Sheet sorting apparatus

FIELD OF THE INVENTION

The invention relates to a sheet feeding apparatus for an image processing device such as a printer, copier, or facsimile machine, and more particularly, to a sheet feeding apparatus that separates the sheets into groups.

RELATED ART

A conventional sheet sorting apparatus is located at the sheet output location of the sheet feeding apparatus. When the image processing device outputs sheets, the sheets are piled on a single tray, one by one. If the sheets in the tray make up a single group, and the group of sheets is removed before the next group is output, then there is no problem. However, if multiple groups of sheets are output to the tray, separate groups are not distinguishable.

Previous sheet sorting designs use several methods to distinguish the groups, such as adding an offset function or a ribbon inserting function. The offset function offsets the stack of sheets in each group in the tray. A disadvantage of this method is that the group divisions are easily lost when the sheets are removed from the tray.

The ribbon inserting function inserts a ribbon between each group of sheets. With this design, the sheet feeder must pause while the ribbon is placed on top of the last sheet in a group, and the sheets in the new group can only be output when the ribbon placement is finished. This adds to the total output time of the sheet feeder. Also, the ribbons can easily fall out of the stack of sheets when they are removed from the tray, and the separate groups are again lost.

Another previous design makes use of multiple trays, one for each group. This design leads to a large apparatus and high cost. Moreover, the use of multiple trays is not practical for a small device.

Despite the several developments in the art of separating the sheets into groups, there remains an opportunity to improve the sorting of sheets in an image processing device. In particular, there exists a need for a simple, small and inexpensive apparatus that easily sorts sheets into groups, and makes these groups readily distinguishable on a single output tray.

SUMMARY OF THE INVENTION

The main object of the invention is to provide an apparatus that easily sorts sheets into groups, and makes these groups readily distinguishable on a single output tray. The sheet sorting apparatus should be simple, small and inexpensive.

According to an aspect of the invention, there is provided a sheet sorting apparatus located at the sheet outlet location of an image processing device, the sheet sorting apparatus having marker attaching means for attaching markers at a certain position on the output sheets. The marker attaching means is comprised of a tape feeding mechanism in which the tape has an adhesive surface along one side edge, a cutter for the end of the tape to make a marker, guides to position the marker in the proper location on the output sheet, a marker attaching roller, and a feeder for feeding the sheet and marker together as one unit. The feeder presses the marker against the sheet to attach it. A special adhesive is used on the markers, so that a certain minimum amount of pressure is needed when a marker is adhered to a sheet. This pressure is provided by the feeder.

The image processing apparatus includes input devices such as scanners, OCR systems, copiers, and facsimile machines, which have image reading function, in addition to the output devices already mentioned which have image printing function.

An advantage of this invention is the markers for separating groups are attached to the sheets so that they won't fall out if the sheets are removed from the output tray. Another advantage is there is no pause in the feeding of the sheets to add markers between the groups, so there is no time-loss.

The above features and advantages of the invention will be better understood from the following detailed description taken into conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

a

is the first embodiment of a sheet sorting apparatus of the invention, and

FIG. 1

b

is a part of the uncut marker tape.

FIG. 2

is a diagram illustrating how a marker is positioned on a sheet.

FIGS. 3

a

and

3

b

show markers adhered at similar or different locations on a series of sheets.

FIG. 4

is a simplified view of the second embodiment of a sheet sorting apparatus of the invention.

FIG. 5

is a flow chart showing the operation of the color marking unit controller in the second embodiment.

FIG. 6

is a simplified view of the third embodiment of a sheet sorting apparatus of the invention.

FIG. 7

a

shows the inner structure of a stamper unit,

FIG. 7

b

shows a color pattern selecting cam and

FIG. 7

c

shows a solenoid for controlling the rotation of the color pattern selecting cam.

FIG. 8

is the fourth embodiment of a sheet sorting apparatus of the invention.

FIG. 9

a

is a simplified view of the fourth embodiment, and

FIG. 9

b

shows the tape detection sensor of the fourth embodiment.

FIG. 10

is a simplified top view of the fourth embodiment.

FIG. 11

illustrates how the sheets are sorted on the output tray by the fourth embodiment.

FIGS. 12

a

and

12

b

are simplified views of the fifth embodiment of a sheet sorting apparatus of the invention.

FIG. 13

is an external view of the sixth embodiment of a sheet sorting apparatus of the invention.

FIG. 14

is an internal view of the sixth embodiment.

FIG. 15

is a top view of the sixth embodiment.

FIG. 16

shows the positions of the internal parts after the first forward motor rotation of the sixth embodiment.

FIG. 17

shows the positions of the external parts after the first forward motor rotation of the sixth embodiment.

FIG. 18

shows the positions of the internal parts after the first reverse motor rotation of the sixth embodiment.

FIG. 19

shows the positions of the external parts after the first reverse motor rotation of the sixth embodiment.

FIG. 20

shows the positions of the internal parts after the second forward motor rotation of the sixth embodiment.

FIG. 21

shows the positions of the external parts after the second forward motor rotation of the sixth embodiment.

FIG. 22

is a perspective view of the seventh embodiment of a sheet sorting apparatus of the invention.

FIG. 23

is the inner structure of the seventh embodiment.

FIG. 24

shows the positions of the parts during the first forward motor rotation of the seventh embodiment.

FIG. 25

shows the positions of the parts during the reverse motor rotation of the seventh embodiment.

FIG. 26

shows the positions of the parts during the second forward motor rotation of the seventh embodiment.

FIG. 27

is the eighth embodiment of a sheet sorting apparatus of the invention.

FIGS. 28-32

are the inner structures of the eighth embodiment.

FIG. 33

shows the mechanism of the eighth embodiment.

FIG. 34

is the ninth embodiment of a sheet sorting apparatus of the invention.

