DE10250149A1 - Sheet feeder for printer, directs airstream to stack of sheets and has rest plates which rest on uppermost sheet to compensate for force acting against conveying direction - Google Patents

Abstract

The sheet feeder has a carrier (14) for receiving a stack of sheets, and a pneumatic device (36) for releasing the uppermost sheet from the stack. A conveying device conveys the released sheet into the printer. The pneumatic device directs an airstream to the stack of sheets. Rest plates (52,54) are provided for resting on the uppermost sheet, and have a weight so as to compensate for the force acting against the conveyance direction on the uppermost sheet owing to the airstream.

Description

The invention relates to a single sheet feeder for one Printer.

In the EP 1 090 859 A1 describes a single sheet feed device for a printer in which a sheet stack consisting of single sheets is received in a carrier and the single sheets are successively transported from a conveyor belt into the printer. The feed device comprises a front nozzle which directs an air flow against the transport direction onto the sheet stack, a side nozzle which directs an air flow transversely to the transport direction onto the sheet stack, and a suction device which directs the uppermost single sheet released by the air flows from the sheet stack towards the conveyor belt sucks. These air flows are coordinated with one another in terms of space and time so that the uppermost single sheet is released as reliably as possible from the single sheets underneath and the latter are pressed down onto the sheet stack.

Towards the front nozzle The air flow directed towards the stack of sheets supports this Solving the uppermost cut sheet from the stack of sheets by moving between them Single sheet and the rest of the sheet stack creates an overpressure. Because of this overpressure the top single sheet becomes something of the sheet stack below it lifted. So that overpressure is effectively built, two support elements are provided, the in the area of the front nozzle The opposite end of the uppermost cut sheet rest on the latter. The one from the front nozzle Air flow not only causes the desired overpressure, but also exercises one against the transport direction on the top single sheet acting force. This force is displaceable in the carrier arranged stop compensated by moving it into the system to that facing away from the front nozzle Side of the sheet stack can be brought. Is the stop on the named side of the stack of sheets, so it works through force against the air flow caused, so that a displacement of the top Single sheet avoided in the direction of transport due to this force can be.

The stop can move Avoid the top single sheet in the direction of transport, provided he's over a certain length directly on the front nozzle edge of the single sheet facing away. With usual Single sheets with straight edges and the same blade length possible without any problems. However, difficulties arise when using single sheets, for example that have different, non-continuous straight edges. Then namely the unfavorable Case that the corresponding edge of the top single sheet not up to the reaches the stop lying against the sheet stack, i.e. the top one Single sheet itself does not directly touch the stop. In the The force acting in the direction of transport can shift the uppermost one Cut sheet on the underlying stack of sheets, which in turn skewed of the single sheet and thus to faults in sheet transport, in particular lead to misfeeds can.

Single sheets with different non-continuous straight edges are, for example, so-called Divider or tab sheets. These single sheets each have an edge with an elongated recess is. The edge of such a single sheet thus has a first rectilinear section and an offset in relation to this second straight section, the two sections mentioned by a step section running essentially perpendicular to them are interconnected. If the sheet stack consists of single sheets with recesses of different lengths of the type mentioned above, so the top single sheet is only directly against the stop, if it faces the stop with its first section. In the area of the second section, however, there is no direct investment given the stop so that it come to the displacement of the single sheet described above can.

The state of the art is still on EP 0 801 016 A1 which have a feed device corresponding to that in the EP 1 090 859 A1 shows described, as well as the US 5,356,127 and the US 5,707,056 , each showing a cut sheet feeder for a printer that uses air currents to separate the cut sheets from a sheet stack.

The object of the invention is a Single-sheet feeder for one Specify printers that have a shift of cut sheets with differently shaped sheet edges in the carrier due to an opposite avoids the air flow acting in the direction of transport.

The invention solves this problem by a single sheet feed device for a printer, comprising a carrier for receiving a sheet stack consisting of single sheets, a pneumatic device for releasing the uppermost single sheet from the sheet stack and a transport device for transporting the detached single sheet into the printer, the Pneumatic device for releasing the uppermost single sheet directs an air flow against the transport direction on the sheet stack, and at least one support element designed to rest on the uppermost single sheet is provided, the weight of which is dimensioned such that the air flow against the trans force acting on the top single sheet is compensated.

By dimensioning the invention Weight of the support element resting on the single sheet can a displacement of the single sheet caused by the air flow against the direction of transport and thus leading to misfeeds skew of the single sheet reliably be avoided. The weight of the support element is on the force caused by the air flow. So on the one hand this force effectively compensates and on the other hand the loosening of the top single sheet is not affected by the sheet stack.

