Information
-
Patent Grant
-
6654133
-
Patent Number
6,654,133
-
Date Filed
Friday, April 9, 199925 years ago
-
Date Issued
Tuesday, November 25, 200321 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Coles; Edward
- Rahimi; Alan
Agents
- Fitzpatrick, Cella, Harper & Scinto
-
CPC
-
US Classifications
Field of Search
US
- 358 498
- 358 112
- 271 904
- 271 908
- 271 909
- 271 12
- 271 271
- 347 153
- 399 367
-
International Classifications
-
Abstract
The present invention relates to a recording apparatus which has a positioning means for manual sheet feeding for aligning a sheet feeding position, and a positioning means for auto sheet feeding provided on an auto sheet feeder for aligning the sheet feeding position, and a sheet fed from the auto sheet feeder does not abut against the positioning means for manual sheet feeding, when the auto sheet feeder is attached to the recording apparatus main body.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a sheet feeding device that feeds a recording medium and to a recording apparatus comprising the sheet feeding device, and, in particular, to the sheet feeding of the recording medium.
2. Related Background Art
As with most other devices, there is significant market demand for miniaturized, lightweight recording apparatuses and reflecting this, miniaturization and decreased weight in recording apparatuses are advanced.
In the pursuit of such miniaturization, as shown in Japanese Patent Application Laid-Open No. 6-183582 and others, devices have been invented in which the auto sheet feeder (hereinafter referred to as “ASF”), which is the sheet feeding device for feeding multiple sheets of the recording medium one by one (one sheet at a time) into the image forming portion of the printer is separated from the printer (recording apparatus main body) for recording images and stands alone as an ASF externally attachable to the printer.
ASF which can be used by attaching not only to a miniature printer but also to the outside of a printer with multiple sheet feeding apertures or to a printer with manual sheet feeding only also currently exist.
Also, in such printers the standard width of the sheets (sheet standard) must be uniform when the sheets are manually fed by the printer as a single unit or when the sheets are automatically fed by the ASF attached to the printer.
When the sheets are fed manually, the user feeds sheets by hand while the side edge portion of the sheet is maintained along the sheet standard. To the contrary, when the sheets are fed automatically with ASF, it is extremely difficult to maintained the side edge portion of the sheet along the sheet standard for the manual sheet feeding within measurement tolerance. Therefore, extremely precise parts and adjustments are necessary to accomplish aligned feeding in conventional ASF, and high cost and great complexity are unavoidable.
As a result, sheet feeding apertures have conventionally been separated into manual and ASF and sheet positioning performed according to each sheet standard. However, though it is possible to separate a manual sheet feeding aperture and an ASF sheet feeding aperture in relatively large devices, there is not enough space for separate sheet feeding apertures in super-miniature printers such as portable mobile printers, and the common sheet feeding aperture must be used.
However, when the common sheet feeding aperture is used and the common sheet guide is shared, if sheets are fed from the ASF, the side edge portion of the sheets interfere with the sheet standard by measurement tolerance and skew feeding, and inconveniences such as skew feeding and damage to the sheet edge portion or sheet jams arise.
SUMMARY OF THE INVENTION
An object of the present invention is to solve such inconveniences and to provide an ASF that can feed sheets into a recording apparatus without causing damage or jams and an image formation device comprising it.
The present invention provides a recording apparatus having a recording apparatus main body comprising a sheet feeding aperture which can record an image on a sheet manually fed from the sheet feeding aperture and an auto sheet feeder detachably attached to the recording apparatus main body that can automatically supply sheets to the recording apparatus main body through the sheet feeding aperture, which has a positioning means for manual sheet feeding for aligning the sheet feeding position by restricting the sides of the sheets fed manually from the sheet feeding aperture and an automatic sheet feeding positioning means for aligning the sheet feeding position by restricting sides of the sheets supplied automatically into the recording apparatus main body with the auto sheet feeder attached, and is constructed such that the sheets supplied by the auto sheet feeder do not abut against the positioning means for manual sheet feeding when the auto sheet feeder is attached to the recording apparatus main body.
The present invention is also constructed such that when the auto sheet feeder is attached to the recording apparatus main body, the positioning means for manual sheet feeding can be retracted so that the sheets supplied from the ASF do not abut against the positioning means for manual sheet feeding. In the present invention, the positioning means for manual sheet feeding can also be retracted to the side of the pass through which the sheets supplied from the ASF path.
As the positioning means for manual sheet feeding of the present invention a sheet feeding tray for supporting the sheets manually fed from the sheet feeding aperture is attached and a tray receiver is provided on the auto sheet feeder main body for receiving the sheet feeding tray such that the sheet feeding tray can be retracted below the pass when the auto sheet feeder is attached to the main body of the recording apparatus.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a perspective view of the first embodiment of the present invention with the ASF attached to the printer.
FIG. 2
is a drawing showing the ASF being attached to the printer.
FIG. 3
is a sectional view of the ASF.
FIG. 4
is a sectional view of the ASF attached to the printer.
FIG. 5
is a perspective view of an embodiment of the present invention.
FIG. 6
is a perspective view of an embodiment of the present invention.
FIG. 7
is a schematic plan view of an embodiment of the present invention.
FIG. 8
is a sectional view of an embodiment of the present invention.
FIG. 9
is a perspective view of an embodiment of the present invention.
FIG. 10
is a perspective view of an embodiment of the present invention.
FIG. 11
is a perspective view showing the arrangement of parts relating to the printer attachment/detachment mechanism of the ASF of the present invention.
FIG. 12
is a perspective view showing the arrangement of parts relating to the printer attachment/detachment of the ASF when attached to the ASF of the present invention.
FIG. 13
is a left sectional view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 14
is a left sectional view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 15
is a left sectional view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 16
is a left sectional view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 17
is a left sectional view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 18
is a left sectional view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 19
is a perspective view showing the arrangement of parts relating to the printer attachment/detachment mechanism for the ASF and a symbolized power relationship of the present invention.
FIG. 20
is a top view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 21
is a top view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 22
is a top view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 23
is a top view explaining the printer attachment/detachment mechanism for the ASF of the present invention.
FIG. 24
is a block diagram of the printer and ASF connections of the present invention.
FIG. 25
is a schematic sectional view of the printer with ASF attached of the present invention.
FIG. 26
is a schematic view showing the connections between connectors and ASF connectors.
FIG. 27
is a schematic view showing the ASF driver mechanism connections and operation directions.
FIG. 28
is a schematic view showing the ASF driver mechanism connections and operation directions.
FIG. 29
is a control flow of the sheet feeding operation in the printer controller of an embodiment of the present invention.
FIG. 30
is the main control flow in the ASF controller.
FIG. 31
is a sub-flow of the sheet feeding operation control in the ASF controller of an embodiment of the present invention.
FIG. 32
is a sub-flow of the initialization operation control of the ASF controller.
FIG. 33
is a sub-flow of the operation control by machine type in the printer controller..
FIG. 34
is the flow of the sheet feeding operation control in the printer controller of the second embodiment.
FIG. 35
is a sub-flow of the sheet feeding operation control in the ASF controller of the second embodiment.
FIG. 36
is a schematic sectional view showing the condition when step
22
is completed during sheet feeding operation.
FIG. 37
is a time chart showing an outline of the printer and ASF operation flows in the second embodiment.
FIG. 38
is a chart showing the contents of the driving tables for the sheet feeding motor.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Next, an embodiment of the present invention is explained in detail using the drawings.
FIG. 1
is a perspective view showing the condition when the printer (main body of the recording apparatus) is attached to the ASF (auto sheet feeder) in the first embodiment of the present invention,
FIG. 2
is a drawing showing the appearance of the printer being attached to the ASF,
FIG. 3
is a sectional view of the ASF and
FIG. 4
is a sectional view of the ASF in the condition when the printer is attached to the ASF.
In
FIGS. 1 through 4
, the ASF
1
is constructed such that it is detachably attachable to the printer
101
. An image formation device is formed of the ASF
1
and the printer
101
.
Here, the printer
101
is a so-called mobile printer, which is miniature and portable, comprising a battery. In this embodiment, an ASF is not housed inside the printer
101
and sheet feeding can only be done by manual sheet feeding on a single unit of the printer
101
. Such a construction is the most suitable form for a mobile printer while miniaturization, simplification, and lower cost of the single unit of the printer
101
can be realized. Of course, the present invention can be applied even if a miniature ASF is housed within the printer
101
.
This type of miniature, portable printer
101
is particularly used in such situations as when outdoors, within a vehicle, or at another office, when a salesman visits a customer. In such situations the number of recording sheets needed is comparatively small and a manual feeding only printer or a printer with a simple, low-capacity, interior-housed ASF is sufficient. To the contrary, it may be necessary to print a comparatively large volume of varied recording sheets when using the printer
101
in one's own office.
The ASF
1
separated from the printer
101
is extremely well suited to meet these needs. The ASF
1
has a so-called desktop type, from usually placed on top of a desk in an office, and by attaching the printer
101
to the ASF
1
, the printer
101
can have the properties of a desktop printer. With the construction described later, the ASF
1
can automatically feed various kinds of recording media such as regular paper, postcards, envelopes, plastic film, or cloth.
The present embodiment provides an extremely high value-added printer that can be used as a high-performance desktop printer by attaching a super-miniature, single unit mobile printer to the ASF of the present invention. The ASF
1
even functions as a receiving place for the printer
101
when the printer is not used as a single unit and can have the role of a so-called docking station where an auto feeding function is added when it receives the printer.
The ASF
1
of the present invention independently stable as a single unit ASF when the printer
101
is not attached and the printer
101
can also be separated from the ASF
1
while sheets are stacked in it. By this arrangement, the user can put the device in operation standby as a desk top printer only by attaching the separated printer
101
to the independent ASF
1
.
Namely, the ASF and the printer function as an extremely user-friendly docking station.
If using the printer
101
as both a mobile printer and a desktop printer as above, it is important that the operations of attaching and detaching the printer
101
from the ASF
1
can be performed extremely simply. This is because it is extremely inconvenient for a user who separates the printer
101
from the ASF
1
and carries the printer around, then returns and attaches it to the ASF
1
almost every day, if attachment and detachment procedures are difficult or take much time.
In the present embodiment, as shown in
FIG. 3
, an attachment aperture
1
A (hereinafter referred to as “aperture”) is provided at the front of the ASF
1
for attaching the printer
101
. The sheet pass-through route in the printer
101
is a so-called horizontal path that is almost horizontal and is constructed such that a sheet path described later is formed by moving the sheet supply side of the printer
101
almost horizontally facing the ASF
1
and pushing it into the aperture
1
A of the ASF
1
.
In other words, in the present embodiment, the printer
101
having the horizontal path is pushed into the ASF
1
in an almost horizontal direction and attached. Then, when the printer
101
is pushed almost horizontally, the printer
101
is automatically secured to the ASF
1
(securing method for both of the printer and the ASF when the printer
101
is attached to the ASF
1
will be described in detail later). When separating the printer
101
from the ASF
1
, the printer
101
is released from the ASF
1
merely by pressing the push lever
40
provided at the top of the ASF
1
and pushing the printer
101
to the front of the ASF
1
.
By constructing the device in this way, the user can attach and detach the printer
101
from the ASF
1
with extreme ease and can use the printer either as a mobile or a desktop printer.
In order to make attachment and detachment operations simple and easy to perform, the present embodiment comprises a bottom surface of the aperture
1
A formed in front of the ASF base
45
which form the main body of the ASF with the ASF case
47
, and a table
45
c
which is a recording apparatus supporting portion, for supporting the printer
101
so as to be able to move in the attachment direction when attaching the printer
101
.
When attaching the printer
101
to the ASF
1
, the printer
101
is first placed on the table
45
c
. Then the user grasps the upper and lower surfaces of the printer
101
at the middle of the side closest to hand (discharge side) with one hand, and places the printer
101
while the inner side (sheet feeding side) thereof is attached lightly on top of the table
45
c
(the printer
101
may be held in both hands on both side portion).