FIG. 35

is the tenth embodiment of a sheet sorting apparatus of the invention.

FIG. 36

is the eleventh embodiment of a sheet sorting apparatus of the invention.

FIGS. 37-38

are the twelfth embodiment of a sheet sorting apparatus of the invention.

FIGS. 39-40

are the thirteenth embodiment of a sheet sorting apparatus of the invention.

FIG. 41

is the table of color patterns in the second embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1

is aside view of a first embodiment of the sheet sorting apparatus of the invention. A pair of exit rollers

11

are located near the outlet of an image processing apparatus

10

such as a printer. A sheet

12

is inserted in the rollers

11

, receives feeding force from the rollers, and is ejected out of the apparatus. A receiving tray (not shown) is located beneath the outlet and the ejected sheet

12

falls into the tray. After all sheets are ejected, the group of sheets piled in the tray is picked up.

A sorting machine

14

of the invention is located at the outlet of the image processing apparatus

10

. A marker is attached on sheets by the sorting apparatus. Groups of sheets are divided by the markers so that the groups can be distinguished from one another. An advantage of the invention is the markers are attached without pausing the output of the sheets.

In this embodiment, a tape roll

16

is mounted in a housing

15

. The tape roll is wound with paper tape

17

. The tape is pulled out continuously and fed along a feeding path

19

. The tape, as shown in

FIG. 1

b

, has adhesive

18

applied along an edge of one side of the tape. The adhesive is pressure sensitive and does not adhere to a surface until a certain minimum pressure is applied. The adhesive should be non-permanent and easily detachable, like the adhesive used on sticky memo pads.

At the lower end of the feeding path

19

are a pair of pull-out rollers

20

. The tape

17

is sandwiched by these rollers and pulled out. The surface of one of the rollers

20

has a smaller diameter at one end to avoid placing pressure on the adhesive.

A cutter apparatus

22

is located below the rollers

20

. A marker

24

is formed by cutting the tape at a preset length. As shown in

FIG. 1

b

, all markers have the same size, but the size can be adjusted.

The cutter apparatus

22

includes a lever

22

c

connected to a holder

22

b

of a cutter edge

22

a

. The upper end of the lever

22

c

is connected to a rotation axis

22

d

. The lever swings bidirectionally with a predetermined degree of rotation. The middle of the lever contacts an eccentric cam

22

e

. When the eccentric cam

22

e

rotates, the lever

22

c

is moved along with the cutter holder

22

b

causing the cutter edge

22

a

to move back and forth. The tape

17

is cut by the cutter edge, forming the marker

24

.

After being cut, the marker

24

is guided to the attaching position by a guide

26

. The edge area of the sheet

12

is determined by pressure roller

27

. The sheet and marker are then sandwiched by the pressure roller

27

and roller

28

, and pressed by a predetermined pressure. This pressure causes the marker to adhere to the sheet. In this process, the rotation velocity of the pressure roller

27

and exit rollers

11

is the same. Another advantage of the invention is the marker

24

is attached to sheet

12

without pausing the ejection operation of the sheets.

In this embodiment the pull-out roller

20

, eccentric cam

22

e

, and pressure roller

27

are all connected to the same drive motor (not shown). They are driven at a preset intermittent and timing rate.

A sheet detection sensor

29

is located near the exit rollers

11

. The sensor detects the front edge of a sheet

12

and gives a signal. On receiving the signal, the pull-out rollers

20

rotate and the tape

17

is pulled out to a preset length after a predetermined time. The cutter edge

22

a

then cuts the tape

17

to make a marker

24

. The marker may be attached at the same position on each sheet as shown in

FIG. 3

a

, or at different positions as in

FIG. 3

b

by changing the time to start the cutting of the cutter apparatus

22

. The sensor

29

may be located near the inlet of the sorting apparatus

14

rather than at the exit rollers

11

.

In using the sorting apparatus, a marker may be attached on each sheet or attached once after every predetermined number of sheets (such as every fifth sheet) or every group of documents. When the attaching position varies as shown in

FIG. 3

b

, the same groups may have markers at the same position on each sheet. This way if many groups are stacked on a single tray, all the members of any one group can be easily distinguished.

FIG. 4

shows a second embodiment of a sheet sorting apparatus of the invention. This embodiment is similar to the first embodiment, and the same reference numbers are used to denote parts that are unchanged from the previous description. In this embodiment there is a marking unit

30

located below the cutter apparatus

22

.

The marking unit

30

applies color to the marker

24

. In this embodiment, for example, red, blue, yellow, and green colors can be applied to markers. An ink jet unit can be applied as the marking unit. The nozzles are controlled by a controller

37

, to give any required color. Any ink can be used as a replacement supply. The controller

37

causes the same color to be printed-on each marker

24

that is attached to the same group of sheets based on the control of the image processing apparatus

10

. Thus, different groups of sheets may be printed with different color patterns.

The operation of the controller

37

is shown in FIG.

5

. The print command for a new sheet is applied by the controller (ST

1

). The controller determines if the sorting and printing operations should happen simultaneously, that is, whether or not to prepare a marker (ST

2

). When it is unnecessary to adhere a marker to the next sheet, the inkjet does not operate (ST

3

). If the controller determines it is necessary to adhere a marker to the coming sheet, it then decides on the color to be printed on the marker (ST

4

). If the color will be the same as the previous color that was printed, then no action is necessary. Otherwise the color is changed to the color for the new group.

A color pattern table is shown in TABLE

1

of FIG.

41

. The controller

37

sets the color order from the table. The marking unit

30

prints the selected color pattern on the marker

24

during printing of the same group of sheets. The printed marker is attached to the sheet, and therefore all group members have the same color (ST

5

). After all printing operations are carried out for the sheet, the apparatus prepares for the next operation (ST

6

).

