TECHNICAL FIELD
The present disclosure relates to a feed device in which a feed tray which accommodates a medium is provided to be installable to and removable from a housing.
BACKGROUND
A related-art discloses two paper feed trays that are installed to be freely pulled out of a main body of an image processing device and accommodate a roll body of a medium rolled in a roll shape. The paper feed trays are disposed in two stages including an upper stage and a lower stage, and respectively include a feed-out roller that conveys the medium unrolled from the roll body, a paper feed path that guides the medium conveyed by the feed-out roller, and a cutter cutting the medium passing through the paper feed path.
SUMMARY
Illustrative aspects of the present disclosure provide a feed device that reduces occurrence of paper feed failure of a medium caused by an operation of installing and removing a feed tray to and from a housing.
A feed device of the present disclosure includes: a feed tray configured to accommodate a roll, in which a medium is rolled in a roll shape, rotatably; a housing that configured to support the feed tray installable; and a pull-back mechanism configured to pull back the medium unrolled from the roll in a direction orthogonal to a rotation axis of the roll in conjunction with an outward movement of the feed tray from the housing in the direction orthogonal to the rotation axis of the roll.
According to a feed device of the present disclosure, when a feed tray is removed from a housing, a medium unrolled from a roll is pulled back. Therefore, when the feed tray is reinstalled to the housing, a tip of the medium hardly contacts the housing and the like, such that the medium is hardly bent. Therefore, it is possible to prevent occurrence of paper feed failure of the medium caused by an operation of installing and removing the feed tray to and from the housing.
BRIEF DESCRIPTION OF DRAWINGS
Illustrative embodiments of the disclosure will be described in detail based on the following figures, wherein:
FIG. 1 is a perspective view of a printer in which a feed device according to an illustrative embodiment of the present disclosure is adopted;
FIG. 2 is a schematic side view illustrating an internal structure of the printer illustrated in FIG. 1;
FIG. 3 is a schematic plan view of the printer illustrated in FIG. 1;
FIG. 4 is a block diagram of a controller;
FIG. 5 is a side view illustrating an internal structure of the feed device and illustrating a fully installed state of a second feed tray on a housing;
FIG. 6 is a plan view of the feed device illustrated in FIG. 1 in a state where a medium is not accommodated;
FIG. 7 illustrates the internal structure of the feed device, and is a side view when a pinion gear starts to be engaged with a rack gear in a half-installed state of the second feed tray on the housing;
FIG. 8 illustrates the internal structure of the feed device, and is a side view when the pinion gear is engaged with the rack gear in the half-installed state of the second feed tray on the housing; and
FIG. 9 illustrates the internal structure of the feed device, and is a side view when the pinion gear is located in front of the rack gear in the half-installed state of the second feed tray on the housing.
DETAILED DESCRIPTION
Since the paper feed tray described in the related art includes the cutter in addition to the feed-out roller, the paper feed tray itself has a complicated configuration. Therefore, for example, the present inventor examines simplification of the configuration of the paper feed tray itself by installing the feed-out roller and the cutter in a housing for installing the paper feed tray provided in the main body of the image processing device, or on a side of an additional housing installable to and removable from the main body of the image processing device and provided for installing the paper feed tray. As a result, the following problems are required to be considered.
When a cutting mechanism such as a cutter is provided on the housing side, a tip of the medium cut by the cutting mechanism is disposed at a position protruding above the paper feed tray. When the paper feed tray is moved in this state and removed from the housing, and then the paper feed tray is reinstalled to the housing, the tip of the medium may contact a component provided in the housing (for example, a paper feed roller and the like) such that the medium may be bent. When the medium is bent due to an operation of installing and removing the paper feed tray to and from the housing in this manner, paper feed failure may occur after the paper peed tray is installed thereon.
Therefore, illustrative aspects of the present disclosure provide a feed device that reduces occurrence of paper feed failure of a medium caused by an operation of installing and removing a feed tray to and from a housing.