Next, when the printer
101
placed on top of the table
45
c
is pushed by hand toward the inside which is the direction of attachment indicated by an arrow in
FIG. 2
, both side surfaces of the printer
101
will be introduced into positioning bosses to be described later while guided by the printer side guide portions
45
a
provided on both side end portions of the table
45
c
, and fit into positioning holes of the printer
101
to be described later, and positioned.
No further positioning is necessary other than pushing the printer
101
in the approximate center of the table
45
c
. In this way, when the printer
101
is attached to the ASF
1
, the printer
101
may be placed on the table portion
45
c
and then pushed along the table portion
45
c
. Thus operability is extremely good and it is extremely easy to attach.
Printer sliding portion
45
b
, over which the bottom of the printer slides when the printer
101
is pushed as shown in
FIG. 2
, are provided on both side portions of table portion
45
c
in a direction perpendicular to the printer attachment direction. Also, a level difference portion G
1
is formed between the printer sliding portion
45
b.
Protruding object such as rubber feet, not shown in the Figures, are provided on the bottom surface of the printer
101
and make it harder to move the printer
101
by external force, for example when using the printer as a single unit while place it on a desk. However, when attaching the printer
101
to the ASF
1
, if these rubber feet contact the table portion
45
c
, the user must use greater force to push the printer
101
, and it becomes extremely difficult to operate.
Therefore the level difference portion G
1
described above was formed in between the printer sliding portion
45
b
so that the rubber feet would not contact the table portion
45
c
. This level difference portion G
1
is formed with a deeper level difference than the height of the rubber feet such that the rubber feet will not contact the table portion
45
c.
By forming such a level difference portion G
1
, the rubber feet will not contact the table portion
45
c
, thereby the user can push the printer
101
by hand without needing much force, and it becomes easier to operate and attach.
An eave portion
47
a
which constitutes one portion of the aperture
1
A and is formed almost parallel to the table portion
45
c
is formed on the upper case
47
of ASF. This eave portion
47
a
forms a pocket portion with the table portion
45
c
in which the printer
101
is fit.
The shape of the pocket formed in this way shows the user the direction to push the printer
101
into the ASF
1
in almost parallel and makes it impossible for the user to push the printer into the ASF
1
in any other direction.
This direction same as for the both connectors used to electrically connect the printer
101
to the ASF
1
, which will be described later. The connection of the connectors is performed during the operation of pushing the printer
101
into the ASF
1
and securing it. With this arrangement, operability is improved because it is not necessary to perform another operation to connect the connectors. Damage to the connectors due to abnormal interposition of the connectors caused by pushing the printer
101
into the ASF
1
in the different direction when the printer
101
is attached to the ASF
1
is also prevented.
After the printer
101
is attached, if the front end of the printer
101
(discharge side) receives upward force, the eave portion
47
a
abuts the printer
101
and restricts any upward movement of the printer
101
. Thus, even if the printer is lifted upward with respect to the ASF
1
, upward movement of the printer
101
can be prevented and damage to the attachment portion or release of attachment due to upward movement of the printer
101
is also prevented.
In this embodiment, the both side portions of the eave portion
47
a
protrude farthest and the center is a concavity
47
b
. By providing this recessed portion
47
b
, operation parts
110
B provided on top of the printer
101
such as the power switch and others can not be covered.
As long as the clearance between the eave portion
47
a
and the top of the printer is between 0.5 mm to 2 mm, it will sufficiently prevent above-mentioned upward lifting. If the clearance is too large it will not have the desired effect.
As shown in
FIG. 4
, when the depth of the printer
101
is set as L
1
, the depth of the table portion
45
c
is set as L
2
, and the depth of the eave portion
47
a
is set as L
3
. In this embodiment they satisfy the following relationship.
L
1
/2
≦L
2
≦
L
1
−15 mm
By selecting the depth L
2
of the table portion
45
c
not less than one half (L
1
/2) of the depth L
1
of the printer, the printer
101
can be maintained in a stable condition when the printer
101
is attached to the ASF
1
. This relationship only needs to be satisfied in one portion of the table portion
45
c
not in the entire area of the table portion.
If L
1
/2 is greater than L
2
, the printer
101
will protrude greatly from the ASF
1
when attached and will be extremely unstable, such that if downward external force is applied on the protruding part, the rear portion of entire apparatus may be lifted up.
On the other hand, by selecting the depth L
2
of the table portion
45
c
smaller, at least 15 mm in the present embodiment than the depth L
1
of the printer
101
, space for the user's fingers on the lower front side of the printer
101
when the printer
101
is attached is preserved.
In this way operability and ease of attachment is improved, as the user can attach and detach the printer
101
by grasping the upper and lower surfaces in one hand. Of course, the user may also grasp the printer in both hands. This relationship need not be satisfied over the entire width of the table portion
45
c
. For example, the table portion
45
c
may also be formed with recessed portion in either the center or on both side portions so as to satisfy this relationship.
By providing a space in the lower front side of the printer
101
a design is achieved which doesn't look vertically large to the eye. Further, if the thickness (height) of the table portion
45
c
is not less than 10 mm, the user's fingers can be inserted under the printer
101
when the ASF
1
is placed on top of a desk, which is also desirable.
In the present embodiment, the depth L
1
of the printer
101
and the depth L
3
of the eave portion
47
a
satisfy the following relationship:
L
1
/4
≦L
3
≦
L
1
/2
If the depth L
3
of the eave portion
47
a
is not less than ¼ of the depth L
1
of the printer
101
, upward lifting the printer
101
is prevented and the direction in which the printer
101
should be pushed is still sufficiently restricted.
If the depth L
3
of the eave portion
47
a
exceeds ½ of the depth L
1
of the printer
101
, the pushing amount with respect to the depth of the printer
101
during attachment will be relatively too large, and the operation will become unsatisfactory and it will interfere with operations on top of the printer as well. Further, a large eave portion
47
a
will make the entire apparatus look large to the eye and will oppress the user.
Because of this it is most preferable for the depth L
3
of the eave portion
47
a
to be not more than ½ of the depth of the printer
101
. With this amount of a protrusion, the protruding eave portion can be sufficiently strong and have a sufficient toughness in the apparatus.
By constructing the table portion
45
c
and the eave portion
47
a
according to these conditions, operability is extremely good and it is easy to attach, and a form that limits the pushing direction of the printer and prevents upward lifting of the printer
101
is achieved.
In the present embodiment, an aperture portion
1
A
1
is formed above the printer side guides
45
a
having a height not less than the clearance between the eave portion
47
a
and the top of the printer. By forming such an aperture portion
1
A
1
, if a power cord, interface connector, or a light emitting and receiving portion for infrared radiation transmission is established on the side of the printer
101
, the ASF
1
will not interfere with it. In other words, the printer
101
can be attached to the ASF
1
even with a power cord or an interface connector attached, and can also be detached in that condition.
Next the connector covers for the connector portion that electrically connect the printer
101
to the ASF
1
will be described.
In particular, when using the printer
101
for a long time period of detached from the ASF
1
, the each connector presents as separate, single units and it is maintained in non-connected state. In such condition, dirt or dust might enter into the connector portion or the internal electrical circuits may be damaged by excessive static electricity transmitted through the connectors.
In order to prevent such situations, in the present embodiment, connector covers are provided on each connector for protecting them. Each connector cover is provided as a single unit and can be removed when the printer
101
is attached to the ASF
1
. Because space is extremely limited in a super miniature printer such as a mobile printer, low cost, removable connector covers requiring very little space are most suitable.
For example, there is a printer connector
117
in the upper surface of the printer
101
facing the ASF
1
when attaching as shown in FIG.
5
. When the printer
101
is attached to the ASF
1
, the sheet feeding tray
116
is opened and the printer connector cover
119
is removed from the printer connector
117
. Similarly, on the ASF side as well an ASF connector cover
59
attached to an ASF connector
44
as shown in FIG.
11
and described later is removed.
When the connectors are connected, the removed twin connector covers
59
and
119
are received in the connector cover receiving portion
45
d
and
45
e
(see
FIG. 2
) in the table portion
45
c
as shown in FIG.
4
. These receiving portion
45
d
and
45
e
were provided in utilizing the thickness of the table portion
45
c
with protrusions of the same dimensions as the connectors inside. The loss of the connector covers
59
and
119
while the printer
101
is attached to the ASF
1
can be prevented by putting the connector covers
59
and
119
in these connector cover receiving portion
45
d
and
45
e.
If these connector cover receiving portion
45
d
and
45
e
were used only to hold the covers, they would function in any part of either the ASF
1
or the printer
101
. However, by providing the connector cover receiving portion
45
d
and
45
e
on the table as in the present embodiment there is no possibility of losing the operation when they are put between the ASF
1
and the printer
101
and the appearance is preferable because they cannot be seen from the outside.
The user is reminded to attach the connector covers
59
and
119
to the connectors
117
and
44
after separating, the printer
101
because when the printer
101
is separated the connector covers
59
and
119
reappear and prevent the user from forgetting to attaching. The connector cover receiving portion
45
d
and
45
e
can be provided for each of the multiple connector covers. The connector covers of the present embodiment are suitable even if the printer
101
and the ASF
1
have a relationship for example of a notebook PC and a station.
Following is an outline description of the route the sheets for recording follow when fed, and how recording occurs when the printer
101
is attached to the ASF
1
(details appear in a later attachment).
FIG. 4
shows a sectional view when the printer
101
is attached to the ASF
1
. In
FIG. 4
, a pressure plate
26
sets a designated number of sheets to be illustrated later. One end of this pressure plate
26
is rotatably supported by the ASF chassis
11
and activated in a clockwise direction by a designated pressure toward a pick-up rubber (sheet feeding rubber)
23
wrapped around a pick-up roller
19
by a pressure plate spring
13
.
When the sheets are set, this pressure plate
26
is moved away from the pick-up rubber
23
by a cam, to be illustrated later, and held there. At this time a designated clearance between the pick-up rubber
23
and the pressure plate
26
is maintained and the sheets are inserted into this clearance and set.
Positioning of the front end of these sheets is effected when the front ends contact an elastic deformable separator sheet
37
made of plastic film on an inclined surface
36
. The ASF sheet feeding tray
2
supports a major portion of the rear ends of the sheets. This ASF sheet feeding tray
2
is rotatably supported by the ASF upper case
47
at a designated angle when supporting sheets.
When the ASF
1
receives a sheet feeding command from the printer
101
, the pick-up roller
19
begins to rotate in a clockwise direction and the cam releases its hold on the pressure plate
26
simultaneously. The pressure plate
26
presses the sheets against the pick-up rubber
23
, a sheet begins to move due to the surface friction of the pick-up rubber
23
, and a single sheet is separated by the separating sheet
37
and conveyed in ASF sheet route
58
formed of the inclined surface
36
and the positioning base
39
(see FIG.
3
).
Afterwards, the sheet is passed from the ASF sheet discharging portion
56
(see
FIG. 3
) and transferred via the sheet feeding aperture
101
A, a so-called manual sheet feeding aperture (illustrated later) in the single unit of the printer, to a sheet route consist of a platen
105
in the printer and the bottom of a battery
107
.
Then the paper end sensor
108
senses that a sheet has been conveyed along the sheet route, thereby the printer
101
recognizes that the sheet has been conveyed from the ASF
1
, and the front end of the sheet is abutted to the pressure contact portion between the LF roller
109
and the pinch roller
110
. When the ASF
1
receives information of the paper end sensor
108
from the printer
101
, it sends a response signal within a predetermined timing to the printer indicating that sheet feeding is completed.
At this time the sheet is pushed on between the LF roller
109
and the pinch roller
110
with a designated pressure by rigidity of the sheet and corrected registration of the front end of the sheet is performed. Then the printer, which has received a response signal from the ASF
1
indicating that sheet feeding is complete, rotates the LF roller
109
for a designated amount of time and sends the sheet toward the recorder comprising a head
115
. In this way the sheet is conveyed as designated and the head
115
records on the surface of the sheet. Afterwards, the sheet is conveyed between a discharge roller
112
and a spur
111
and discharged.
The present embodiment is equipped with a sheet pass R, a recording medium pass-through route as described above when the printer
101
is attached to the ASF
1
. The sheet pass R of the printer
101
is almost parallel to the attachment direction of the connectors
44
and
117
.