FIG. 6

shows the third embodiment of the sheet sorting apparatus of the invention. In this embodiment, a color pattern is printed by a stamper. In the second embodiment the inkjet printer was used, but in the third embodiment a stamper is used instead. A stamper unit

33

is connected to a solenoid

35

through a link mechanism

34

. The link mechanism rotates around a pivot

34

a

, in both clockwise and counterclockwise directions. The solenoid

35

moves up and down, and the stamper moves back and forth accordingly. The inner structure of the stamper

33

is shown in.

FIG. 7

a

. There are four stamps

33

b

(red, blue, yellow, and green) in the casing

33

a

arranged in a row. The stamps

33

b

are changeable by cartridges. One or more of the four stamps

33

b

is selected to stamp a colored pattern on the marker. The color pattern changing mechanism has a color pattern selecting cam

33

c

. This color pattern selecting cam

33

c

is shown in

FIG. 7

b

. The cam has projections

33

d

around the surface along the shaft

33

e

. The projections

33

d

contact the stamps

33

b

and push downward. For example, in

FIG. 7

b

red, yellow, and green patterns are printed. The projection number and patterns are different. By rotating the cam, the pattern of the projections is changed, and the printed color pattern is changed. Rotation of cam

33

c

is controlled by solenoid

33

g

as shown in

FIG. 7

c

. A one-way latch

33

f

is connected to the solenoid

33

g

. When the solenoid moves a predetermined length, the latch rotates the axis, but if the latch moves in the opposite direction the latch does not rotate.

The solenoid

33

g

as well as the solenoid

35

are driven and controlled by the controller

36

. The controller

36

operates similarly to the second embodiment, as shown in FIG.

5

. For example, in

FIG. 5

when the color pattern is decided in Step

4

, the chosen pattern is set to print by solenoid

33

g

, and the color pattern is printed in Step

5

. The color pattern is decided at the same time as the operation of the tape

17

and cutting apparatus

22

. When the tape

17

is pulled out to a preset length, the end of the tape reaches the roller

21

, the solenoid works to stamp the tape, and the cutter moves forward to cut the tape.

In the second and third embodiments, multiple color patterns are prepared to print the different color patterns in order to distinguish the different groups of sheets. In this invention the plural patterns are not limited to color patterns. Characters may also be printed instead of color patterns;

Although a certain pattern is printed on the marker in the second and third embodiments, the pattern may also be printed directly on the sheet.

FIG. 8

shows the fourth embodiment of the sheet sorting apparatus of the invention. In this embodiment, the marker is attached to the underside of the sheet. In this way, the next sheet added to the output tray will not separate the marker from the sheet. The sheet sorting apparatus

40

is located on the outlet of the image processing apparatus. The sheet sorting apparatus is attached under the output roller

41

. Paper tape

44

is fed continuously from tape roll

43

. A roller

45

pulls the tape. Each side of the tape has adhesive material. A cutting apparatus

46

is located near the roller

45

, and the cutting apparatus creates marker

47

by cutting the end of the tape

44

.

In

FIG. 8

, a cutter holder

46

b

is connected to an eccentric cam

46

c

. The cutter holder

46

b

has a cutter edge

46

a

on the top end. By the rotation of the eccentric cam, the cutter holder is moved back and forth. The cutter edge cuts the tape

44

. A marker attachment roller

48

and marker pinch rollers

49

guide the marker

47

. The attachment roller

48

contacts the sheet output roller

41

, and the marker is attached to the sheet

42

as both of them pass through the rollers. In this case the marker is affixed to the underside of the sheet. The marker

47

is supported by rollers

48

and

49

. This operation is shown in

FIGS. 9 and 10

.

Preferably, the rotation velocity of the attachment roller

48

is equal to the feeding velocity of the sheet

42

. If the rotation velocity of the roller differs from the feeding speed of the sheet, then the sheet could jam or become skewed. For the synchronous operation of the rollers

48

and

49

, each roller has a gear and these gears are interlocking. The driving force for the rollers

49

is provide by the feeding roller

41

.

In this embodiment, as described in the first embodiment, the time delay from sheet detection to the start of rotation is adjustable. By changing the delay time, the position where the marker

47

is adhered to the sheet changes as shown in FIG.

11

. Of course, as in the second and third embodiments, a color or other printed pattern may be printed on the marker

47

. Referring to

FIG. 8

, a marker detecting apparatus

50

is positioned on the sheet feeding path after the attachment roller

48

. The detecting apparatus

50

detects if the marker is or is not in the correct position on the sheet. The detecting apparatus has an L-shaped lever

50

a

and a switch

50

b

. The switch is turned on or off by the position of the lever

50

a

. The lever rotates around the axis located at the center bent section.

Turning to

FIG. 10

, the lever

50

a

is located beside the sheet feeding path where it can contact the marker

47

. When there is no feeding sheet, the end of the lever

50

a

crosses the sheet feeding plane by a spring operation as shown by the dotted line in FIG.

8

. When a marker

47

contacts the lever

50

a

, the lever is moved downward. By the movement of the lower end of the lever

50

a

, the switch

50

b

is turned on. Various types of switches can be used. For example, a micro-contact switch or a non-contact switch such as a proximity sensor can be used.

Whether or not the marker

47

will adhere at a predetermined position correctly or not is detected by the signal of the switch

50

b

. If the marker adhering operation is done and the switch

50

b

is off, then the controller judges that the adhering operation was done correctly. If a signal of incorrect attachment is received, then a predetermined alarm output is generated, such as a flashing lamp.