Hereinafter, a printer 1 in which a feed device 3 according to an illustrative embodiment of the present disclosure is adopted will be described. The printer 1 is installed and used in a state illustrated in FIG. 1. In the illustrative embodiment, three directions indicated by arrows in FIG. 1 are an up and down direction A1, a front and rear direction A2, and a left and right direction A3. The three directions illustrated in FIG. 1 are the same in the other drawings.
Overview of Printer 1
As illustrated in FIG. 1, the printer 1 is formed in an approximately rectangular parallelepiped shape, and includes a printer main body 2 and the additional feed device 3 installed to a lower portion of the printer main body 2. The printer main body 2 includes a housing 11. An opening 12 is formed approximately in the center of a front wall 11a of the housing 11. A first feed tray 15 and a paper discharge tray 16 are provided in two upper and lower stages. The first feed tray 15 is configured to be insertable into and removable from the opening 12 in the front and rear direction A2, that is, to be installable to and removable from the housing 11. A cut sheet paper P1 of a desired size (for example, an A4 size) is placed on the first feed tray 15. The printer main body 2 is connectable to an external device such as a personal computer (hereinafter referred to as a PC). Next, a recording operation is executed based on a recording command from the PC. Various functions are also executed by a user operating an operation button.
As illustrated in FIG. 1, the front wall 11a of the housing 11 includes an opening and closing cover 4 on a right side part thereof. The opening and closing cover 4 is configured to be pivotable at a lower end portion thereof with a rotation axis (not illustrated) along the left and right direction A3 as a rotation center.
Internal Structure of Printer Main Body 2
Next, an internal structure of the printer main body 2 will be described. As illustrated in FIGS. 2 and 3, the printer main body 2 includes a first feeder 20, a pair of conveyance rollers 35, a recorder 40, a tank unit 18, a pair of paper discharge rollers 36, a first auto sheet feed (ASF) motor 20M (refer to FIG. 4), a line feed (LF) motor 35M (refer to FIG. 4), and a controller 5 (refer to FIG. 4).
The first feeder 20 feeds paper P1 placed on a first feed tray 15 to a conveyance path 25. The pair of conveyance rollers 35 conveys the paper P1 fed by the first feeder 20 and a medium P2 fed from a feed device 3 via a branch path 25a to the recorder 40. The recorder 40 has, for example, an inkjet recording type configuration, and records an image on the paper P1 and the medium P2 conveyed by the pair of conveyance rollers 35. The pair of paper discharge rollers 36 discharges the paper P1 and the medium P2 recorded by the recorder 40 to the paper discharge tray 16.
Tank Unit 18
As illustrated in FIG. 3, the tank unit 18 includes four tanks 18a to 18d. The four tanks 18a to 18d are provided on a downstream side of the printer main body 2 in a conveyance direction and in a part on a right side in FIG. 3, and are disposed side by side in the left and right direction (a scanning direction) A3. Black, yellow, cyan, and magenta inks are stored in the four tanks 18a to 18d in order from the one located on the right side. That is, the black ink is stored in the rightmost tank 18a, and the color inks are stored in the other three tanks 18b to 18d. Next, the inks of the four colors stored in the four tanks 18a to 18d are supplied to an inkjet head 41 (described later) via four tubes and the like (not illustrated).
First Feeder 20
As illustrated in FIG. 2, the first feeder 20 is provided on an upper side of the first feed tray 15. The first feeder 20 includes a first paper feed roller 21 and a first arm 22. The first paper feed roller 21 is pivotally supported by a tip of the first arm 22. The first arm 22 is pivotably supported by a support shaft 22a, is urged by a spring or the like, and is pivoted downward so that the first paper feed roller 21 contacts the first feed tray 15. The first arm 22 is configured to be retractable upward when the first feed tray 15 is attached and detached. The first paper feed roller 21 is rotated by power of the first ASF motor 20M transmitted via a transmission mechanism (not illustrated), and the paper P1 stacked in the first feed tray 15 is fed to the conveyance path 25.