However, if a sheet is passed from the ASF
1
to the printer
101
and a sheet jam occurs in either the ASF
1
or the printer
101
when the sheet is inside both, it will be necessary to separate the printer
101
from the ASF
1
. Thus the fact that the sheet pass R is almost parallel to the attachment direction of the both makes it possible to separate both in such a situation.
If the sheet pass R was at a right angle to the attachment direction of the connectors, when the printer was detached in the attachment direction of the connectors the sheet would have to be moved across and a danger of the sheet tearing and of some shreds of the sheet remaining within the device would arise. Further more, if a thick sheet that is difficult to tear was used, it could be impossible to detach the printer
101
.
However, because the sheet pass R in the present embodiment is almost parallel to the attachment direction of the connectors, when there is a sheet jam the printer
101
can be detached by moving the printer
101
in a direction such that the sheet slides out. As a result, fixing a sheet jam is extremely simple and can be done without tearing the sheets or leaving any pieces of the sheets inside the device.
Next the standard position of the sheet width direction in the sheet pass R described above is explained.
First, the standard in sheet width direction of the printer
101
is described.
As shown in
FIGS. 5 and 6
, a rotatable sheet feeding tray
116
with one end axially supported in a designated position is provided on the printer
101
. When the printer
101
is used as a single unit, this sheet feeding tray
116
stabilizes the manual sheet feeding operation.
When the sheet feeding tray
116
is open, a sheet feeding aperture
101
A is opened and a standard guide
116
a
, which is the positioning means for manual sheet feeding, provided perpendicular to one end of the sheet feeding tray
116
, appears. When a sheet is inserted, it is inserted along this standard guide
116
a
. In the present embodiment, the sheet width standard is this standard guide
116
a
and positioning across in the sheet width direction is performed by inserting the sheet while keeping the side portion of the sheet in contact with the guide.
A standard guide
101
a
as the main body positioning means is provided in the printer of the present embodiment at the same position with respect to the sheet width direction for positioning in sheet width direction with the standard guide
116
a
. When the sheet feeding tray
116
is open or closed held by a toggle means, not shown in the Figure, in each condition.
As this guide stabilizes the sheet in the conveying direction when the sheet is lengthwise, the standard guide
116
a
provided on the sheet feeding tray
116
stabilizes the positioning of the sheet across its width and prevents skew feeding. However, it is also possible to guide the sheet with only the standard guide
116
a
provided on the movable sheet feeding tray
116
without the standard guide inside the printer.
As mentioned before, the manual sheet feeding aperture and the sheet feeding aperture of the ASF are separate in a super-miniature mobile printer and one must feed sheets through each sheet feeding aperture because it is extremely difficult to have separate sheet guides given the problems of space.
As a result, when the printer
101
is connected to the ASF
1
, the standard guide
116
a
which is the sheet standard when manually sheet feeding must also be used when sheet feeding from the ASF
1
, but sheet feeding while keeping the side of the sheet auto fed from the ASF
1
along (in contact with) this standard guide
116
a
is extremely difficult. This is because for the ASF
1
to keep the side of the sheet along the standard guide
116
a
in the same way as the user does when adjusting by hand, the sheet standards of the printer
101
and the ASF
1
must be perfectly uniform.
In the present embodiment the sheet standard of the ASF
1
is an ASF sheet standard
26
b
provided on the pressure plate
26
as an auto sheet feeding positioning means. Sheets are put in a designated position by keeping the side of the sheet in contact with this standard when feeding. It is extremely difficult and would necessitate high costs and complex mechanisms to make the position of this guide uniform with the position of standard guide
116
a
because the structural tolerance between them becomes great.
However, if the sheet standards are not uniform the side of the sheet and the standard guide
116
a
will interfere with each other, and such things as skew feeding of the sheet, damage to the sheet edge portion, or sheet jams due to the front edge of the sheet colliding with the standard guide
116
a
will result.
Thus, for example if the standard guide
116
a
is provided only in a relatively upstream place on the manual sheet feeding portion of the printer
101
, in other words if the standard sheet width is determined only by the standard guide
116
a
which appears when the movable sheet feeding tray
116
is open as shown in
FIG. 5
, and if there is no member for restricting the positioning of the sheet downstream of that, when the printer
101
is attached to the ASF
1
, by setting the sheet pass R such that the sheet passes through above the base guide
116
a
only the sheet standard
26
b
of the ASF
1
will be effective for positioning the sheet and interference from the sheet standard of the printer
101
can be avoided.
Further, as shown in
FIG. 5
, the surface for guiding the sheet of sheet feeding tray
116
is almost horizontal when the sheet feeding tray is open on the printer as a single unit, in other words when manually sheet feeding, but as can be seen in
FIG. 4
by rotating the movable sheet feeding tray
116
when the printer
101
is attached to the ASF
1
to a position even lower than its position on the printer as a single unit, the sheet pass is closer to the sheet pass of manual sheet feed.
The ASF side has a standard guide receiving portion
36
b
which is a tray receiver for receiving the sheet feeding tray
116
by rotating it into a designated position. Thus, when pushing the printer
101
into the ASF
1
, the standard guide
116
a
is guided by a standard guide
36
c
that forms the standard guide receiving portion
36
b
, and the standard guide
116
a is received in the base guide receiving portion
36
b
. The standard guide receiving portion
36
b
is disposed within the inclined surface
36
.
In this way, the amount the sheet pass of the ASF
1
must move with regard to the sheet pass during manual feeding in order to avoid interference of the standard guide
116
a
with the sheet pass is decreased, and inconveniences due to unnatural sheet pass (back tension to the sheet, etc.) can be prevented.
In the present embodiment, the sheet feeding tray
116
on the printer side has a right edge guide
122
which is another positioning member for guiding the other edge of the sheet as shown in FIG.
6
. This right edge guide
122
is provided so that it can slide in the direction of the sheet width across the sheet feeding tray
116
and guides the edge of the sheet opposite to the standard edge in accordance with the width of the sheet.
The form of the right edge guide
122
is almost the same as the form of the base guide
116
a
seen from the sheet thickness direction of the sheet pass, and it is made such that when the printer
101
is attached to the ASF
1
it is received by the standard guide receiving portion
36
b
along with the sheet feeding tray
116
and the standard guide
116
a
. The right edge guide
122
also can be moved to an optional position within a designated range on the sheet feeding tray
116
, but no matter where the right edge guide
122
is within that designated range the standard guide receiving portion
36
b
is made so that it can receive the sheet feeding tray
116
comprising the standard guide
116
a
and the right edge guide
122
.
When the printer
101
is attached to the ASF
1
, by setting the sheet pass to a position in which it avoids the standard guide
116
a
and the right edge guide
122
, the sheet standard of the printer main body is ineffective and only the sheet standard of the ASF is effective. Therefore greater complexity to the equipment and higher costs due to making both sheet bases uniform can be prevented.
Further, skew feeding the sheets and damage due to the sheet standard
116
a
of the printer main body and the right edge guide
122
interfering with the edges of the sheets fed from the ASF
1
and sheet jams due to the sheets colliding with the sheet standard
116
a
and the right edge guide
122
can be prevented.
Up until this point of the explanation the embodiment was constructed such that the sheet passes through over the standard guide
116
a
, but the present embodiment is not limited to this construction. For example, it can also be constructed such that the sheet passes by the side of the standard guide
116
a
by providing a standard guide
116
a
on the sheet feeding tray
116
that can slide across the width of the sheet, and by sliding this standard guide
116
a
across the width of the sheet through a movement means such as a cam used by linking it to the operation of attaching the printer.
On the other hand, there is also a standard guide
101
a
inside the printer in the same position with regard to the sheet width as the standard guide
116
a
, and it is difficult to set the sheet pass to avoid all of the standard guides for sheets whose positioning is stabilized by increasing the length the sheet is guided.
Therefore, in such a situation, the sheet standard guide
101
a
on the printer side and the sheet standard
26
b
on the ASF side should be set in positions slightly askew in advance as shown in FIG.
7
. In other words, the sheet standard
26
b
on the ASF side is set in a spot askew only by the amount t toward the inner side of the sheet standard
116
a
on the printer side, or toward the recording position side which is the side at a right angle to the sheet conveying direction by the head
115
, so that when sheet feeding from the ASF
1
the sheet standard
101
a
on the printer side will not interfere with the sheet.
Here, the value t by which the sheet standard is set off is greater than the tolerance of positioning of the sheet width between the printer
101
and the ASF
1
, and is determined by referring to such instances as when the sheets were fed askew from the ASF. In the present embodiment, the value t by which the sheet standard is set off is about 0.6 mm.
In this situation, because the sheet standards when recording on the printer as a single unit and when recording with the printer attached to the ASF are not aligned, if one records with the head
115
in the same position on both the distance of the sheet width from the side of the sheet to the recording position will be different for both.
Therefore, in the present embodiment, the recording position for the printer as a single unit and for the printer when attached to the ASF should differ by the same amount t as the sheet standard position was set off. For example, in the present embodiment, because the printer
101
is electrically connected to the ASF
1
by connectors
44
and
117
, the printer
101
electrically senses whether the ASF
1
is attached or detached and can decide to set off the recording position (the position of the head
115
) according to the result of the sensor. This decision can also be made by setting up an ASF sensor switch, as well as through the electrical connection.
In this way interference from the standard guides can be eliminated by setting off the sheet standard of the single unit of the printer and the sheet standard when attached to the ASF from each other and the recording position on the sheet can be set identically. Accordingly inconveniences due to differences in recording positions between the recording of both (for example, differences in recording position on a preprint sheet) are eliminated. Even if the amount the two sheet standards are set off and the amount the two recording positions are set off are not exactly the same, different values within an allowed range may be set.
Next the ASF sheet feeding tray
2
which supports loaded sheets is explained.
As shown in
FIGS. 1 through 4
, the ASF sheet feeding tray
2
is supported on one end by the ASF case
47
, and is rotatable such that it can be folded around this supporting portion. When sheets are loaded on this ASF sheet feeding tray
2
it is opened to a designated angle. When sheets are not loaded on to it, it can be folded as shown in FIG.
8
and closed.
This is not for the purpose of allowing the ASF
1
to use a portable printer
101
as a desktop model given the present embodiment, rather it indicates that it is possible to carry the printer
101
even when attached to the ASF
1
as it is extremely compact.
In order to realize this form it is necessary for the ASF sheet feeding tray
2
when closed to close with a form fitting the outer shape of the ASF
1
as closely as possible when the printer is attached. For this purpose the ASF sheet feeding tray is made in a thin plate shape.
Further, in the present embodiment, when the sheet feeding tray
2
is closed, there is no danger that the operation parts will be touched carelessly and the printer
101
operated when carrying the ASF
1
with the printer
101
attached, because it covers the operation parts of the printer
101
as shown in FIG.
9
.
Also, when the sheet feeding tray
2
is folded up, it interlocks with the ASF case
47
through an optional interlocking means such as a hook (not shown in the drawings), desirable because with it the sheet feeding tray
2
can not be carelessly opened while it is carried. This interlocking means for the sheet feeding tray
2
may be provided onto the main body of the printer or onto the ASF itself, but the best embodiment is to provide such an interlocking means onto the side guide
2
a
to be described later. If an interlocking means is used on the main body of the printer, it can perform the double function of holding the ASF
1
and the printer
101
together (or of an integral lock).
As shown in
FIG. 10
, when feeding an envelope E vertically with the ASF
1
, usually the flap E
1
of the envelope is on the left side and the ASF
1
in the present embodiment receives strong resistance from the tab side (left side) when feeding it due to swelling of the flap E
1
from moisture. The envelope E is thus forced to rotate in a clockwise direction.
Therefore in the present embodiment, in order to prevent (restrict) rotation in a clockwise direction of the envelope E, in other words movement at a right angle to the sheet feeding direction, an ASF sheet feeding tray side guide
2
a
(hereinafter referred to as a side guide) which restricts the upstream side of the sheet feeding direction of the ASF sheet feeding tray
2
was provided on. By providing on such a side guide
2
a
, after the envelope E is set vertically in the ASF
1
, when it is fed, even if there is a rotating force on the envelope E the right side of the rear end of the envelope will contact the side guide
2
a
and any clockwise rotation will be restricted.