Referring to

FIG. 9

a

, a sensor

52

to detect an out-of-tape condition is located on the lower position of cutter apparatus

46

. The sensor

52

may be a photo-electric or other type of sensor. In this embodiment, the sensor

52

is a transparent type photo-electric sensor. When there is tape

44

in front of the sensor

52

, light to the sensor is blocked. When there is no tape, light is detected. When the end of the tape passes beyond the sensor, a tape empty signal is generated. Based on the signal, an out-of-tape message is sent.

FIG. 12

shows the fifth embodiment of the sheet sorting apparatus of the invention. This embodiment is based on the fourth embodiment. Additionally, the attachment roller

48

is movable up and down to separate the roller from the feed roller

41

. In this embodiment, when the attachment of the marker is not needed, the attachment roller is separated from the feeding roller, so the sheet

42

is not pressed with unnecessary force.

In this embodiment, the cutter apparatus

46

and attachment roller

48

operate synchronously. The attachment roller is held on the upper end of a link arm

55

, which rotates around the axis

55

b

. On the lower end

55

c

of the lever, a torsion spring

56

provides force in the A direction, as indicated in

FIG. 12

a

. By the force of the torsion spring, the link arm moves in the B direction and separates the attachment roller

48

from the feeding roller

41

. The sheet

42

is then fed smoothly by roller

41

only. A pressure lever

58

is provided on the end of the cutter holder

46

b

. When the cutter holder moves to cut the tape, the pressure lever

58

moves as well. The end of the pressure lever contacts the lower end of the link arm

55

, forcing the link arm to move in the C direction. By this force, the torsion spring

56

is deformed. The link arm rotates in the D direction as shown in

FIG. 12

b

, and the attachment roller

48

contacts the feeding roller

41

. In this position, the marker can be adhered to the sheet. When the rotation force of the attachment roller

48

is applied to the feed roller

41

, the operation is the same as explained in the fourth embodiment.

Gears are not shown, but roller

48

is only driven when the gears on the same axis contact gears on the axis of feed roller

41

. In the fifth embodiment, unnecessary force by the feed rollers is eliminated. When the cutter apparatus

46

cuts the tape, eccentric cam

46

c

is positioned as shown in

FIG. 12

b

. After a set amount of time, the marker is adhered to the sheet. Then the eccentric cam

46

c

returns to its normal position as shown in

FIG. 12

a.

The mechanism for movement of the attachment roller

48

is not limited to this embodiment. The movement mechanism and driving mechanism may also be provided independently. The independent mechanism can be operated by a control signal to adhere the marker.

The sixth embodiment of the sheet sorting apparatus of the invention will now be described. The standard position for feeding the sheet in the sixth embodiment is shown in

FIGS. 13-15

.

FIG. 13

is the view from the B direction in

FIG. 15

, and

FIG. 15

is the top view.

FIG. 14

shows the inner structure of the apparatus. This embodiment is based on the fifth embodiment. In this sixth embodiment, in order to simplify the structure, movement of the cutter apparatus

46

, pulling of the tape

44

, and feeding and attaching the marker

47

are driven by a single motor.

In this embodiment, as in the fifth embodiment, a cutter apparatus

46

is moved by an eccentric cam

46

c

. The cutter edge

46

a

cuts the tape. In

FIG. 15

, the cutter edge is angled. By this configuration, the cutter cuts the tape sharply and surely. As described in the previous embodiment, the attachment roller

48

only contacts the sheet when the marker is to be adhered.

In the drive system, a driving motor capable of alternating rotation, such as a servo motor, is used. First gear

61

is located on the output shaft

60

of the driving motor. Second gear

62

contacts first gear

61

. The first gear

61

rotates counterclockwise. In this embodiment, forward rotation is defined as counterclockwise rotation of the first gear

61

, and reverse rotation is clockwise rotation of it. Third gear

63

contacts second gear

62

. A stopper

64

is attached to gear

63

. The stopper

64

has a hollow wedge shape. When the driving motor alternates rotation, the stopper

64

moves back and forth around the axis of the third gear

63

. A fixed rod

66

passes through the interior of the stopper

64

to limit the stopper's movement. A torque limiter

82

is provided on the shaft of the third gear

63

. When torque greater than a set value is applied to the shaft, the shaft is blocked by the limiter. In this way, if the driving motor rotates beyond the movement limit of the stopper, then the stopper will not rotate further. By this mechanism, rotation control of the driving motor can be rough, but the stopper is positioned precisely.

A fourth gear

65

is provided on the end of the shaft

46

d

of the eccentric cam

46

c

. A stopper

67

is also provided. The fourth gear

65

rotates by rotation force from the third gear

63

. The stopper

67

contacts the stopper

64

. The shaft

46

d

has a one-way clutch

83

. The one-way clutch

83

transfers rotation force only when the driving motor rotates in the reverse direction. When the driving motor rotates in the forward direction, the driving force is not transmitted to the shaft

46

d

and the fourth gear

65

runs idle. The fourth gear

65

rotates alternatively and synchronously with the driving motor, and the rotation force is transmitted to the fifth gear

74

.

On the shaft

69

of the second gear

62

, a first link element

70

is provided as shown in FIG.

14

. The first link element

70

has a fork

70

a

, and the fork contacts cutter contact pin

71

. The movement of the contact pin

71

controls cutter holder

46

b

's movement. According to the alternating movement of the cutter contact pin

71

, the first link element

70

rotates in alternating directions. The other fork element

70

b

contacts the pin

71

a

of the second link element

73

. By the alternating rotation of the first link element

70

, the second link element

73

rotates alternatively around the axis P. A fifth gear

74

is also provided on axis P. At the end of the second link element

73

is a sixth gear

75

. The fifth gear

74

contacts the sixth gear. On shaft P of the fifth gear is a one-way clutch

85

. A seventh gear

86

is also provided on shaft P. In this way the sixth and seventh gears are connected. The one-way clutch

85

transmits force when the driving motor rotates forward, which rotates the seventh gear

86

. By this configuration, the force of the fourth gear

65

is transmitted to the sixth gear

75

through the fifth gear

74

. Near the end of the second link element

73

, the eighth gear

76

and ninth gear

77

are located. By the alternating movement of the second link element, the sixth gear contacts either the eighth gear

76

or the ninth gear

77

. Thus the link gear is changeable when the motor rotates forward.