First Feed Tray 15
As illustrated in FIG. 2, the first feed tray 15 includes an inclined wall portion 15a. The inclined wall portion 15a guides the paper P1 to the conveyance path 25 when the paper P1 placed on the first feed tray 15 is fed by the first paper feed roller 21.
Conveyance Path 25
The conveyance path 25 is formed in the housing 11, and as illustrated in FIG. 2, is bent upward from a rear end portion of the first feed tray 15 and bent toward a front side of the printer 1. The paper P1 fed from the first feed tray 15 is guided by the conveyance path 25 so that the paper P1 makes a U-turn from the bottom to the top and reaches the recorder 40.
Branch Path 25a
The branch path 25a is connected to the conveyance path 25. The branch path 25a is also formed in the housing 11, extends in the up and down direction A1 behind the first feed tray 15, and is connected to the conveyance path 25. The medium P2 fed from the feed device 3 is guided from the branch path 25a to the conveyance path 25, and is guided from the bottom to the front by the conveyance path 25 to reach the recorder 40.
Pair of Conveyance Rollers 35 and Pair of Paper Discharge Rollers 36
The pair of conveyance rollers 35 includes a conveyance roller 35a disposed on a lower side and a pinch roller 35b disposed on an upper side. The conveyance roller 35a is rotated by power of the LF motor 35M transmitted via a transmission mechanism (not illustrated). The pinch roller 35b rotates with the rotation of the conveyance roller 35a. The conveyance roller 35a and the pinch roller 35b cooperate with each other so that the paper P1 and the medium P2 are interposed therebetween in the up and down direction A1, and convey the paper P1 and the medium P2 to the recorder 40.
The pair of paper discharge rollers 36 includes a paper discharge roller 36a disposed on a lower side and a spur roller 36b disposed on an upper side. The paper discharge roller 36a is rotated by the power of the LF motor 35M transmitted via the transmission mechanism (not illustrated). The spur roller 36b rotates with the rotation of the paper discharge roller 36a. The paper discharge roller 36a and the spur roller 36b cooperate with each other so that the paper P1 and the medium P2 are interposed therebetween in the up and down direction A1, and convey the paper P1 and the medium P2 to the paper discharge tray 16.
Recorder 40
As illustrated in FIGS. 2 and 3, the recorder 40 includes an inkjet head (one example of a recording head) 41, a head moving mechanism 50, and a platen 6. The head moving mechanism 50 includes a carriage 51. The carriage 51 reciprocates in the scanning direction (which is the left and right direction A3 and a direction orthogonal to the conveyance direction of the paper P1 and the medium P2). The inkjet head 41 is supported by the carriage 51.
A lower surface of the inkjet head 41 is an ejection surface 41b formed with a plurality of ejection ports 41a for ejecting ink to the paper P1 and the medium P2 conveyed below the inkjet head 41. As illustrated in FIG. 3, the plurality of ejection ports 41a are arranged so that the ejection port rows arranged along the conveyance direction are formed in four rows in the scanning direction. In the illustrative embodiment, black ink is ejected from the ejection ports 41a belonging to the rightmost ejection port row in FIG. 3, and color inks (magenta, cyan, and yellow) are ejected from the ejection ports 41a belonging to the ejection port rows of the other three rows. The inkjet head 41 ejects ink of each color as a minute ink droplet from the ejection ports 41a under the control of the controller 5 based on a recording command.
A tube joint 44 is provided to be integrated with the inkjet head 41. The inkjet head 41 and the tank unit 18 are connected to each other via four flexible tubes (not illustrated) connected to the tube joint 44, and the ink of each color is supplied to the inkjet head 41.