However, there is a resistance of the flap E
1
when sheet feeding an envelope vertically, particularly to the timing for conveying the envelope E. In the present embodiment, this occurs when the envelope E passes over the inclined sheet
37
and when the front of the envelope is lifted up along the incline of the incline
36
directly after that. Thus, the influence of the resistance of the flap E
1
decreases when it surpasses the timing, and rotation of the envelope E does not occur even if there is no side guide
2
a.
For this reason, a side guide
2
a
is provided on one part of the ASF sheet feeding tray
2
near the position of the rear end of the envelope E in the present embodiment, which prevents rotation of the envelope, but a side guide spanning the entire length of the envelope was not provided.
Further, in the present embodiment, when the printer
101
is attached there is a level difference G between the ASF case
47
and the top of the printer as shown in FIG.
8
. When the ASF sheet feeding tray
2
is closed the side guide
2
a
fits into that level difference G as shown in the same Figure.
Thus, by providing the side guide
2
a
onto one part of the ASF sheet feeding tray
2
in this way and fitting the side guide
2
a
into the level difference G, the side guide
2
a
does not interfere with other parts when the ASF sheet feeding tray
2
is closed, the ASF sheet feeding tray
2
can be fitted into a shape that follows the external form of the ASF, and the portability is not damaged and miniaturization is possible.
Incidentally, the side guide
2
a
must have a height greater than that of sheets such as envelopes when loaded, and the G must be higher than the side guide
2
a
in order to achieve the above effect.
The present embodiment prevents rotation during conveyance of an envelope vertically, but it can also prevent (regulate) rotation for any reason not only during vertical conveyance of an envelope but during conveyance of other sheets having a length as great as an envelope. Also, the side guide
2
a
can be provided at an extremely low cost because it is formed as a single body with the ASF sheet feeding tray
2
. The side guide
2
a
may also be formed such that there is no level difference G when the tray is shut, for example a concavity may be provided in advance into the printer
101
or the ASF
1
and the side guide
2
a
can be fit into this concavity.
If employing a side guide with such a construction on the sheet feeding tray
116
of the printer
101
, it can restrict sheet rotation even when using the printer
101
as a single unit. Further, by forming the side guide and the sheet feeding tray
116
as a single body, the side guide will not interfere with other parts when the sheet feeding tray
116
is shut, the sheet feeding tray
116
can be fit along the external shape of the printer, and the portability will not be damaged and miniaturization is possible.
Next the printer attachment and detachment mechanism of the ASF is described.
FIG. 11
is a perspective view showing the placement of parts relating to the printer attachment and detachment mechanism of the ASF
1
.
FIG. 12
is a drawing showing the placement of parts relating to the attachment to and detachment from the ASF
1
of the printer
101
.
In
FIG. 11
,
39
is a positioning standard which positions the sheet pass between the ASF
1
and the printer and positions the connection of the ASF connector
44
of the ASF
1
to the printer connector
117
.
Two positioning bosses
39
d
and
39
e
are provided onto the positioning standard
39
. When the printer
101
is attached to the ASF
1
, before the ASF connector
44
is connected to the printer connector
117
, the first positioning hub
39
d
is fitted into the positioning hole
118
a
provided onto the plate holder
118
of the printer
101
shown in FIG.
12
and the second positioning hub
39
e
is fitted into the oblong positioning hole
118
b.
Damage to the connectors through positioning slips between the connectors is prevented because the connectors are connected after positioning by fitting the two positioning bosses
39
d
and
39
e
into the positioning holes
118
a
and
118
b
. Also, positioning of the sheet pass between the printer
101
and the ASF
1
is completed at the same time because positioning of the ASF
1
and the printer in the x and the z directions is performed by fitting in the bosses
39
d
and
39
e.
A hook (left)
16
and a hook (right)
17
are provided into the printer slider
45
b
of the ASF
1
such that they can be pressed down or pulled up to position the printer in the y direction after it is attached to the ASF
1
. On the printer side, hook stabilizer holes
103
y
and
103
z
are provided into both sides of the base
103
of the printer
101
that interlock with the two hooks
16
and
17
.
Thus, when the printer
101
is attached to the ASF
1
, hook (left)
16
and hook (right)
17
provided on the ASF
1
interlock respectively with hook stabilizing holes
103
y
and
103
z
provided onto the printer and stabilize the printer
101
in the y direction.
The user detaches the printer
101
from the ASF
1
by pressing the push lever
40
in the direction shown by arrow
40
A. In other words, when the push lever
40
is pressed, hook (left)
16
and hook (right)
17
which protrude from the printer slider
45
b
retreat in the direction of arrow
40
A and are released from the hook stabilizer holes
103
y
and
103
z
of the printer
101
.
Afterward, the connection of connector
44
to
117
is released by pressing the upper portion of the sheet discharge side
102
a
of the printer
101
in the direction of
43
A (the y direction) by pop-ups
43
a
and
43
b
provided onto the ASF
1
. These pop-ups
43
a
and
43
b
are activated in the direction of
43
A (the y direction) by an elastic member not shown in the drawing and can be slid in the y direction.
As the force biasing the pop-ups
43
a
and
43
b
works with an opposing force when attaching the printer
101
to the ASF
1
, if the biasing force is strong, the printer
101
can not be pushed into the ASF
1
and attachment is not possible. Therefore an appropriate biasing force is set. (For example, an biasing force that will not move the ASF
1
when the printer
101
is attached to the ASF
1
.)
However, there are situations in which the extraction force needed to break the connection between the connectors is greater than the biasing force of the pop-ups
43
a
and
43
b
. In such a situation, the connection between the connectors can not only be released by the pop-ups
43
a
and
43
b
. Therefore, the present embodiment is constructed such that by pushing the push lever
40
in the direction of arrow
40
A a protruding portion
40
b
of the push lever
40
protrudes in the y direction.
Thus, the connection between the connectors (
44
and
117
) is released by protruding the protruding portion
40
b
of the push lever
40
and pressing the lower portion (or center portion) of the sheet discharge side of the printer
101
. By doing so, the user can easily pull the printer
101
from the ASF
1
in the y direction.
Next the attachment and detachment mechanisms of the ASF
1
and the printer
101
are explained further in detail.
FIG. 13
shows the placement of the mechanical parts relating to the printer detachment and attachment to the ASF
1
. As shown in
FIG. 13
, the push lever
40
is attached rotatably (arrows
40
A,
40
B, and
40
C) on a lever shaft
42
secured on a positioning base
39
. The push lever
40
is linked to the chassis
11
of the ASF
1
by a push lever spring
7
.
A boss
40
c
is provided onto the push lever
40
as a rotation stopper and slide surfaces
39
a
,
39
b
, and
39
c
that collide with the hub
40
c
are provided onto the positioning base
39
. Here the slide surface
39
c
is shown by a dotted line so the construction is easy to understand. With this construction, the rotation of the lever shaft
42
of the push lever
40
around a rotation center is restricted when the hub
40
c
of the push lever
40
collides with the guide surface
39
a.
The hook (left)
16
, along with the hook (right)
17
, is secured to a hook shaft
18
mounted rotatably on the chassis
11
. In this way the hook (left)
16
and the hook (right)
17
are linked. A connecting spring
9
is attached between the hook (left)
16
and the push lever
40
. The lower portion
40
d
of the push lever
40
is usually held abutting the upper surface of the hook (left)
16
by this connecting spring
9
.
A hook spring
3
is attached between the hook (left)
16
and the ASF base. The claw part of the hook (left)
16
is held protruding from the printer slider
45
b
of the ASF base
45
by this hook spring
3
.
FIG. 14
shows the printer set on top of the printer slider
45
b
in order to attach the printer
101
to the ASF
1
. In
FIG. 14
, the printer
101
is shown by a chain double-dashed line in order to explain the mechanism in a way that is easy to understand. The base
103
of the printer is shown as a sectional view.
When the printer
101
is moved along the printer slider
45
b
of the ASF base
45
in the direction of arrow A and pushed into the ASF
1
, first the claw portion
16
a
of the hook (left)
16
abuts the base front end
103
w
of the printer
101
. When the printer is pushed further, the hook (left)
16
is pushed down in the direction of arrow
16
A with a hook shaft
18
as the rotating axis and soon the upper end
16
a
2
of the claw portion
16
a
abuts the bottom surface
103
x
of the base
103
. At the same time, the push lever
40
lowers in the direction of arrow
40
A as it is linked to the hook (left)
16
by the connecting spring
9
.
In this pushed in position, the positioning bosses
39
d
and
39
e
are meshed into positioning hole
118
a
(see
FIG. 12
) and oblong positioning hole
118
b
(see
FIG. 12
) of the printer
101
as shown in FIG.
15
and the pre-connection connector positioning of the ASF connector
44
(see
FIG. 13
) and the printer connector
117
(see
FIG. 12
) is done.
Afterwards, when the printer is pushed further, the ASF connector
44
is connected to the connector
117
. Then, when the claw portion
16
a
of the hook (left)
16
reaches the hook securing hole
103
y
of the printer
101
, the hook (left)
16
rises in the direction of arrow
16
B through the biasing force of the hook spring
3
as shown in FIG.
16
and abuts the wall of the hook securing hole
103
y
of the printer
101
and they mesh together.
At the same time, the push lever
40
is also linked and rises in the direction of
40
B. Due to this action the user can confirm that the printer is attached (secured) to the ASF
1
.
Because the hook (left)
16
and the hook (right)
17
are secured on the hook shaft
18
, as long as both hooks
16
and
17
do not enter the hook securing holes
103
y
and
103
z
on the printer
101
(see
FIG. 12
) the push lever
40
will not rise in the direction of arrow
40
B. For example, the user can prevent incomplete attachment such as when the printer
101
is attached to the ASF
1
askew and one hook is not fitted into the hook securing hole of the printer
101
by checking the height of the push lever
40
.
However, in the present embodiment, the position of the hooks
16
and
17
when meshed with the printer
101
is set to the same position as the rotation center of the hooks
16
and
17
or to a position slightly higher than that rotation center. Thus, if the user tries to forcibly detach the printer
101
from the ASF
1
, the hooks
16
and
17
will stop in a position proportionate to the force, or in other words in a position at the same height as the center of rotation of the hooks
16
and
17
, and the printer can not be removed from the ASF
1
.
Next, detachment of the printer
101
from the ASF
1
is explained.
The user performs the operation of pressing the push part
40
a
of the push lever
40
in the direction of arrow
40
A by hand as shown in
FIG. 16
to detach the printer
101
from the ASF
1
. At this time, because the push lever
40
is sandwiched between the guide surfaces
39
a
and
39
b
provided onto the positioning base
39
, it cannot rotate around the lever shaft
42
until the guide surface
39
a
is gone, and it moves downward in the direction of arrow
40
A.
At the same time as the push lever
40
moves downward, hook (left)
16
rotates around the hook shaft
18
in the direction of arrow
16
A because the hook (left)
16
is linked to the push lever
40
, and the claw portion
16
a
of the hook (left)
16
is thereby released from the hook securing hole
103
y
of the printer
101
as shown in FIG.
17
. At the same time, the hook (right)
17
is released from the hook securing hole
103
z
, though it is not illustrated in the Figure.
When the claw portion
16
a
is released in this way, the upper portion of the sheet discharge side of the printer
101
shown in
FIGS. 16 and 17
with a dotted line is pushed against by the pop-up
43
and pushed out in the direction of arrow B. At the same time the ASF connector
44
is released from the printer connector
117
.
If the user presses the push lever
40
in the direction of
40
A in this condition, the form shown in
FIG. 15
is achieved. In other words, the connectors
44
and
117
are released, the hook
16
is released from printer
101
, and the user can easily remove the printer
101
from the ASF
1
.
However, as mentioned before, if the force pulling apart the connectors is greater than the force pushing the pop-ups, the printer
101
will not move even if the hook
16
is released from the printer
101
, the form shown in
FIG. 15
can not be achieved, and the user will not be able to remove the printer
101
from the ASF
1
.
Thus, as mentioned before a user push-out function was added to the present embodiment.