The eighth gear transmits rotation force through a tenth gear

78

and an eleventh gear

79

to a gear (not shown) that links the eleventh gear and the attachment roller

48

. In this way the attachment roller is rotated. The tenth gear is located on the shaft of the tape-pulling roller

45

. The ninth gear

77

is located on the shaft of rollers

49

. A twelfth gear

88

is located at the opposite side of the shaft of the roller

49

. The gears

77

and

88

rotate equally. The twelfth gear contacts a thirteenth gear

90

via an idle gear

89

. The rotating force of the thirteenth gear is transmitted to the attachment roller

48

through the feed roller

41

. By this structure, when the sixth gear

75

contacts either the eighth gear

76

or the ninth gear

77

, the attachment roller

48

is rotated.

First, the forward rotation of the motor will be explained. This pulls the tape out from the roll.

FIGS. 13-15

show the standard position. When the motor drives in the forward direction, as shown in

FIGS. 16-17

, the first, second, and third gears are rotated in the direction of the arrows. The stopper

64

rotates counterclockwise, and the inside edge portion

64

b

contacts the pin

66

, which stops further movement. When the motor rotates in the forward direction, the rotation shaft

46

d

does not receive rotation force due to a one-way clutch

83

. The eccentric cam

46

c

does not rotate, and the cutter edge

46

a

stays in the standard position. In that way, the seventh gear

75

is kept in the standard position and engages with the eighth gear

76

. The one-way clutch

85

located on rotation shaft P transmits the driving force of the fifth gear

74

to the tenth gear

78

. Pull-out roller

45

is rotated, and tape

44

is pulled out to a set length according to the amount of rotation of the pull-out roller. The pulled-out tape projects from the cutter apparatus

46

.

Next is the reverse rotation operation, which involves the cutting of the tape to make the marker. As shown in

FIGS. 17-18

, the driving motor rotates in the reverse direction. This causes the first, second, and third gears to rotate in the opposite direction from before, as shown in

FIGS. 18-19

. The stopper

64

stops at a position shown in

FIG. 19

when the inside edge

74

a

contacts pin

66

. As the reverse rotation of the driving motor starts, the stopper

64

and the cutter shaft stopper

67

are not touching, and the shaft

46

d

can rotate, as shown in FIG.

17

. When the driving motor begins reverse rotation, the one-way clutch

83

transmits driving force. Then by the rotation of the fourth gear

65

, the eccentric cam

46

rotates. The eccentric cam moves the cutter holder and cutter edge forward. When the eccentric cam rotates 180 degrees, the cutter stopper

64

is in the position shown in FIG.

19

. The cutter shaft stopper

67

contacts the stopper

64

, and further rotation is prevented. The cutter edge

46

a

is stopped exactly at the most forward position, where it stays. As the cutter edge moves forward, it cuts the tape

44

. A marker is formed from the extended part of the tape. According to the forward movement of the cutter holder

46

b

, the attachment roller

48

moves forward and contacts the feed roller

41

as in the fifth embodiment. Additionally in this embodiment, the cutter contact pin

71

moves forward with the cutter holder

46

b

, as shown in FIG.

18

. The first link element

70

rotates counterclockwise, and the second link element rotates clockwise. The sixth gear

75

on the end of the second link element

73

engages the ninth gear

77

. During the reverse rotation of the driving motor, the fifth gear

74

rotates, but the sixth gear

75

and ninth gear

77

do not rotate because of the one-way clutch

85

.

After that process, the driving motor changes direction again to start a second forward rotation period. In this period the marker is fed and adhered to the sheet. From the position of

FIGS. 18 and 19

, the driving motor rotates forward. Then in

FIGS. 20 and 21

, the first gear

61

, second gear

62

, and third gear

63

rotate in the direction of the arrows. Finally the cutter stopper

64

stops at the position shown in FIG.

21

. The fourth gear

65

rotates when the driving motor rotates forward. The driving force of the motor is blocked by the one-way clutch

83

, and the rotation shaft

46

d

and eccentric cam

46

c

do not turn. Accordingly the cutter holder

46

b

remains in the forward position, and the cutter contact pin

71

does not move. The first link element

70

and the second link element

73

remain in the position from the previous process. The forward rotation of the driving motor and the one-way clutch

85

cause the ninth gear

77

to rotate. Accordingly, the roller

49

is rotated, and the marker

47

is fed. On the opposite side of the apparatus, the twelfth gear

88

, idle gear

89

, and thirteenth gear

90

rotate as well. Thus the attachment roller

48

rotates. Then, the cut marker

47

is adhered to the lower side portion of the sheet

42

.

This marks the start of the second reverse rotation of the driving motor, which returns the apparatus components to their standard positions. From the position in shown in

FIGS. 20 and 21

, the driving motor rotates in the reverse direction. The first gear

61

, second gear

62

, arid third gear

63

rotate as shown in FIG.

19

. The cutter stopper

64

stops as shown. At the start of reverse rotation, as shown in

FIG. 21

, the cutter stopper

64

and cutter shaft stopper

67

have not contacted each other, and the shaft

46

d

is free to rotate. By the rotation of the fourth gear

65

, the eccentric cam

46

c

also rotates. The cutter holder

46

b

and edge

46

a

move backwards. When the eccentric cam

46

c

rotates 180 degrees, the mechanisms become as shown in

FIGS. 13 and 14

. They then are prepared for the next adhering process. Continuous operation, from making the marker to adhering it to the sheet, is operated by a single driving motor. The improvements in the fourth, fifth, and sixth embodiments of course apply to the first embodiment. Similarly, the second and third embodiments can be applied to the fourth, fifth and sixth embodiments.