The platen 6 that supports the paper P1 and the medium P2 conveyed by the pair of conveyance rollers 35 is disposed below the inkjet head 41. The platen 6 is disposed in a part of reciprocating movement ranges of the carriage 51, through which the paper P1 and the medium P2 pass. Since a width of the platen 6 is sufficiently larger than a maximum width of the paper P1 and medium P2 that can be conveyed, the paper P1 and the medium P2 conveyed through the conveyance path 25 always pass on the platen 6.
As illustrated in FIG. 3, the head moving mechanism 50 includes a pair of guide rails 52 and a belt transmission mechanism 53. The pair of guide rails 52 are disposed to be separated from each other in the front and rear direction A2 and extend parallel to each other in the left and right direction A3. The carriage 51 is disposed so as to straddle the pair of guide rails 52, and is reciprocated on the pair of guide rails 52 along the left and right direction A3.
The belt transmission mechanism 53 includes two pulleys 54 and 55, an endless timing belt 56 partially fixed to the carriage 51, and a carriage motor 50M. The two pulleys 54 and 55 are disposed to be separated from each other in the left and right direction A3, and the timing belt 56 is stretched therebetween. The pulley 54 is connected to a drive shaft of the carriage motor 50M, and when the carriage motor 50M is driven, the timing belt 56 travels and the inkjet head 41 moves in the scanning direction together with the carriage 51.
The inkjet head 41 ejects the ink of each color from the ejection ports 41a under the control of the controller 5 based on the recording command. That is, as the carriage 51 reciprocates in the left and right direction A3, the inkjet head 41 is scanned with respect to the paper P1 and the medium P2, and an image is recorded on the paper P1 and the medium P2 conveyed on the platen 6 by ejecting the ink of each color from the ejection ports 41a. A linear encoder (not illustrated) having a large number of translucent portions (slits) arranged with a space therebetween in the scanning direction is provided in the printer 1. On the other hand, the carriage 51 is provided with a transmission type position detection sensor (not illustrated) including a light emitting element and a light receiving element. The printer 1 can recognize a current position of the carriage 51 in the scanning direction from a count value of the translucent portion of the linear encoder detected by the position detection sensor while the carriage 51 is moving, and rotation drive of the carriage motor 50M is controlled.
As illustrated in FIG. 4, the controller 5 includes a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), an application specific integrated circuit (ASIC), and the like, and these devices cooperate with each other to control operations of the first ASF motor 20M, a second ASF motor 80M (described later), the LF motor 35M, the carriage motor 50M, the inkjet head 41, a motor for cutting 90M (described later), and the like. For example, the controller 5 controls the inkjet head 41, the first ASF motor 20M, the LF motor 35M, the carriage motor 50M, and the like based on the recording command transmitted from the PC, and records an image and the like on the paper P1. The controller 5 also controls the inkjet head 41, the second ASF motor 80M, the LF motor 35M, the carriage motor 50M, the motor for cutting 90M, and the like based on the recording command transmitted from the PC, and records an image and the like on the medium P2.
While the controller 5 of the illustrative embodiment includes one CPU and one ASIC, the controller 5 may include only one ASIC, and the one ASIC may collectively perform required processes. Alternatively, the controller 5 may include a plurality of ASICs, and the plurality of ASICs may share and perform the required processes.
Feed Device 3
As illustrated in FIGS. 1, 2, 5, and 6, the feed device 3 includes a housing 60, a second feed tray 61, a pull-back mechanism 70, a second feeder 80, and a cutting mechanism 90. The feed device 3 can rotatably accommodate a roll P2a which will be described later. As illustrated in FIG. 1, the housing 60 has a rectangular parallelepiped shape and is configured to be installable to and removable from the lower portion of the printer main body 2. An opening 60b is formed approximately at the center of a front wall 60a of the housing 60. The housing 60 supports the second feed tray 61. The second feed tray 61 is configured to be insertable into and removable from the opening 60b in the front and rear direction A2 (in an orthogonal direction), that is, to be installable to and removable from the housing 60.