FIG. 17
shows the condition when the printer
101
will not move even though hook
16
has been released from the printer
101
. In this condition, the hook (left)
16
is in the released position from the hook securing hole
103
y
and the rotation restriction of the hub
40
c
of the push lever
40
by the guide surface
39
b
of the positioning base
39
has been released.
The lever shaft
42
is pressed toward the upper end surface of the sliding hole
40
e
of the push lever
40
thereby restricting the downward motion of the hook (left)
16
. Further, the position of the hook (left)
16
will not change even if the push lever
40
rotates because the surface
40
e
that abuts the hook (left)
16
of the push lever
40
is in the shape of an ark that rotates around the lever shaft
42
.
In this condition if the user continues to press the push part
40
a
of the push lever
40
, the push lever
40
will rotate in the direction of
40
D around the lever shaft
42
. Then the hook (left)
16
will be released from the printer
101
due to the rotation of the push lever
40
in this way, the protrusion
40
b
of the push lever
40
will abut the lower portion of the sheet discharge side
102
b
of the printer
101
, and the printer will be pushed out in the direction of the arrow B.
If the user continues to press the push lever
40
after this, the abutting surface
40
c
of the push lever
40
will abut against a stopper
39
d
of the positioning base
39
, and the rotation of the push lever
40
will be regulated in this position. The amount the printer
101
was pushed by the push lever
40
is set to the amount that releases the hook (left)
16
from the printer
101
.
After pushing the printer
101
in this way the user releases the pressure on the push part
40
a
of the push lever
40
. Thus, the hook (left)
16
rises in the direction of arrow
16
B due to the hook spring
3
when the pressure is released in this way. At the same time the push lever
40
also rises up due to the hook (left)
16
, the boss
40
c
of the push lever
40
abuts the guide surface
39
c
of the positioning base
39
, and the push lever
40
rotates in the direction of arrow
40
E due to the pulling force of the spring
7
on push lever
40
.
When the boss
40
c
of the push lever
40
hits the guide surface
39
a
of the positioning base
39
, rotation of the push lever
40
is restricted and the push lever
40
rises in the direction of arrow
40
B due to the spring force of the hook spring
3
.
Because of this, the connection of the connectors is finally released as shown in
FIG. 15
, the hook (left)
16
is also released from the printer
101
, and the user can easily remove the printer
101
from the ASF
1
.
In the present embodiment as explained up to now, when the printer is detached from the ASF
1
a force acts on the ASF
1
in a perpendicular direction because the push lever
40
is pressed in an approximately perpendicular direction. As a result, when the printer is pushed out in an approximately horizontal direction, the ASF
1
will not slip. Further, because the printer
101
is pushed in an approximately horizontal direction, reattachment caused by the printer moving in the attachment direction due to its own weight will not occur.
FIG. 19
is a drawing showing the power relationship between and placement of the push lever
40
, the pop-ups
43
a
and
43
b
, the positioning bosses
39
d
and
39
e
, the hook (left)
16
and the hook (right)
17
, and the ASF connector
44
in the present embodiment.
FIG. 20
is a partial sectional view of the top of the ASF
1
.
As shown in
FIGS. 19 and 20
, the positioning bosses
39
d
and
39
e
of the printer and the hooks
16
and
17
are provided in the vicinity of both ends across the width of the printer
101
. The ASF connector
44
is between the two positioning bosses
39
e
and
39
d
close to the second positioning boss
39
e
. Also, the push lever
40
and the second pop-up
43
b
are placed in a position even from the first positioning hub than the ASF connector
44
.
With such a configuration, when removing the printer
101
from the ASF
1
, the push lever
40
is pushed in the direction of arrow
40
A as mentioned earlier, and by pushing the protrusion
40
b
of the push lever
40
to the printer
101
at the same time with the hooks
16
and
17
released from the hook securing holes
103
y
and
103
z
(see
FIG. 14
) of the printer
101
, one can release the connector connection and release the hooks
16
and
17
from the hook securing holes
103
y
and
103
z
of the printer
101
.
The pop-ups
43
a
and
43
b
are a supplementary means of decreasing the force of the user pushing the push lever
40
, and they are slidably biased to a designated position on the side of the printer when pushed out by an elastic material not shown in the drawings.
In the present embodiment, the printer is pushed out while sliding on the printer slider
45
b
with the positioning bosses
39
d
and
39
e
as centers of rotation.
Here, because the printer positioning hole
118
a
on the first positioning hub side, which serves as rotation fulcrum, is a round hole and the positioning hole
118
b
on the second positioning hub side is an oblong hole (see FIG.
12
), if the user tries to remove the printer
101
in the condition shown in
FIG. 20
from the ASF
1
with the first positioning boss
39
d
as the rotation fulcrum, the position of the printer in relation to the ASF
1
will be as shown in FIG.
21
.
However, in this condition, the printer
101
can not be moved by the pushing force of the first pop-up
43
a
alone because crimping has occurred between the first positioning boss
39
d
and the positioning hole
118
a
. If the user tries to remove the printer
101
from the ASF
1
, the first positioning boss
39
d
will be deformed or damaged.
Therefore, the present embodiment is constructed to prevent the fit of the first positioning boss
39
d
which serves as the rotation fulcrum of the printer
101
with the positioning hole
118
a
from crimping due to slippage in the direction of connector release caused by the pushing force of the first pop-up
43
a
before the printer
101
is pushed out by the push lever
40
and the second pop-up
43
b.
In other words, the force needed to push out the printer
101
using the pushing force of the first pop-up
43
a
with the first positioning boss
39
e
as the rotation fulcrum given the placement dimensions shown in
FIG. 19
, is the value below:
F
1
>(
X
1
/
X
2
)×
P
1
+
P
2
In the equation above, F
1
is the printer pushing force of the first pop-up
43
a
, P
1
is the extraction force of the connector
44
, P
2
is the friction between the printer
101
and the printer sliding surface
45
b
of the ASF
1
, X
1
is the distance from the second positioning boss
39
e
which serves as rotation fulcrum to the connector
44
, and X
2
is the distance from the second positioning boss
39
e
to the first pop-up
43
a.
As is clear from the above equation, the greater the distance between the first pop-up
43
a
and the ASF connector
44
, in other words the smaller the value of X
1
/X
2
, the smaller the value for the pushing force F
1
of the first pop-up
43
a
that can be set. This printer pushing force F
1
of the first pop-up
43
a
works as a reactive force when the printer
101
is attached to the ASF
1
as mentioned earlier, and considering that the extraction force of the connector is, in general, from 1 to 2 kgf, a value of not more than 0.5 for X
1
/X
2
is appropriate.
In the present embodiment, the height of the claw of hook (right)
17
is formed to be lower than the height of the claw of hook (left)
16
. Thus the hook (right)
17
is released before the hook (left)
16
when the hooks
16
and
17
are released from the hook securing holes
103
y
and
103
z
(see
FIG. 12
) on the printer
101
.
Due to this, in the instant that the hook (right)
17
is released first from its position fitted into the hook securing hole
103
z
of the printer
101
, the printer
101
rotates due to the pushing force of the first pop-up
43
a
with the second positioning boss
39
e
as rotation fulcrum and accompanying this rotation the position of the fitted first positioning boss
39
d
and the positioning hole
118
a
moves toward the connector connection release side as shown in FIG.
22
.
After that, if the hook (left)
16
is released from the hook securing hole
103
y
and the printer
101
is pushed out by the push lever
40
and the second pop-up
43
b
, the printer
101
can be removed from the ASF
1
as the first positioning boss
39
d
and the positioning hole
118
a
do not crimp together as shown in FIG.
23
.
If the push lever
40
and the second pop-up
43
b
are placed between the first positioning boss
39
d
which serves as rotation fulcrum for the printer
101
and the ASF connector
44
, when the connection force between the connectors is great, the connector
44
becomes the rotation fulcrum of the printer
101
, the first positioning boss
39
d
and the positioning hole
118
a
of the printer
101
that form a round hole fit crimp together, and there is a danger of deforming of the boss
39
d
due to this crimping.
As a result, it is necessary to place the push lever
40
and the second pop-up
43
b
farther away from the first positioning boss
39
d
which is the rotation fulcrum of the printer
101
than the ASF connector
44
. Controller
FIG. 24
is a block diagram of the connections of the externally attached ASF controller and the controller of the main body of the printer in the present invention.
The main body controller
202
that controls the main body of the printer
101
is placed on the main body plate
123
shown in FIG.
4
and comprises a microcomputer connected by a bus to a CPU
203
, a ROM
204
and a RAM
205
.
When the main body of the printer
101
records, this main body controller
202
drives a carriage motor
121
through a motor driver
208
based on a main body control program stored in the ROM
204
and records one line by driving a recording head
115
attached to a carriage not shown in the drawing connected to the carriage motor
121
through a head driver
210
.
After that, the main body controller
202
feeds a sheet by driving the sheet feeding motor
120
through the motor driver
206
and finishes recording onto the sheet by repeating the driving of the carriage motor
121
and the recording head
115
a second time. A connector
117
that functions as a communication port that can communicate in two directions to output to the outside a command signal from the CPU
203
of the main body controller and input to the CPU
203
a response signal from the outside and can also supply a power source to the outside as will be described later. A paper end sensor
108
is provided inside the main body of the printer and has either an optical switch or a mechanical switch. When a sheet
200
is inserted into the main body of the printer, the output voltage of the paper end sensor changes from LO (low) to HIGH. A discharge sensor
113
has the same function as the paper end sensor
108
. If the sheet
200
remains inside the main body of the printer after recording, the output voltage of the discharge sensor changes to HIGH.
The output voltage of both the paper end sensor
108
and the discharge sensor
113
can both be monitored by the CPU
203
and the output voltage of the paper end sensor
108
is connected such that it can output directly to the outside through the connector
117
.
The ASF controller
201
that controls the externally attached ASF
1
comprises a microcomputer connected through a bus to a CPU
213
, a ROM
214
, and a RAM
215
as is the printer main body controller
202
. The CPU
213
drives a sheet feeding motor
27
through a motor driver
216
based on an ASF control program stored in the ROM
214
. The ASF connector
44
functions as a communication report and can communicate in two directions to receive a signal from an external device such as the printer main body
101
and output a signal from the CPU
213
of the ASF controller.
Communication Port
FIG. 26
shows a model of the detailed construction of the connector
117
and the ASF connector
44
. Connector
117
and the ASF connector
44
each has eight ports,
117
a
to
117
h
and
44
a
to
44
h
respectively. When the ASF
1
is attached to the printer
101
, the ports with corresponding letters are electrically connected.
Looking from the ASF
1
,
44
a
designate a GND line,
44
b
designate a
5
v
power line for signals,
44
e
designate a
34
v
power line for driving the sheet feeding motor
27
,
44
f
designate a transmission port that transmits signals to the printer side,
44
g
designate a receiving port that receives signals from the printer side, and
44
h
designate a line that receives the output voltage of the paper end sensor
108
inside the main body of the printer. As
44
c
and
44
d
are short-circuited, it can easily find out that equipment has been externally connected using the ports
117
c
and
117
d
on the printer side. ASF detachment and conveyance mechanism portion
FIG. 25
is a sectional view showing the condition when the externally attached ASF is attached to the main body of the printer in the present invention.
A sheet feeding roller
19
feeds out sheet
200
. A pick-up rubber
23
has been fitted around the sheet feeding roller
19
and when the sheet feeding roller
19
rotates the sheet
200
is conveyed by the friction of the pick-up rubber
23
.
The reference numeral
26
designates a pressure plate on which the sheet
200
is loaded, with both ends of the upstream side with respect to the sheet conveying direction axially supported on the ASF chassis
11
such that it can rotate. The pressure plate
26
is activated in the direction of the pick-up rubber
23
by the pressure plate spring
13
but the pressure plate
26
is held apart from the pick-up rubber
23
because a cam
19
c
provided into both ends of the sheet feeding roller
19
and a cam
26
a
provided into both ends of the pressure plate
26
interlock during initialization, so that the sheet
200
can be set smoothly. Inclined surface
36
has an abutting surface
36
a
on the sheet conveying direction extension of the pressure plate
26
which is set such that the front end of the sheet
200
abuts this abutting surface
36
a
when the sheet is set. A separating sheet
37
is mounted on the abutting surface
36
a
as a sheet separating means. The separating sheet
37
is a sheet made of an elastic material such as plastic film and functions to separate one sheet at a time using the elasticity evoked when it is bent.