Each embodiment discussed so far is applied to the marker attaching mechanism of a sorting apparatus for an image forming apparatus. The marker adhering mechanism is located at the exit of the image forming apparatus and operates the ejected sheets which are printed. However, this invention is not limited to these embodiments. For example, it can apply to an image reading apparatus. An example is shown in FIG.

22

. The sheet sorting apparatus

14

is located at the exit of facsimile

10

′. A marker is adhered to a sheet when the sheet moves through the sorting mechanism

14

, and the sheet is piled on the output tray

10

′

a

. If some documents are sent to different persons, they can be marked by group. This also applies to receiving documents.

In this invention, the side edge part

10

′

b

of tray

10

′

a

is open. By this structure, the marker adhered to the sheet is located in the open area. Then, the marker is not bent and the position of the marker is easily recognized. There is a guide plate

10

′

c

on the front part of the tray. This keeps the sheets in alignment and prevents them from falling off the tray.

For the complete structure of the sheet sorting apparatus

14

, each embodiment can be applied. For other embodiments, such as those shown in

FIGS. 23-26

, a different structure is described. This is the seventh embodiment of the sheet sorting apparatus of the invention. Of course, the seventh embodiment can be applied to the exit part of an image processing apparatus.

In the seventh embodiment, the structure is the same as in the sixth embodiment. The main difference is the replacement of the marker adhering roller

48

with an adhering belt unit

48

′. Some of the parts that transfer the driving force are also different. As shown in

FIG. 23

, driving pulley

48

′

a

, responding pulley

48

′

b

, endless belt

48

′

c

, and tension roller

48

′

d

are located with some resistance. The tension roller is provided to give a set amount of tension. It feeds the marker along with the belt

48

′

c.

When the driving pulley

48

′

a

rotates in the clockwise direction, the endless belt

48

′

c

feeds a marker. The marker adhering belt unit

48

′ can swing in a predetermined range, and when it is in the up position the belt and feeding roller contact and a marker is pressed to a sheet as it is fed.

The marker adhering belt unit

48

′ has the same functions as the adhering roller

48

: move, stop, and swing up and down. Synchronized with the movement of the belt, the cutter edge

46

b

of the cutter apparatus moves back and forth it cuts the tape spooled out from the roller

43

at a preset time, and then the newly-made marker is attached to the sheet. In this embodiment the driving motor

60

′ alternately rotates. The driving force is transmitted by a system of gears. The sheets are moved from the making to the adhering of the marker by a single driving motor.

Next the mechanism of the driving force is described. As shown in

FIG. 24

, gears A

1

, A

2

, A

3

, and A

4

transmit the driving force from the driving motor

60

′ to the rotation shaft

46

d

of the eccentric cam

46

c

. The gears A

1

through A

4

correspond to the gears

61

,

62

,

63

, and

65

in the sixth embodiment. Gear A

4

contacts gear B

1

, and the driving force of gear B

1

is transmitted to gear B

2

. A one-way clutch is provided on gear B

1

, so that any time it rotates counterclockwise, gear B

2

also rotates. Gear B

2

contacts either gear C

1

or gear D

1

and transmits the driving force alternately. Gear B

1

corresponds to fifth gear

74

in the previous embodiment, gear B

2

corresponds to sixth gear

75

, gear C

1

corresponds to eighth gear

76

, and gear D

1

corresponds to ninth gear

77

. Gear C

1

provides the driving force to gear C

4

. The pull-out rollers

45

c

and

45

b

connected to C

3

are rotated. The pull-out roller

45

b

is a dependent roller, and its rotation depends on the roller

45

a

. Gear D

1

provides the driving force to gears D

2

-D

5

, causing the feeding roller

41

connected to the gear D

5

to rotate.

As shown in

FIG. 24

, the driving motor

60

′ rotates counterclockwise. Accordingly, the A gears rotate in the direction of the arrows and transmit the driving force to the B gears. Gear B

1

rotates counterclockwise, and gear B

2

rotates clockwise. Gear B

2

engages gear C

1

, and the C gears rotate as indicated. Then the pull-out rollers

45

a

and

45

b

pull out the tape

44

to a set length. This is the pull-out step, and next is the tape cutting step.

As shown in

FIG. 25

, the driving motor rotates clockwise. The A gears rotate as indicated, and gear B

1

rotates clockwise. Due to the one-way clutch, gear B

2

does not rotate, and the C gears are not turned. The pull-out rollers and adhering belt do not move. By the counterclockwise rotation of gear A

4

, the eccentric cam

46

c

rotates and the cutter edge

46

a

moves forward. The tape

44

is cut, and a marker is manufactured. By a similar structure to the fifth and sixth embodiments, the marker adhering belt

48

′

b

moves upward, corresponding to the movement of the cutter edge. The marker and sheet are pressed together by the belt

48

′

c

and the feeding roller

41

.

As shown in

FIG. 26

, the driving motor

60

′ again rotates counterclockwise. Accordingly, as in the tape cutting step, the A-named gears rotate as indicated by the arrows and transmit the driving force. Gear A

4

is connected to the shaft

46

d

through a one-way clutch. Accordingly the eccentric cam

46

c

does not rotate, and the cutter edge remains in the forward position. The adhering belt

48

′ and the feeding roller

41

hold the sheet and marker. Gear B

1

rotates counterclockwise and drives gear B

2

. Gear B

2

engages gear D

1

, and the D gears rotate as indicated. By the D gears, the feeding roller

41

rotates. Accordingly, the sheet and marker are fed, and by the adhesive material on the marker, the marker is adhered to a predetermined position on the sheet.