Second Feed Tray 61
As illustrated in FIGS. 5 and 6, the second feed tray 61 includes a tray main body 61a, a support base 61b for supporting the roll P2a of the medium P2, and a conveyance guide 61d. The support base 61b and the conveyance guide 61d are configured to be installable to and removable from the tray main body 61a. As illustrated in FIG. 6, the tray main body 61a has a rectangular planar shape. The tray main body 61a has a planar size which can accommodate, for example, cut sheet paper having an A4 size in a state where the support base 61b and the conveyance guide 61d are removed. As illustrated in FIG. 5, the tray main body 61a includes an inclined wall portion 61a1 at a rear end portion thereof. The inclined wall portion 61a1 guides the medium P2 fed by the second paper feed roller 81 toward the branch path 25a. A presser 61c for pressing the roll P2a toward the support base 61b is provided at a front end portion of the tray main body 61a. As illustrated in FIG. 5, the presser 61c includes a plate-shaped member 61c1 bent in a dogleg shape. The plate-shaped member 61c1 is supported by the tray main body 61a so that a front end of the plate-shaped member 61c1 is pivotable around a rotation axis 61c2. Accordingly, the presser 61c presses the roll P2a toward the support base 61b by allowing the plate-shaped member 61c1 to pivot by its own weight with the rotation axis 61c2 as the rotation center. Therefore, even though a weight of the roll P2a becomes smaller as the medium P2 decreases, a slip hardly occurs between a roller 71 which will be described later and the roll P2a. Therefore, the roll P2a can be rotated by the roller 71. The plate-shaped member 61c1 of the presser 61c may press the roll P2a by an urging force of an urging member such as a spring. The medium P2 is paper which is the same as the paper P1, and may be cloth and the like.
As illustrated in FIGS. 5 and 6, the conveyance guide 61d includes a plate-shaped guide member 61d1 and a roller 61d2. As illustrated in FIG. 6, the guide member 61d1 has an approximately rectangular planar shape extending in the left and right direction A3, a notch portion 61d3 is formed in a rear center thereof, and a notch portion 61d4 is formed in a front side thereof. The notch portion 61d3 is formed so that tip portions of the second paper feed roller 81 and a second arm 82, which will be described later, can enter and exit by pivoting of the second arm 82. The roller 61d2 extending in the left and right direction A3 is disposed in the notch portion 61d4. Opposite end portions of the roller 61d2 in the left and right direction A3 are rotatably supported by the guide member 61d1. A roller 61a4 extending in the left and right direction A3 is rotatably supported by the tray main body 61a. The roller 61a4 is disposed at a position opposite to that of the roller 61d2 in the up and down direction A1. Accordingly, the medium P2 unrolled from the roll P2a can be interposed between the two rollers 61a4 and 61d2. Therefore, the roll P2a is set on the support base 61b, and the roller 61d2 is manually rotated counterclockwise in FIG. 5 in a state where the medium P2 unrolled from the roll P2a is interposed between the two rollers 61a4 and 61d2, such that a tip of the medium P2 is fed out up to a desired position and setting is easily performed. Here, the desired position is, for example, a position where the second feed tray 61 can contact the second paper feed roller 81 and a position in the vicinity of the rear end in FIG. 5 of the tray main body 61a in a fully installed state where the second feed tray 61 is fully installed to the housing 60.