Printer Conveyance Mechanism, Printing Mechanism
Next the conveyance mechanism and printing mechanism of the main body of the printer in
FIG. 25
is explained.
An LF roller
109
conveys the sheet
200
. This LF roller
109
is formed from a metallic pipe with a paint film of a material with a high friction coefficient such as urethane resin on its surface that rotates driven by the sheet feeding motor
120
shown in FIG.
24
and conveys the sheet
200
by pinching it between itself and the pinch roller
110
.
A recording head
115
records image information on the sheet
200
conveyed by the LF roller
109
loaded onto a carriage not shown in the drawing and it can move back and forth across the length of the LF roller
109
. The recording head
115
is driven along with the carriage by the carriage motor
121
in FIG.
24
and can move back and forth across the width of the sheet
200
(perpendicular to the surface of the sheet).
The spur
111
and the discharge roller
112
are positioned on the downstream side of the LF roller
109
and the recording head
115
and form a pair of double rollers to convey the sheet
200
when printing is finished. The discharge roller
112
is connected to the LF roller by a drive transmission means not shown in the drawing and rotates such that it conveys the sheet
200
in the same direction as the LF roller
109
with the LF roller
109
as drive source.
A paper end sensor
108
is provided on the sheet pass further upstream than the LF roller
109
with respect to the sheet conveying direction and a discharge sensor
113
is set between the pair of double discharge rollers. The output voltage of each sensor changes from LO to HIGH when the sheet
200
passes by. ASF driving mechanism
FIGS. 27 and 28
show the driving mechanism of the externally attached ASF in the present invention.
The sheet feeding motor
27
is a stepping motor that can drive in both forward and reverse. An idle gear
15
interlocks with the motor gear
27
a
of the sheet feeding motor
27
. An ASF double gear
29
has a double gear with different diameters and interlocks with the idle gear
15
. A forward planetary gear
31
interlocks with the gear with the smaller diameter of the ASF double gear and revolves around the perimeter of the ASF double gear. A reverse sun gear
33
has a double gear with different diameters and interlocks with the gear with the smaller diameter of the ASF double gear
29
. A reverse planetary gear
35
interlocks with the gear with the smaller diameter of the reverse sun gear
33
and revolves around the perimeter of the reverse sun gear. A sheet feeding roller gear
19
a
is provided on the axial end of the sheet feeding roller
19
. The sheet feeding roller
19
is provided on the revolving axis of the forward planetary gear
31
and the reverse planetary gear
35
and is placed in a position that interlocks with each gear.
Next the operation of each gear is explained. In
FIG. 27
, when the sheet feeding motor.
27
rotates in the direction of arrow b (reverse drive), each gear rotates in the direction of the respective arrows. In other words, the reverse planetary gear
35
revolves around the perimeter of the reverse sun gear
33
by way of the idle gear
15
and the ASF double gear
29
from the position shown by the broken line to the position shown by the solid line in the direction shown by the arrow in
FIG. 27
, and interlocks with the sheet feeding roller gear
19
a
. Due to this, the sheet feeding roller rotates in the direction shown by the arrow in the drawing (in the direction that the sheet
200
stacked on the pressure plate
26
is fed to the printer
101
). When the sheet feeding roller gear
19
rotating interlocked with the reverse planetary gear
35
rotates to a position such that the untoothed portion
19
b
faces the reverse planetary gear
35
it slips from that gear and ceases to rotate even when the sheet feeding motor is driven in reverse.
In this condition, the forward planetary gear
31
revolves from the position shown by the dotted line to the position shown by the unbroken line in the direction of the arrow shown in
FIG. 27
, but does not influence the rotation of the sheet feeding roller
19
because it hits a stopper not shown in the drawing and stops.
Next, when the sheet feeding motor
27
rotates in the direction of arrow f (positive drive), each gear rotates in the direction of the arrows shown in
FIG. 28
respectively. In other words, the forward planetary gear
31
revolves by way of the idle gear
15
and the ASF double gear
29
around the periphery of the ASF double gear
29
from the position shown by the dotted line toward the position shown by the unbroken line in the direction of the arrow shown in the drawing and interlocks with the sheet feeding roller gear
19
a
. In this way, the sheet feeding roller
19
rotates in the direction of the arrow shown in
FIG. 28
(in the direction that the sheet stacked on the pressure plate
26
is fed to the printer). When the sheet feeding roller
19
a
rotating interlocked with the forward planetary gear
31
rotates to a position such that the untoothed portion
19
b
faces the forward planetary gear
31
it slips from that gear and ceases to rotate even when the sheet feeding motor is driven forward.
In this condition, the reverse planetary gear
33
revolves from the position shown by the broken line to the position shown by the solid line in the direction of the arrow shown in
FIG. 28
, but does not influence the rotation of the sheet feeding roller
19
because it hits a stopper not shown in the drawing and stops.
Further, when the untoothed portion
19
b
of the sheet feeding roller gear
19
a
faces the forward planetary gear
31
, the cam of the sheet feeding roller
19
c
interlocks perfectly with the cam
26
a
of the pressure plate
26
resulting in the same phase as at initialization, and the pressure plate
26
and pick-up rubber
23
are placed set apart from each other.
Accordingly, when the sheet feeding motor
27
is driven forward continuously, the sheet feeding roller cam
19
c
and the pressure plate cam
26
a
interlock and the sheet feeding roller
19
ceases rotation with the same phase as at initialization with the pressure plate
26
and the pick-up rubber
23
separated. Afterwards, because the forward planetary gear
33
and the reverse planetary gear
35
both idle in the positions shown by the solid lines in
FIG. 28
no rotation is transmitted to the sheet feeding roller
19
and it is stabilized.
As explained above, regardless of whether the sheet feeding motor
27
runs forward or in reverse, the sheet feeding roller
19
will only rotate in the direction that the sheet
200
is fed to the printer
101
and will not rotate in the opposite direction. Sheet feeding operation and printing operation (printer side)
Next the chain of operations in which the printer and the ASF discharge a sheet after feeding, conveying and recording is explained.
When a recording command is received from an external information device such as a computer, the printer
101
first performs a sheet feeding operation and then performs a recording operation.
FIG. 29
is a control flow if the printer is performing a sheet feeding operation. First, the main body controller
202
of the printer
101
carries out sub-flow C
1
. The details of the contents will be described later using
FIG. 33
, but the sub-flow C
1
is for the purpose of judging the type of machine attached to the outside of the printer through ports
117
f
and
117
g
shown in FIG.
26
.
Next the controller proceeds to S
1
. If the results of sub-flow C
1
indicated that an ASF was attached to the printer
101
, it proceeds to S
2
for ASF sheet feeding. In S
2
, the main body controller
202
sends an initializing command to the ASF and proceeds to S
3
.
In S
3
, if there is no response signal indicating that initialization is finished from the ASF, the controller returns to S
3
and proceeds to S
4
when it receives a response. In S
4
, the main body controller
202
sends a sheet feeding command signal and a kind of sheet signal expressing the kind of sheet for sheet feeding (plain paper, coated paper, post card, glossy film, etc.) to the ASF and proceeds to S
5
.
In S
5
, if no response is received from the ASF it proceeds to S
8
and if a pre-set time limit of t
2
seconds has not elapsed the main body controller
202
returns to S
5
. In S
8
, if the time limit t
2
seconds has elapsed since commencement of sheet feed, it proceeds to S
9
and generates a sheet feeding error signal and ends the sheet feeding operation. In S
5
there is a response signal from the ASF and if this is a signal indicating that sheet feeding is finished, the controller proceeds to S
7
. Step S
7
performs an operation of feeding leading end to initial position on the sheet
200
and the main body controller
202
rotates the LF roller
109
by driving the sheet feeding motor
120
only by a designated amount R
3
in the sheet conveying direction (forward) at time of recording and ends the sheet feeding operation. The designated amount R
3
is set such that the front end of the sheet
200
comes directly under the recording head
115
but does not reach the area where sheet detection by the discharge sensor
113
is possible. Accordingly, when the printer
101
next begins recording on the sheet
200
, there is no need to return the sheet
200
upstream of the conveying direction, and the sheet will not be bent or misfed because the rear end of the sheet
200
will not impact on the internal parts of the ASF.
Also in S
5
, if there is a response signal from the ASF and it indicates an error in sheet feeding, the main body controller
202
proceeds to S
9
, issues a sheet feeding error, and ends the operation of sheet feeding.
In S
1
, if the result from the sub-flow C
1
indicated that the ASF was not attached to the printer
101
the controller proceeds to S
10
for manual sheet feeding.
In S
10
, if the user has not inserted a sheet no sheet will be detected because the output voltage of the paper end sensor
108
remains at LO, and the controller returns to S
10
. When the user inserts a sheet
200
into the printer
101
and it contacts the LF roller
109
, the output voltage of the paper end sensor
108
changes to HIGH and the sheet is detected, and so the controller proceeds to S
11
. In S
11
, the main body controller
202
drives the sheet feeding motor
120
by the sheet feeding motor driver
206
such that the LF roller
109
rotates forward (in the rotation direction that will convey the sheet in the conveying direction when recording) only by a designated amount R
4
. The designated amount R
4
is set to the amount that will cause the front end of the sheet
200
to reach the area where the discharge sensor
113
can detect the sheet. Next the controller proceeds to S
12
, and if the discharge sensor
113
senses the sheet
200
it judges that sheet feeding was successful and proceeds to S
13
. In S
13
, the main body control means
202
drives the sheet feeding motor
120
with the sheet feeding motor driver
206
such that the LF roller
109
rotates in reverse (in the rotation direction that will convey the sheet in the opposite direction as the conveying direction when recording) only by a designated amount R
5
. The designated amount R
5
is set at the amount that will return the sheet
200
that was conveyed to the range where detection by the discharge sensor
113
was possible to the position where recording will begin, and where the front end of the sheet
200
is not coming out from between the LF roller
109
and the pinch roller
110
.
Also in S
12
, if the discharge sensor
113
does not detect the sheet
200
, for example if the sheet
200
contacted the LF roller
109
weakly and was not correctly sucked between the LF roller
109
and the pinch roller
110
or if the front end of the sheet
200
did not reach the range where it could be detected by the discharge sensor
113
though it was conveyed by the designated amount R
4
because it struck the LF roller
108
askew, the main body controller
202
judges this a manual sheet feeding failure and proceeds to S
14
. In S
14
, the main body control means
202
drives the sheet feeding motor
120
with the sheet feeding motor driver
206
such that the LF roller
109
rotates in reverse only by a designated amount R
6
.
The designated amount R
6
is set at an amount large enough so that the front end of the sheet
200
that was conveyed up to the range where it can be detected by the discharge sensor
113
to stick out from the LF roller
109
and the pinch roller
110
.
In this way, during manual feeding one can confirm definitely that the sheet feeding went well by confirming whether or not the discharge sensor detected the sheet
200
. It has the further advantage that when the sheet feeding fails, the sheet
200
can be easily removed and manual sheet feeding can be repeated because the sheet
200
is returned to a position where it is not pinched by the LF roller.
As there are no parts that collide in a different way during manual feeding from auto feeding with the ASF attached, even if the sheet
200
is conveyed in the opposite direction this will not cause it to bend or misfeed.
The printer
101
that has finished the operation of sheet feeding through the sheet feeding control flow described above next performs a recording operation. The main body controller
202
drives the carriage motor
121
with the motor driver
208
, drives the recording head
115
attached to a carriage not shown in the drawing connected to the carriage motor
121
with the head driver
210
and records one line. After that, the main body controller
202
conveys the sheet
200
by one line only by driving the sheet feeding motor
120
with the motor driver
206
and finishes recording onto the sheet by repeating the recording head
115
drive and the carriage motor
121
drive. When recording is finished, the main body controller
202
drives the sheet feeding motor
120
and rotates the LF roller
109
forward. Due to this the discharge roller
112
rotates, and the sheet
200
is discharged from the printer
101
.