After the adhering process finishes, the driving motor

60

′ rotates in the reverse direction (clockwise). As in the tape cutting process, gear B

2

is not driven, and gear A

4

rotates counterclockwise. Then the eccentric cam

46

c

rotates and the cutter backs up to its original position. By their movement, the next cutting process is prepared and the dependent roller

48

′

b

of the adhering belt

48

′ moves downward and the endless belt

48

′

c

and feed roller

41

are separated. Then there is no feeding pressure from the attachment belt.

This process is repeated each time a marker is adhered. In the sixth and seventh embodiments, a driving motor is provided. However, in this invention, a driving motor is not required. Power could be provided externally, either from the image processing apparatus or another source.

In

FIG. 23

, RS is a limit switch to detect the passage of sheets. When a sheet is detected, the driving motor

60

′ starts to rotate. The time from detection to start of rotation can be varied. When the time is the same, the adhering position of the marker is the same. If the time is varied, the position is changed.

In the seventh embodiment, this sorting apparatus is applied to a facsimile device as an image reading apparatus, but the invention is not limited to only the applications in the embodiments. For example, by the results of OCR recognition of characters, a marker may be adhered to a sheet which has a bad recognition rate to show where the recognition error occurred.

FIG. 27

shows the eighth embodiment of the,sheet sorting apparatus of this invention. In this embodiment, a marker

116

is adhered to a sheet

112

, and the sheet is then piled on the tray

113

. The sheet sorting apparatus body

150

contains the marker adhering unit. The inner mechanism is shown in FIG.

28

. In

FIG. 28

, a movable unit

152

is provided inside casing

151

. The unit

152

is forced upwards by a plate spring

153

. In the normal state shown in

FIG. 28

, the top end portion of the unit

152

is lifted up.

In the unit

152

, a marker roll

154

is provided. The roll

154

is made of backing paper

155

to which a row of evenly spaced adhesive markers

116

is attached. The unwound end of the backing paper

155

is introduced into an outlet

152

a

of the unit

152

. The backing paper

155

turns at the outlet

152

a

, and the marker attached to the paper is removed. Then the removed marker is attached to the sheet below the outlet. The pressure roller

158

presses the marker against the sheet.

The unit

152

has a movable link mechanism. A bar

162

is linked to a round wheel

160

. The wheel is turned by a motor (not shown). The bar

162

has a guide pin

163

, which is inserted in a guide hole

165

in the casing

151

. Driven by the turning of the wheel, the guide pin moves back and forth in the hole, and the unit

152

moves accordingly. There is a guide rail

167

in the unit

152

, and the guide rail contacts a roller

169

. The guide rail is bent so that the end portion

167

a

is lower than the base portion

167

b

. In the normal state shown in

FIG. 28

, the roller

169

contacts the lower portion of the guide rail

167

a

. When the unit

152

moves backwards according to the turning of the wheel

160

, the roller

169

contacts the base portion of the guide rail

167

b

. As shown in

FIGS. 29 and 30

, the unit

152

is forced downwards by the action of the roller

169

. Both the roller

169

and the wheel

160

are mounted on the casing.

When a sheet is exiting beneath the apparatus, the motor is driven and the wheel

160

turns. Then as shown in

FIG. 29

, the outlet

152

a

moves downwards, and the top of the marker

116

contacts the sheet under the unit. Due to the turning, of the wheel

160

, the unit

152

moves to the right, and the roll

154

and rollers

156

and

157

turn as shown in FIG.

29

. Then the backing paper

155

is pulled out and the marker is pulled out with it. The backing paper turns sharply at the outlet

152

a

, causing the marker

116

to be removed and placed by the roller

158

.

As the wheel

160

continues to turn, the unit

152

moves completely to the right side of the casing, as shown in FIG.

30

. The marker adhering process is finished, and the next marker is waiting in the outlet

152

a

. By the turning of the wheel, the unit

152

moves back to the left, as shown in FIG.

31

. When the unit moves backwards, the backing paper is not pulled out due to a one-way clutch mechanism which cuts the driving force.

After the wheel

160

has rotated a complete 360 degrees, as shown in

FIG. 32

, the roller

169

is again in contact with the end portion

167

a

of the guide rail. The outlet side of the unit is lifted up by the recovery force of the plate spring

153

. To attach the next marker the cycle is repeated.

As shown in

FIG. 27

, the sheet sorting apparatus body

150

is movable along a guide rod

170

. By this mechanism, the marker adhering position is changeable. The mechanism is shown in detail in FIG.

33

. The sheet sorting apparatus body

150

is mounted under a mount

171

. A pair of guide rods

170

and a screw bolt

172

is provided through the mount

171

. By the turning of a screw bolt

172

, the sheet sorting apparatus body's position is changeable to adjust the attaching position.

In the embodiment mentioned above, the sheet sorting apparatus body's position is changed in line with the sheet feed direction. Of course, the sheet sorting apparatus body may also be moved across the path of the sheet, as shown in FIG.

34

.

In particular,

FIG. 34

shows the ninth embodiment of the sheet sorting apparatus, and

FIG. 35

shows the tenth embodiment of the sheet sorting apparatus of this invention. In these embodiments, the sheet sorting apparatus body

150

and

115

, respectively, are movable perpendicular to the sheet feeding direction. This movement may be carried out either manually or automatically by the screw bolt as shown in FIG.

33

. Due to these structures, the size of the sheets may be different. Referring to the structure shown in

FIG. 34

, this structure allows the markers to be attached to the front edge of the sheets.

