical, hydraulic, be operated pneumatically or electrically. 4 # device according to claim 1 "to 3> characterized in that the actuation of the knocking devices (74) by the same drive device (52, 50, 58, 44, 42) takes place, which controls the movement of the oscillating plates (38, 40). 5 * Device according to one of claims 2 to 4, characterized characterized in that actuation of the knocking devices (74) after each first, second, third or subsequent inward s movement of the oscillating plates (38, 40) takes place 6 # Device according to one of claims 2 to 5, characterized characterized in that one or more knocking devices (74) are arranged on each of the oscillating plates (38, 40). 7. Device according to one of claims 2 to 6, characterized in that the knocking device is an electrically controlled Device (74) is used which contains an armature (80) actuated by a coil (78, Pig · 4), which, when the coil (78) is supplied with current, strikes against a stop (84), which is applied directly or via suitable intermediate links is connected to the vibrating plate and thus given her a sharp blow. 8. Device according to claim 7, characterized in that that the impact occurs by the forward movement of the armature (80). 9 # Device according to claim 7 and 8, characterized in that that the armature (80) of the knocking device (74) when the coil (78) is de-energized in a manner known per se by a l? eder (96), by gravity or otherwise in its starting position is returned. 10 · Device according to one of claims 7 to 9, characterized characterized in that the coils (78) are supplied with current through a switch (114, 116) which is operated by the drive device (52, 50, 44, 42) for the oscillating plates (38, 40) is controlled. 11. Device according to one of claims 1 to 10, characterized in that a shaft (52, Fig. 3) which has a squat (50) or the like. to actuate the oscillating plates (38, 40) carries, with a second cam (118) or the like * is provided which the Actuation of the knocking devices (74) controls 12. The device according to claim 11, characterized in that that the squat (118) controls a switch (114) which controls the circuit for the coils (78) of the knocking devices (74) closes. 13. Arch deposit, in particular according to one of claims 1 to 12, characterized in that the oscillating plates (38, 40) are provided with bores (120). 14. The device according to claim 13, characterized in that that the bores (120) are widened conically inwards (extension 120a, Pig · 6). 15 · Device according to claim 13 or 14, characterized in that - 4 - shows that the bores (120) with valve flaps (125) od * like * are provided, which allows an air flow through the Allow holes through to the outside, but prevent such holes inwards. 16. Device according to one of claims 13 to 15, characterized characterized in that the oscillating plates (38, 40) are controlled so that they move quickly outwards and slowly inwards move.