Sheet Feeding Operation (ASF Side)
FIG. 30
shows a main control flow of the ASF, which can be externally attached to the printer in the present invention. The controller
201
of the ASF
1
in the present invention is usually on standby when the ASF is attached to the printer
101
, and if no command signal is received from the printer
101
as shown in S
37
it repeats performing S
37
until a command signal is received. When a command signal from the printer
101
is received with the serial receiving port
44
g
in
FIG. 26
, it proceeds to the following sub-flow or step in response to the contents of the command signal. In other words, if the command signal from the printer
101
indicates “sheet feeding command”, it proceeds to sub-flow C
2
that controls the ASF sheet feeding operation, and if the signal indicates “initializing command”, it proceeds to sub-flow C
3
that controls the initializing operation. When each sub-flow is finished it proceeds again to S
37
and goes into standby. If the command signal from the printer
101
indicates “kind of device judging command”, it proceeds to step S
6
and when it has sent the code ID that expresses the type of device of the ASF itself via the serial transmission port
44
f
to the printer
101
, it proceeds to S
37
and goes into standby.
Of the two sub-flows mentioned above, sub-flow C
2
that controls the ASF sheet feeding operation is described first and the details of sub-flow C
3
that controls the initialization operation will follow.
FIG. 31
is sub-flow C
2
that controls the sheet feeding operation in the ASF
1
.
The ASF controller
201
first advances to S
15
where it reads driving table T of the appropriate sheet feeding motor
27
for the type of sheet to be fed from the ROM
214
to the CPU
213
based on the type of sheet information received from the printer
101
and the sheet feeding command signal. The driving table T includes such information as the driving speed of the sheet feeding motor
27
, which is a pulse motor, and the number of pulses P
5
in correction registration in order to rotate the sheet feeding roller
19
only by the amount appropriate to the type of sheet when correcting registration in step S
22
to be described later. Multiple values are prepared corresponding to hypothesized sheet characteristics.
After reading the driving table T the ASF controller
201
advances to step S
16
and sets each variable, designated as INIT, n, and Pc to the initialization value of 0. Each variable is stored in the RAM
215
, with INIT as a flag showing whether or not the phase of the rotation direction of the sheet feeding roller
19
is in the initialization position, n as a rotation number counter, indicating how many times the sheet feeding roller
19
has rotated since the beginning of the sheet feeding flow C
2
, and Pc as a number of pulses counter that indicates how many pulses the sheet feeding motor
27
was driven reversely.
Proceeding to S
17
, the ASF controller drives the sheet feeding roller
19
one pulse reversely via the sheet feeding motor driver
216
. Advancing to S
18
, the value of number of pulses counter Pc is increased by one, and it proceeds to S
19
. In S
19
, the ASF controller
201
compares the value of number of pulses counter Pc to the size of the allowed number of pulses Pmax.
The allowed number of pulses Pmax is the total number of pulses such that the sheet feeding roller rotates up to a position where the untoothed portion
19
b
of the sheet feeding roller gear faces the reverse planetary gear
35
as explained in
FIG. 27
after the sheet feeding motor
27
begins reversely, and does not rotate any further. Immediately after the start of sheet feeding, the relationship of Pc <Pmax is satisfied, so the controller advances to step S
20
. In S
20
, the ASF control means
201
checks the output voltage of the paper end sensor
108
within the printer
101
through the port
44
h
shown in FIG.
26
. The output voltage of the paper end sensor
108
is LO because immediately after the start of sheet feeding operations the sheet
200
still has not reached the inside of the printer
101
, thus the controller returns to S
17
. In this way steps S
17
to S
20
are repeated and the reverse planetary gear
35
revolves from the position shown by the broken line to the position shown by the solid line in FIG.
27
and interlocks with the sheet feeding roller gear
19
a
, whereupon the sheet feeding roller
19
begins to rotate. When the sheet feeding roller
19
begins to rotate from the initialization phase, the sheet feeding roller cam
19
c
slips from the pressure plate cam
26
a
, the pressure plate
26
is raised upward by the pressure plate spring
13
, and the sheet
200
loaded on the pressure plate
26
is compressed by the pick-up rubber
23
. At this time the front end of the sheet
200
abutted by the abutting surface
36
a
of the inclined surface
36
is also raised upward and contacts the approximate middle of the separating sheet
37
.
When the sheet feeding roller
19
is rotated by repeating S
17
to S
20
further and continuing to drive the sheet feeding motor
27
reversely, conveyance of the sheet
200
by the force of the friction of the pick-up rubber
23
begins, the front end of the sheet
200
is separated from the sheet below by a reactive force caused by pressing the elastic separating sheet
37
, and one sheet only is fed forward.
However, if reverse drive of the sheet feeding motor
27
is continued until the number of pulses counter Pc reaches a certain size, the relationship of Pc<Pmax is not satisfied, and the controller branches off from S
19
and advances to S
24
. In S
24
, the ASF controller
201
drives the sheet feeding motor
27
forward only by a designated number of pulses P
4
. The designated number of pulses P
4
is the number of pulses sufficient to rotate the sheet feeding roller to the initialization position by driving with the forward planetary gear
31
. In other words, by performing S
24
, the sheet feeding roller
19
rotates to a phase exactly one rotation after the initialization position, the exact position at which the portion of the sheet feeding roller gear without teeth
19
b
faces the reverse planetary gear
31
and they are released from each other, and stops. The controller then proceeds to S
25
, returns the number of pulses counter Pc to 0, increases the number of rotations counter n by one, and proceeds to step S
26
. In step S
26
at this time n still equals one, and so it returns to step S
17
and begins to drive the sheet feeding motor
27
reversely again.
As mentioned above, the ASF controller
201
repeats steps S
17
to S
20
, begins the second rotation of the sheet feeding roller
19
, and further conveys the sheet
200
. When the front end of the sheet
200
reaches the paper end sensor
108
within the printer
101
, the output voltage of the paper end sensor changes to HIGH, and the controller proceeds from S
20
to S
21
. In S
21
, the ASF controller
201
compares the value of the number of pulses counter Pc added to the value of the registration correcting pulse number P
5
within the driving table T with the size of the allowed number of pulses Pmax. If the relationship of Pc+P
5
=Pmax is satisfied, it advances to S
22
because the transmission of the reverse driving will not be released in the middle even if the sheet feeding motor
27
is driven reversely by P
5
pulses only.
If the relationship of Pc+P
5
>Pmax is satisfied, the controller advances to S
24
because if the sheet feeding motor
27
is further driven reversely by P
5
pulses only, the portion of the sheet feeding roller gear without teeth
19
will arrive at a position facing the reverse planetary gear
35
halfway through and the driving transmission to the sheet feeding roller will be cut off. In S
24
, the controller drives the sheet feeding motor forward again by P
4
pulses only and returns the sheet feeding roller
19
to initialization position, sets Pc to 0 and n to n+1 in S
25
, and advances to S
26
. Usually at this time n=2 because at the second rotation of the sheet feeding roller
19
the paper end sensor
108
detects the sheet
200
, so the controller returns to S
17
. At that time, as the output voltage of the paper end sensor
108
is already at HIGH and the number of pulses counter Pc has just been reset, the controller advances from S
17
through S
18
, S
19
, S
20
, to S
21
, and then advances to S
22
because this time the relationship Pc+P
5
=Pmax is fulfilled.
S
22
is where so-called registration correction is performed. The ASF controller
201
drives the sheet feeding motor reversely only by the number of pulses P
5
from the driving table T and rotates the sheet feeding roller
19
. At this time, the front end of the sheet
200
is sent from a position where it is detected by the paper end sensor
108
further into the printer
101
and stopped when it hits a nip formed by the stopped LF roller
109
and the pinch roller
110
, but the rear of the sheet
200
is pushed further by the sheet feeding roller
19
. As a result, the front end of the sheet
200
is aligned parallel to the nip portion formed by the LF roller
109
and the pinch roller
110
.
Proceeding next to step S
23
, the ASF controller
201
sends a signal indicating that sheet feeding is finished to the printer
101
via the serial transmission port
44
f
shown in FIG.
26
and ends operation.
If a sheet is not stacked on the pressure plate
26
, no matter how many times the sheet feeding roller
19
rotates, the output voltage of the paper end sensor will not turn to HIGH.
As a result, after the ASF controller
201
has twice repeated the operation in which is repeated a certain number of times the loop of S
17
to S
18
to S
19
to S
20
to S
17
and then returned to S
17
via the loop of S
19
to S
24
to S
25
to S
26
, when it reaches S
26
for the third time it proceeds to S
27
because the sheet feeding roller
191
number of rotations counter n equals 3, sends a sheet feeding error signal to the printer
101
and ends operations.
Other Operations (Printer Side, ASF Side)
FIG. 32
is the sub-flow C
3
for controlling the initialization operations of the ASF
1
. When the ASF
1
receives an initialization command signal from the printer main body
101
, the ASF controller
201
proceeds to S
28
and checks the value of the INIT flag that indicates whether or not the phase of the rotation direction of the sheet feeding roller
19
is in the initialization position. If INIT=1, the sheet feeding roller
19
is already in the initialization position and it advances to step S
31
and finishes the operation by sending an initializing finished signal to the printer
101
. If INIT=0, it advances to S
29
and drives the sheet feeding roller motor
27
forward only by a designated number of pulses P
0
. The designated number of pulses P
0
is set as the value sufficient to rotate the sheet feeding roller
19
to the initialization position such that the portion of the sheet feeding roller gear untoothed portion
19
b faces the forward planetary gear
31
no matter where the phase of the rotation direction of the sheet feeding roller
19
is. By performing S
29
, the sheet feeding roller
19
rotates ad returns to the initialization position, the pressure plate
26
and the pick-up rubber
23
separate, and the sheet
200
can be set smoothly.
The controller next advances to step S
30
to change the INIT flag to 1 to indicate that the sheet feeding roller is in the initialization position, and advancing to S
31
sends an initializing finished signal to the printer
101
and ends operation.
FIG. 33
is the sub-flow C
1
for performing judging of the kind of device attached to the outside of the printer via the ports
117
f
and
117
g
shown in FIG.
26
. The main body controller
202
first proceeds to step S
32
and sends kind of device judging command to the external device via the port
117
g
. Next it proceeds to S
33
, and if no response signal is received from the external device via the port
117
f
, it proceeds to S
35
and then returns to S
33
if a designated time limit of t
1
has not elapsed. In S
35
, if the time limit t
1
has elapsed, the controller advances to S
36
and judges that no external device is attached and ends operation.
In S
33
, if a response signal is received from the external device, the controller proceeds to S
34
. In S
34
, the main body controller
202
reads partial code ID that indicates kind of device attached from the response signal received and ends operation.
FIGS. 34 and 35
show the second embodiment of the control flows of the printer and of the externally attached ASF attachable to the printer of the present invention. The same symbols are used for parts having the same functions and forms as in the first embodiment and for operation that are the same and the detailed explanation has been summarized.
In the first embodiment the ASF controller
201
advances to S
23
after reversely driving the sheet feeding motor by P
5
pulses only in S
22
as shown in FIG.
31
and sends a sheet feeding finished signal to the printer
101
. However in this case because the sheet feeding roller
19
has not returned to the initialization position, the sheet feeding roller
19
remains compressed on the sheet
200
as shown in FIG.
36
. In this condition, if head scanning or recording operations on the printer main body side are performed only by the LF roller alone, back tension from the sheet feeding roller
19
will occur and there is the danger that the precision of the conveyance of the sheet
200
will decline.
The second embodiment is an improvement regarding this problem.
After the ASF controller
201
performs the correction registration operation in S
22
as shown in
FIG. 35
, it advances to S
38
and drives the sheet feeding motor
27
forward by a designated number of pulses P
6
only. The designated number of pulses P
6
is the number of pulses sufficient to rotate the sheet feeding roller to the initialization position by driving with the forward planetary gear
31
. At the same time as it starts the forward driving of the sheet feeding motor
27
it operates the counter for measuring the elapsed time since start of driving and advances to S
39
when a designated amount of time t
3
has elapsed and sends a request for synchronous driving to the printer main body
101
side. The designated amount of time t
3
is slightly larger than the amount of time from the start of driving the sheet feeding motor
27
in S
38
until the forward planetary gear
31
revolves so that the sheet feeding roller
19
interlocks with the sheet feeding roller gear
19
a
and begins to rotate.