As illustrated in FIGS. 5 and 6, the support base 61b is disposed between the center and the front end of the tray main body 61a in the front and rear direction A2. The support base 61b includes a base body 62 having an approximately rectangular parallelepiped shape extending in the left and right direction A3, and a plurality of rollers 63a to 63c. The base body 62 is formed with two inclined surfaces 62a and 62b provided on an upper surface of the base body 62 in a state where the center of the base body 62 in the front and rear direction A2 is interposed between the two inclined surfaces 62a and 62b. The inclined surface 62a of the two inclined surfaces 62a and 62b is disposed in a front side and the inclined surface 62b thereof is disposed in a rear side. The two inclined surfaces 62a and 62b are configured to incline downward as the two inclined surfaces 62a and 62b are close to each other. Eight rollers 63a are arranged along the left and right direction A3 at a rear end portion of the inclined surface 62a. Eight rollers 63b are arranged along the left and right direction A3 at a front end portion of the inclined surface 62b. Eight rollers 63c are arranged along the left and right direction A3 at a rear end portion of the inclined surface 62b. The plurality of rollers 63a and 63b contact a lower part of an outer peripheral surface P2a1 of the roll P2a of the medium P2, and support the roll P2a from below. The plurality of rollers 63c guide the medium P2 unrolled from the roll P2a. The plurality of rollers 63a to 63c are supported by the base body 62 so as to be rotatable around a rotation axis parallel to the left and right direction A3. Therefore, the roll P2a of the medium P2 can also rotate around a rotation axis C parallel to the left and right direction A3. A groove 62c opened upward is formed in the base body 62. As illustrated in FIG. 6, the groove 62c is located at the center of the base body 62 in the front and rear direction A2 and is disposed between the two inclined surfaces 62a and 62b. A penetrating portion 62d is formed in the center of the base body 62 in the left and right direction A3.
Pull-back Mechanism (Rotation Mechanism) 70
The pull-back mechanism 70 pulls back the medium P2 unrolled from the roll P2a in conjunction with an operation of removing the second feed tray 61 from the housing 60 by moving the second feed tray 61 in a direction orthogonal to the rotation axis C of the roll P2a. The pull-back mechanism 70 includes a rotation mechanism that rotates so as to pull back the medium P2 unrolled from the roll P2a in conjunction with the operation of removing the second feed tray 61 from the housing 60. In the illustrative embodiment, since the rotation mechanism itself is the pull-back mechanism 70, the rotation mechanism will be also described with the same reference sign as that of the pull-back mechanism 70. The rotation mechanism 70 includes a roller 71, a power transmission device 72, a pinion gear 73, and a rack gear 74 that can be engaged with the pinion gear 73. As illustrated in FIG. 6, the roller 71, the power transmission device 72, and the pinion gear 73 are disposed side by side in the left and right direction A3 at positions opposite to that of the penetrating portion 62d. The roller 71, the power transmission device 72, and the pinion gear 73 are rotatably and movably supported by a bottom portion 61a2 of the tray main body 61a in the up and down direction A1. As illustrated in FIG. 5, the roller 71 is formed to have a diameter larger than that of the pinion gear 73, and formed to have a size that allows the roller 71 to move up and down in the penetrating portion 62d. The roller 71 is supported to be movable between a separation position (refer to FIG. 5) at which the roller 71 is separated downward from the outer peripheral surface P2a1 of the roll P2a and a contact position (refer to FIG. 8) at which the roller 71 contacts the outer peripheral surface P2a1 of the roll P2a.
The power transmission device 72 is a known one-way clutch, and transmits a rotational force in one direction of the pinion gear 73 to the roller 71. In FIG. 5, the power transmission device 72 in the illustrative embodiment is configured to transmit the rotational force when the pinion gear 73 rotates counterclockwise to the roller 71, and configured not to transmit the rotational force when the pinion gear 73 rotates clockwise to the roller 71. The pinion gear 73 is configured to be rotatable by being engaged with the rack gear 74.