In the single sheet feeder according to the invention can sheet stacks consisting of single sheets are now also processed, whose sheet edges facing away from the air flow are different from one another are. This applies in particular to Divider or tab sheets, each one with an elongated one Have recessed edge, the length of this recess of sheet is different from leaf. The processing of such single sheets in one for one Printer specific cut sheet feeder was previously difficult due to the problem described at the beginning, if not impossible.

To better understand the The present invention will hereinafter be referred to in the drawings illustrated preferred embodiment Reference that described using specific terminology is. However, it should be noted that the scope of the invention not restricted by this should be because of such changes and further modifications to the device shown and such further applications of the invention, as shown therein, as usual current or future Expertise of a responsible Be considered professional.

The figures show an embodiment of the Invention, namely

1 a side view of a single sheet feeder according to the invention,

2 a plan view of the single sheet feeder,

3 a longitudinal section of part of the in the 1 and 2 feed device shown,

4 a perspective view of the in 3 shown part of the feed device,

5a and 5b perspective views of a side nozzle,

6 1 shows a schematic illustration to illustrate how individual components of the feed device are arranged relative to one another,

7 a detailed perspective view of in 6 shown support elements, and

8th a plan view of two single sheets used in the embodiment.

In the 1 and 2 is a single sheet feeder 10 shown for a printer, not shown. The feeder 10 is used from a sheet stack consisting of single sheets 12 in a carrier designed as a drawer 14 is arranged to pull off the single sheets one after the other and feed them to the printer.

The feeder includes the carrier 14 and a suction belt conveyor 16 that over the carrier 1 and thus above that in the carrier 1 recorded stack of single sheets 12 is arranged. The suction belt conveyor 16 includes a suction box 18 and an endless conveyor belt running around it 20 , The bottom of the suction box 18 and the conveyor belt 20 are each provided with holes, not shown, which are arranged in a regular pattern. Where the holes of the suction box are 18 and that of the conveyor belt 20 overlapping each other, air passages are formed through which an upward air flow can be generated, as in 1 by the arrows between the suction belt conveyor 16 and the carrier 14 is indicated.

This airflow is generated by a first fan 22 generated, the inlet side via an intake line 24 with the suction box 18 connected is. A solenoid valve 26 that in the intake pipe 24 is arranged, allows the upward air flow between the carrier 14 and the suction belt conveyor 16 to take effect when the fan 22 is operating to the top cut sheet from the sheet stack 12 against the suction belt conveyor 16 to suck. That from the stack of sheets 12 Single sheet is then sucked through the conveyor belt 20 from the sheet stack 12 deducted. The entry of the removed single sheet into a transport gap, not shown, arranged in the output path is detected by a light barrier, not shown, whereupon the conveyor belt 20 is stopped. The single sheet, which at this point is already at least partially in the printer, is then transported further in this by a transport device, not shown, and printed by a printing unit.

The feeder 10 further includes a second fan 28 that to an outlet pipe 30 is connected, the outlet opening laterally, ie transversely to the transport direction of the single sheets, on the in the carrier 14 picked sheet stack 12 is directed. The orientation of the second blower 28 Airflow generated is from one at the outlet end of the outlet conduit 30 arranged side nozzle 32 determined in the 5a and 5b is shown in more detail. The second blower 28 serves to pass air through the outlet line 30 on the sheet stack 12 to blow. The one from the second blower 28 generated airflow fanned out the top single sheets a little and pushed the top single sheet up to the suction belt 16 out. The air flow thus forms a flow nucleus for blowing air between the single sheets 12 to separate them.

The feeder 10 also includes a third blower 33 that to an outlet pipe 34 connected. At this outlet end there is an in 4 shown front nozzle 36 , which directs an air flow from the front, ie against the transport direction, to the upper single sheets. This air flow aids in detaching the top single sheet from the sheet stack 12 by placing it between the top cut sheet and the rest of the sheet stack 12 creates an overpressure. This overpressure presses those single sheets that are below the uppermost single sheet firmly onto the sheet stack 12 , This can prevent these single sheets from coming off the sheet stack 12 to solve.

In the 5a and 5b is the side nozzle 32 shown in perspective. The side nozzle 32 has the function of the side of the sheet stack 12 to split the air flow into several air flows that have different flow characteristics. In their interaction, these air flows with their own flow characteristics ensure that the uppermost single sheet is reliably removed from the sheet stack 12 is solved. The side nozzle 32 is designed as an insert into the outlet opening of the outlet line 30 is used. The side nozzle 32 includes several nozzle parts 38 to 48 whose function in detail in the EP 1 090 859 A1 on page 2, line 26 to page 3, line 4 is described.