In S
38
, the speed that the sheet feeding motor
27
is driven is set such that the peripheral speed of the pick-up rubber
23
attached to the sheet feeding roller
19
is slightly larger than the peripheral speed when the LF roller
109
of the printer main body rotates in S
7
.
When the step S
38
is finished, the sheet feeding roller
19
rotates to the same phase as the initialization position and the controller advances to S
40
. In S
41
, the ASF controller
201
changes the INIT flag to “1” to indicate that the rotation direction phase of the sheet feeding roller is in initialization condition and ends operations.
In S
39
, the printer main body controller
202
, which receives the request for synchronous driving sent by the ASF controller
201
, advances from S
5
to S
7
shown in FIG.
34
and begins to rotate the LF roller
109
forward.
A time chart outlining which operations the printer main body
101
and the ASF
1
perform according to elapsed time in the present embodiment is shown in FIG.
37
.
When the printer begins sheet feeding operations, it first sends a command for judging the kind of device to the ASF side (S
32
). The ASF sends to the printer side a signal ID indicating the code of the kind of device it is (S
37
). Next, the printer sends to the ASF side an ASF initializing command (S
2
), and the ASF performs an initializing operation by rotating the sheet feeding roller if it is not initialized (S
29
) and sends to the printer an initializing finished signal (S
31
). Then the printer sends a sheet feeding command to the ASF (S
4
). The ASF drives the sheet feeding motor based on the sheet feeding operation control flow C
2
and rotates the sheet feeding roller (S
18
) after it has read the driving table T that is appropriate based on the sheet feeding command and the kind of sheet information sent (S
15
, omitted from FIG.
37
). When the output voltage of the paper end sensor
108
provided on the printer changes to HIGH and the sheet is detected, the ASF rotates the sheet feeding roller further by the amount Rl only, based on the before-mentioned pulse number P
5
, the so-called correcting registration operation (S
22
). After the correcting registration operation is finished, the ASF rotates the sheet feeding roller further by an amount R
3
only to the same position as initialization (S
38
) and sends a request for synchronous driving to the printer when the amount of time t
3
only has elapsed since the beginning of sheet feeding motor driving (S
39
).
The printer, having received the request for synchronous driving from the ASF, rotates the LF roller by the amount R
3
only, the so-called operation of feeding leading end to initial position (S
7
).
As is clear from the above explanation, in the present embodiment, in
FIG. 36
showing the condition when step S
22
is finished, the sheet feeding roller
19
begins to rotate and the LF roller
109
begins to rotate shortly thereafter. At this time the peripheral speed of the pick-up rubber
23
is slightly faster than the peripheral speed of the LF roller
109
. Therefore when the LF roller begins to rotate because of the operation of feeding leading end to initial position in S
7
, no back tension occurs because the pick-up rubber
23
compressed by sheet
200
begins to rotate slightly before it. Furthermore, no back tension occurs as a result of the difference in peripheral speeds because the peripheral speed of the pick-up rubber
23
is slightly faster than the peripheral speed of the LF roller, and the conveyance precision during head scanning of the sheet
200
is stable.
However if t
3
is too small, there is a danger than the LF roller
109
will start to rotate before the driving force of the sheet feeding motor
27
is transmitted to the sheet feeding roller
19
. If t
3
is too large, there is the danger that the sheet feeding roller
19
will rotate a lot before the LF roller
109
begins to rotate, and the sheet
200
will be deformed halfway through or the front end will not align parallel to the nip formed by the LF roller
109
and the pinch roller
110
. As a result of experiments, in the present embodiment, 10 ms to 100 ms was the most appropriate value for t
3
. In the case the peripheral speed of the pick-up rubber
23
attached to the sheet feeding roller
19
is not very fast compared to the peripheral speed of the LF roller
109
, there is a danger that back tension will occur when the pick-up rubber
23
slips due to the kind of sheet
200
or the peripheral environment. If the peripheral speed of the pick-up rubber
23
is too fast, there is a danger than the sheet
200
will be deformed. As a result of experiments, in S
38
of the present embodiment, the most appropriate condition for the peripheral speed of the pick-up rubber
23
is 5% to 50% faster than the peripheral speed of the LF roller
109
in S
7
.
The signal name “request for synchronous driving” in the present embodiment was corresponds to the signal name “finishing sheet feeding” in the first embodiment because of a difference in the meaning of the operation, but no problems result if the same signal as “finishing sheet feeding” is used as. the actual signal. Accordingly, the sheet feeding operation control flow of the printer main body in the first and second embodiments (
FIGS. 29 and 34
) are in essence identical. In other words, the printer indicated in the first embodiment can be used by attaching to the ASF shown in either the first or the second embodiment.
Next the contents of the multiple driving tables T in the second embodiment are explained using FIG.
38
.
For example if the kind of sheet information received from the ASF
1
indicated plain paper, the ASF controller
201
selects driving table
1
. For plain paper the driving speed is set at medium speed because the resistance during correcting registration in step S
22
is low. Also, since the sheet is rarely conveyed askew during sheet feeding there is no need to make the amount the sheet is pushed by the LF roller
109
large and a small value can be set for the number P
5
of pulses in correcting registration.
If the kind of sheet information received from the ASF
1
indicated an envelope, the ASF controller
201
selects driving table T
3
. Here the driving speed is set at a low speed relative to plain paper and a large torque is ensured such that the sheet feeding motor
27
does not malfunction, because the resistance during correcting registration is particularly large in step S
22
. As an envelope more easily falls aslant during sheet feeding compared to other kinds of sheets (skew feeding easily occurs), a medium value, larger than table T
1
for plain paper, is set for the number P
5
of pulses in correcting registration in step S
22
. By doing so the front end of the envelope can be aligned with more precision because the amount the front end of the envelope is pushed by the LF roller
109
increases.
If the kind of sheet information indicated glossy paper, the ASF controller
201
selects driving table T
4
. Resistance during correcting registration is large for glossy paper, but skew feeding does not occur easily. As a result a low speed is set for the driving speed in correcting registration and a small value, equivalent to that for plain paper, is set for number P
5
of pulses in correcting registration in T
4
.
If the kind of sheet information indicated a postcard, the ASF controller
201
selects driving table T
2
. A postcard does not have a large resistance in correcting registration, so a medium speed, equal to that for plain paper, is set for the driving speed in correcting registration.
However, when the LF roller
109
on the printer side in FIG.
37
and the ASF sheet feeding roller
19
are rotating at the same time, a very rigid sheet such as a postcard is not easily deformed and ends up being pushed in when the sheet feeding roller
19
with a high peripheral speed resists the fricative force of the LF roller
109
. Because the front end of the postcard ends up being conveyed than the rotation amount R
3
of the LF roller, correct printing results may not be achieved. In order to avoid this, the largest possible value for number P
5
of pulses in correcting registration in step S
22
is set in table T
2
. Concretely, a variable, expressed by P
5
=Pmax—Pc, determined by the number of reverse driving pulses of the sheet feeding motor needed for the paper end sensor
108
to detect the sheet
200
is set. By doing so, no matter when the paper end sensor
108
detects the sheet
200
, the total number of pulses the sheet feeding motor
27
is driven reversely when step S
22
is finished in
FIG. 35
will be Pmax. In other words, the untoothed portion
19
b
of the sheet feeding roller gear
19
a
definitely rotates until the position where it faces the reverse planetary gear
35
and slips from contact. As a result, the rotation direction phase of the sheet feeding roller
19
after completion of step S
22
moves from initialization position to a position greatly advanced, and then the phase of the sheet feeding roller
19
returns quickly to initialization position even if the sheet feeding roller
19
rotates in step S
40
. Accordingly, because the postcard loaded on the pressure plate
26
and the pick-up rubber
23
are quickly separated immediately after synchronous driving of the LF roller
109
and the sheet feeding roller
19
begins, the postcard is no longer pushed in by resistance of the sheet feeding roller
19
to the friction of the LF roller
109
.
If the kind of sheet information received by the ASF
1
from the printer
101
is a kind of sheet that does not fit with the ASF
1
or if a kind of sheet is not indicated, the ASF controller
201
selects driving table T
5
. In the present embodiment the same values are stored in driving table T
5
as in driving table T
2
for postcards, but depending on the hypothesized situation, the same values as another kind of sheet table, or values that are completely different from any other kind of sheet table can be stored in T
5
.
Claims
- 1. A recording apparatus including a recording apparatus main body which has a sheet feeding aperture and which can record an image on a sheet manually fed from the sheet feeding aperture, and an auto sheet feeder which is detachably attached to the recording apparatus main body and which can automatically feed a sheet to the recording apparatus main body via the sheet feeding aperture, said recording apparatus comprising:positioning means for manual sheet feeding for aligning the sheet feeding position by restricting sides of a sheet manually fed from the sheet feeding aperture, wherein said positioning means for manual sheet feeding is retractable such that the sheet fed from the auto sheet feeder does not abut said positioning means for manual sheet feeding when the auto sheet feeder is attached to the recording apparatus main body.
- 2. A recording apparatus according to claim 1, wherein said positioning means for manual sheet feeding retracts below a pass through which the sheet fed from the auto sheet feeder passes.
- 3. A recording apparatus according to claim 2, wherein said positioning means for manual sheet feeding is provided on a sheet feeding tray for supporting the sheets manually fed from the sheet feeding aperture, and a tray receiving portion is provided on the auto sheet feeder for receiving the sheet feeding tray such that the sheet feeding tray can be retracted below the pass when the auto sheet feeder is attached to the recording apparatus main body.
- 4. The recording apparatus according to claim 3, wherein said positioning means for manual sheet feeding has a moving positioning member movable in accordance with the sheet size, and the tray receiving portion can receive the sheet feeding tray regardless of the position of the moving positioning member.
- 5. The recording apparatus according to claim 3, wherein the auto sheet feeder has a sheet supporting means for supporting a sheet stack, a sheet feeding means for feeding sheets from the sheet supporting means, and a sheet separation means for separating sheets fed from the sheet feeding means one by one, and a positioning means for auto sheet feeding provided on the sheet supporting means.
- 6. The recording apparatus according to claim 5, wherein a main body positioning means is provided on the recording apparatus main body for restricting the position of the sides of the sheet manually fed, the manual sheet feeding standard is set by the main body positioning means and said positioning means for manual sheet feeding, and the manual sheet conveying standard is positioned the outer side in the width direction of the sheet than a sheet feeding standard for sheets fed automatically set by said positioning means for auto sheet feeding.
- 7. A recording apparatus according to claim 3, wherein the sheet feeding tray is mounted rotatably on the recording apparatus main body between a position for closing the sheet feeding aperture and a position for supporting the sheet, and the sheet feeding tray is received portion by the tray receiver by rotating from the position for supporting the sheet when the auto sheet feeder is attached to the recording apparatus main body.
- 8. The recording apparatus according to claim 7, wherein a guide is provided on the tray receiving portion for guiding the sheet feeding tray to the tray receiving portion by rotating further from the position for supporting sheets when the auto sheet feeder is attached to the recording apparatus main body.
- 9. A recording apparatus according to claim 1, wherein said positioning means for manual sheet feeding retracts to the side of the pass through which the sheet fed from the auto sheet feeder passes.
- 10. The recording apparatus according to claim 1, wherein the auto sheet feeder has a sheet supporting means for supporting a sheet stack, a sheet feeding means for feeding sheets from the sheet supporting means, and a sheet separation means for separating sheets fed from the sheet feeding means one by one, the sheet separation means has a plate member that can change form elastically and an inclined surface placed on the downstream side of the plate member, and the tray receiving portion is placed on the inside of the inclined surface.
- 11. The recording apparatus according to claim 10, wherein the plate member separates sheets of slight rigidity and the inclined surface separates sheets of great rigidity.
- 12. The recording apparatus according to claim 1, wherein the recording apparatus main body is portable and a recording means of the recording apparatus main body is ink jet system.
Priority Claims (1)
Number |
Date |
Country |
Kind |
10-105240 |
Apr 1998 |
JP |
|
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Jul 1992 |
EP |
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Jun 1995 |
EP |
6-183582 |
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JP |
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