Referring now to the structure as shown in

FIG. 35

, if one edge of the sheets

112

are in line on one side of the feeder, then the marker adhering position differs by the sheet size. In this case, by moving the position of the sheet sorting apparatus body

115

, a marker can be adhered to the appropriate position on each sheet

112

a

and

112

b.

The eleventh embodiment of the sheet sorting apparatus of the invention is shown in FIG.

36

. This embodiment illustrates some possible variations of the sheet receiving tray

175

. This type of tray

175

is designed to hold sheets

112

with markers

116

affixed to the side edge relative to the sheet feeding direction. As shown in FIG.

36

(

a

), both side edges of the tray have walls

175

a

for guiding the sheets

112

. An expanded area

175

b

is provided to prevent the markers

116

from contacting the side edge. FIG.

36

(

b

) shows an embodiment with tray sides

175

′

c

and

175

′

d

that ramp downward from the center of the tray

175

′. The downward ramps

175

′

c

and

175

′

d

cause the sheets to be held more securely and prevent the top-piled sheet from sliding off of the tray. Because the sides of the sheets in the tray slope downward, the side edges of a sheet being output will not contact the sheets in the tray

175

′. This prevents markers attached to the sheet edges from being accidentally removed by an exiting sheet.

FIG. 37

shows the twelfth embodiment of the sheet sorting apparatus of this invention. In this embodiment, the expanded portion of the tray is divided into several sections a, b, c. A label

177

may be attached to each section. The position of a marker on a sheet corresponds to one of the sections on the tray. The marker

116

does not cover the label

177

, so the label is visible and may be easily verified by the operator of the apparatus. This structure allows the label

177

to be used as an index, so that exited and piled sheets can be easily distinguished. Many styles for grouping the sheets may be employed according to necessity. For example, sheets can be sorted by each group of documents that are output, by the type of document such as printer or facsimile documents, or by a user-specified method.

In the embodiment above, the tray can also be flat. The sectioned portion a, b, c may alternately be applied to the forward end of the tray, as shown in FIG.

38

. In this case, markers

116

are attached to the front edge of the sheets.

FIGS. 39 and 40

show the thirteenth embodiment of the sheet sorting apparatus of this invention, a function of automatically loading a tape roll

124

for the sheet sorting apparatus based on the embodiments. After exchanging the roll

124

and closing the cover

121

, the tape

117

is automatically pulled out from the roll

124

and stops at a certain position ready for the adhering operation. A gear E

1

is provided on the shaft of the pull-out roller

125

a

. A feed roller

180

is provided on the shaft of a gear E

2

engaging gear E

1

. Gears E

1

and E

2

do not interfere with the operation of the other gears A, B, C, or D. The feed roller

180

contacts the tape roll

124

. The feed roller

180

and the pull-out roller

125

a

are interconnected so that by the rotation of the feed roller, the tape roll

124

is rotated and the tape

117

is pulled out at the same rate. A switch

181

is provided on the cover

121

to detect when the cover is opened. The switch

181

detects when the cover

121

is closed after exchanging the tape roll

124

. The detection signal is sent to a controller (not shown). The controller drives the motor

132

based on the detection signal. The motor

132

drives gear C via gears A and B. When C

3

is rotated, it causes the pull-out roller

125

a

to rotate. Accordingly, the driving force is transmitted to gears E

1

and E

2

. The feed roller

180

and the tape roll

124

are then rotated, and the tape

117

is pulled out.

The length of the time the drive motor

132

is active may be set to a predetermined time after receiving the detection signal from the cover switch

181

. Alternatively, as shown in the embodiment in

FIG. 40

, a reflective sensor

183

can be provided above the tape roll

124

. A reflection plate

183

a

is provided on the cover

121

. When the cover

121

, is closed after inserting a new tape toll, the reflection sensor

183

detects comparably strong light reflected from the reflection plate

183

because there is no tape between the sensor

183

and the plate

183

a

. When the tape

117

is pulled out, it covers plate

183

a

causing the amount of reflected light to be decreased. This allows the reflection sensor

183

to detect when the top of the tape

117

passes. After a predetermined time, the driving motor

132

is stopped. This structure allows the tape

117

to be loaded automatically by simply closing the cover

121

.

FIGS. 36

to

38

show other embodiments of the sheet receiving trays. They are designed to hold sheets with markers affixed to the edges.

FIGS. 39 and 40

show a function of automatically loading a marker roll

124

. After exchanging the roll

124

and closing the cover

121

, the tape

117

is automatically pulled out from the roll

124

and stops at a certain position ready for the adhering operation.

The primary advantages of this invention are as follows. By adhering markers to predetermined sheets, a group of sheets can be easily distinguished when multiple groups of sheets are piled on a single tray. The groups of sheets are sorted quickly and accurately. Markers are adhered to sheets by pressure-sensitive adhesive, so that the probability of them falling off is reduced. The marker adhering process is operated by a pair of feeding means with the sheet. The sheet being fed is not stopped while the marker is adhered, allowing non-stop operation. Sorting is operated by the marker. The invention is still effective when different-sized sheets are used.

While the invention has been described in detail with reference to a number of embodiments, it should be apparent to those skilled in the art that many modifications and variations are possible without departure from the scope and spirit of this invention as defined in the appended claims.

Number	Date	Country
9-177855	Jun 1997	JP
9-251485	Sep 1997	JP
9-363882	Dec 1997	JP

Number	Name	Date	Kind
3245859	Busk	Apr 1966	A
3926713	Lowe et al.	Dec 1975	A
4070220	Cavender	Jan 1978	A
4966644	Clark, Jr. et al.	Oct 1990	A
5390594	Nobile et al.	Feb 1995	A
5556492	Vonderhorst et al.	Sep 1996	A
5807457	Norman, Jr. et al.	Sep 1998	A

Sheet sorting apparatus

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (3)

US Referenced Citations (7)