3 shows part of the feeder 10 in a section along the transport direction. 4 shows this part in a perspective view. As in 3 shown, the front nozzle is blowing 36 an air flow 50 from the front onto the single sheets 12 to get air between that against the conveyor belt 20 sucked single sheet and bring the single sheet underneath, whereby the latter on the sheet stack 12 is pressed. The front nozzle 36 has a slit-shaped opening 37 whose central part 37 ' is more open than either side of this part 37 ' lying parts 37 '' , as in 4 is shown. The airflow 50 is therefore larger in the middle than on its sides, which creates a suitable pressure below the top single sheet.

As in 4 are shown in the feeder 10 a first support element 52 and a second support element 54 provided that in 7 are shown in detail. The support elements 52 and 54 lie on the top surface of the top single sheet. As later referring to 7 the support elements are explained 52 and 54 each with a light barrier assigned to them 56 respectively. 58 together.

6 shows a top view of the carrier 14 , from which in particular the spatial arrangement of the two support elements 52 and 54 evident. The support elements 52 and 54 lie on a section of the top single sheet, that of the air flow that the side nozzle 32 across the transport direction onto the sheet stack 12 and the intake flow that the suction belt conveyor 16 generated and the in 6 is directed vertically upwards, remains largely unused. The first support element 52 is in the area of the side nozzle 32 facing edge section of the uppermost single sheet extending in the transport direction. The second support element 54 is opposite the first support element 52 arranged transversely to the direction of transport and is closer to that of the side nozzle 32 edge section facing away from that of the side nozzle 32 facing edge section of the top single sheet.

In the carrier 14 are a first stop that can be moved parallel to the transport direction 60 and a second stop that can be moved transversely to the transport direction 61 arranged. The first stop 60 is intended to be in contact with the front nozzle 36 opposite side of the sheet stack 12 to be brought up during the second stop 61 is intended to be in contact with the side nozzle 32 opposite side of the sheet stack 12 to be brought. Through the two stops 60 and 61 can the sheet stack 12 in the carrier 14 be fixed.

The stack of sheets 12 single sheets forming in this embodiment are so-called separator or tab sheets. In 8th two of these single sheets are shown, with 62 and 64 are designated. The single sheets 62 and 64 have each at their first stop 60 facing edge an elongated recess 66 respectively. 68 , The single sheet 62 points due to the elongated recess 66 an edge 70 on, which consists of a first straight section 72 , a second rectilinear section offset in relation to this 74 and a step section 76 composed, which is substantially perpendicular to the two sections 72 and 74 runs and connects them together. The single sheet points accordingly 64 one the first stop 60 facing edge 78 based on a first section 80 , a second section 82 and one of the two sections 80 . 82 interconnecting step section 84 composed.

In 8th is in addition to the two single sheets 62 and 64 the first stop 60 shown to make it clear that this when it is on the front nozzle 36 opposite side of the sheet stack 12 only with the edge 78 of the single sheet 64 comes into direct contact, but not with the edge 70 of the single sheet 62 , The one from the front nozzle 36 escaping air flow against the transport direction force acting on the top single sheet is therefore by the first stop 60 only for the single sheet 64 effectively compensated as the top single sheet, but not for the single sheet 62 , Because the first stop 60 not directly with the single sheet 62 is in contact, this can be done through the The above-mentioned force is shifted against the transport direction and, in the worst case, rotated so that the single sheet skews 62 comes. Such a skew can lead to malfunctions in single sheet transport, in particular to misfeeds.

In order to solve the problem described above, the support elements are 52 and 54 According to the invention dimensioned in their weight so that they by the air flow from the front nozzle 36 Compensate the force acting on the uppermost single sheet, so that a displacement of this single sheet in the transport direction or even twisting is prevented. In the present embodiment, the two support elements 52 and 54 , as in 7 shown, each as a plastic lever 86 respectively. 88 trained on which an additional weight 90 respectively. 92 is appropriate. The plastic levers 86 and 88 each have a weight of about 2 g and the additional weights in this embodiment 90 and 92 each a mass of about 10 g. The support elements 52 and 54 thus each have a total weight that is just such that on the one hand the compensation of the air flow from the front nozzle 36 force compensated for on the top single sheet and on the other hand the reliable release of the top single sheet from the sheet stack 12 through the air flows from the two nozzles 32 and 36 and the suction belt conveyor 16 are generated is guaranteed.

The plastic levers 86 and 88 of the two support elements 52 and 54 are each on a bearing rod 94 stored, which is mounted in the carrier. The two support elements 52 and 54 act solely on the weight of the top single sheet on which they rest. In the present embodiment, the support elements 52 and 54 each with the additional function with the light barrier 56 or the light barrier 58 cooperate to fill the sheet stack 12 in the carrier 14 capture. For example, the light barrier 56 formed as a transmitted light barrier, which consists of a light emitting part 96 and a light receiving part 98 consists. One piece on the plastic lever 86 of the first support element 52 trained engagement part 100 is located outside of between the light emitting part 96 and the light receiving part 98 lying area when in the carrier 14 there is still at least one single sheet on which the support element 52 and thus the engaging part 100 rest. As soon as the last single sheet from the carrier 14 is removed, the engaging part falls 100 as it were in a support surface of the carrier, not shown 14 trained recess and thus reaches the above area between the light emitting part 96 and light receiving part 98 the light barrier 56 , whereby a signal is detected. This signal indicates that there is no single sheet left in the carrier 14 located. Via a correspondingly modified arrangement, which consists of the second support element 54 and the light barrier 58 there may be a drop in the fill level of the sheet stack 12 in the carrier 14 below a predetermined fill level value, which is determined, for example, by a predetermined number of single sheets.

Although in the drawings and the previous description of a preferred embodiment is shown and described in detail, this should be considered pure by way of example and not to limit the invention. It it is pointed out that only the preferred embodiment is shown and described and all changes and modifications, the present and future to be protected within the scope of the invention.

10

Single-sheet feeder

12

sheet stack

14

carrier

16

suction belt

18

suction box

20

conveyor belt

22

first fan

24

suction

26

magnetic valve

28

second fan

30

outlet pipe

32

side air

33

third fan

34

outlet pipe

36

front nozzle

38 to 48

Nozzle parts of the side nozzle 32

50

airflow

52.54

support elements

56.58

light barriers

60.61

attacks

62.64

Single sheets

66.68

recesses

70

Sheet edge of the single sheet 62

72

first section of the sheet edge 70

74

second section of the sheet edge 70

76

Step section of the sheet edge 70

78

Sheet edge of the single sheet 64

80

first section of the sheet edge 78

82

second section of the sheet edge 78

84

Step section of the sheet edge 78

86.88

Plastic lever

90.92

weights

94

bearing rod

96

Light transmission part of the light barrier 56

98

Light receiving part of the light barrier 56

100

Engagement part of the plastic lever 86

Claims (8)

Single sheet feeder ( 10 ) for a printer comprising: a support ( 14 ) to accommodate a single sheet tern ( 62 . 64 ) existing stack of sheets ( 12 ), a pneumatic device ( 22 to 36 ) for detaching the top single sheet from the sheet stack ( 12 ) and a transport device ( 20 ) for transporting the detached single sheet into the printer, the pneumatic device ( 22 to 36 ) to release the top single sheet, an air flow against the transport direction on the sheet stack ( 12 ) and at least one support element designed to rest on the top single sheet ( 52 . 54 ) is provided, the weight of which is such that the force acting on the uppermost single sheet by the air flow against the transport direction is compensated. Single sheet feeder ( 10 ) according to claim 1, characterized by a light barrier ( 56 . 58 ) which are used to record the fill level of the sheet stack ( 12 ) in the carrier ( 14 ) with the support element ( 52 . 54 ) interacts. Single sheet feeder ( 10 ) according to claim 1 or 2, characterized in that the support element ( 52 . 54 ) a pivoted plastic lever ( 86 . 88 ) on which an additional weight ( 90 . 92 ) is attached, through which the weight of the support element ( 52 . 54 ) is essentially determined. Single sheet feeder ( 10 ) according to claim 3, characterized in that the plastic lever ( 86 . 88 ) a mass of about 2 to 4 g and the additional weight ( 90 . 92 ) has a mass of about 10 to 30 g. Single sheet feeder ( 10 ) according to one of the preceding claims, characterized in that the carrier ( 14 ) a stop ( 60 ) includes the side of the sheet stack facing away from the air flow mentioned () 12 ) can be moved along the transport direction. Single sheet feeder ( 10 ) according to one of the preceding claims, characterized in that the pneumatic device ( 22 to 36 ) a first nozzle, which directs the air flow against the transport direction onto the sheet stack to release the uppermost single sheet, a second nozzle ( 32 ) which, to loosen the uppermost single sheet, a further air flow across the transport direction onto the sheet stack ( 12 ) and a suction device ( 16 ) which is caused by the air currents from the sheet stack ( 12 ) detached single sheet for the transport device ( 20 ) sucked in. Single sheet feeder ( 10 ) according to claim 6, characterized in that two support elements ( 52 . 54 ) are provided which are arranged so that they rest on a section of the uppermost single sheet which is separated from the second nozzle ( 32 ) and the suction device ( 16 ) remains essentially unaffected. Single sheet feeder ( 10 ) according to claim 7, characterized in that one of the two support elements ( 52 ) is arranged in such a way that it rests on the edge of the uppermost single sheet, which runs in the transport direction, that of the second nozzle 32 ) facing, and that the other support element ( 54 ) compared to this support element ( 52 ) is arranged offset transversely to the transport direction.