As illustrated in FIG. 5, the rack gear 74 is disposed on a bottom portion 60c of the housing 60, and disposed to be closer to the front than the center of the bottom portion 60c in the front and rear direction A2. The rack gear 74 is configured to extend along the front and rear direction A2, and to be able to be engaged with the pinion gear 73. That is, as illustrated in FIGS. 5 and 6, the rack gear 74 is disposed in front of the pinion gear 73 and is not engaged with the pinion gear 73 in the fully installed state where the second feed tray 61 is fully installed to the housing 60. On the other hand, the rack gear 74 is disposed at a position where the rack gear 74 can be engaged with a lower part of the pinion gear 73 in a half-installed state. The half-installed state refers to a state of the second feed tray 61 until the second feed tray 61 moves forward from the fully installed state and the second feed tray 61 is removed from the housing 60. The rack gear 74 is engaged with the pinion gear 73 when the second feed tray 61 moves forward from the fully installed state, thereby rotating the pinion gear 73 counterclockwise in FIG. 5. The rack gear 74 is also engaged with the pinion gear 73 when the second feed tray 61 in the half-installed state on the housing 60 moves rearward, thereby rotating the pinion gear 73 clockwise in FIG. 5. The rack gear 74 is disposed at a position at which the roller 71 can be located from the separation position to the contact position when the rack gear 74 is engaged with the pinion gear 73. As illustrated in FIG. 5, a groove 61a3 extending along the front and rear direction A2 is formed on a lower surface of the tray main body 61a such that the second feed tray 61 does not contact the rack gear 74 when the second feed tray 61 is installed to the housing 60.
Second Feeder 80
As illustrated in FIG. 5, the second feeder 80 is provided on an upper side of the second feed tray 61. The second feeder 80 includes the second paper feed roller 81 and the second arm 82. The second paper feed roller 81 is pivotally supported at a tip of the second arm 82. The second arm 82 is pivotably supported by a support shaft 82a, is urged by a spring or the like, and is pivoted downward so that the second paper feed roller 81 contacts the second feed tray 61. The second arm 82 is configured to be retractable to an upper retracted position (refer to FIG. 7) when the second feed tray 61 is attached to and detached from the housing 60. The second paper feed roller 81 is rotated by the power of the second ASF motor 80M transmitted via a transmission mechanism (not illustrated), and the medium P2 unrolled from the roll P2a accommodated in the second feed tray 61 is fed to the branch path 25a via the cutting mechanism 90.
Cutting Mechanism 90
As illustrated in FIGS. 5 and 6, the cutting mechanism 90 is installed in an upper rear portion of the housing 60. The cutting mechanism 90 is a known cutting mechanism that extends along the left and right direction A3 and can cut the medium P2 along the left and right direction A3. The cutting mechanism 90 includes a guide portion 92 that defines a conveyance path 91 through which the medium P2 fed by the second paper feed roller 81 passes, a cutter (not illustrated), and the motor for cutting 90M that drives the cutter (refer to FIG. 4). The cutter is configured to be movable along the left and right direction A3 and cuts the medium P2 in the conveyance path 91. The cutting mechanism 90 cuts the medium P2 fed by the second feeder 80 at a desired position under the control of the controller 5. Therefore, a tip of the cut medium P2 is disposed at a position above a tip of the second feed tray 61 (a rear end in FIG. 5). In the illustrative embodiment, the tip of the cut medium P2 is located in the conveyance path 91. In the illustrative embodiment, the cutting mechanism 90 is provided in the housing 60, and may be provided in the printer main body 2.
Operation of Rotation Mechanism 70
Next, an operation of the rotation mechanism 70 when the second feed tray 61 of the feed device 3 is attached to and detached from the housing 60 will be described below with reference to FIGS. 5 and 7 to 9. As illustrated in FIG. 5, the printer 1 is usually used when the second feed tray 61 is in the fully installed state on the housing 60. Since the medium P2 is cut by the cutting mechanism 90 when the medium P2 is used for image recording, the tip thereof exists in the conveyance path 91.
When a user pulls out the second feed tray 61 forward to remove the second feed tray 61 from the housing 60 in order to look inside the second feed tray 61, the roll P2a is rotated by the rotation mechanism 70, the medium P2 is rerolled, and the tip of the medium P2 moves. At this time, the second arm 82 moves to the retracted position.
More specifically, when the second feed tray 61 moves from the fully installed state illustrated in FIG. 5 to the position illustrated in FIG. 7 in the half-installed state, the pinion gear 73 and the rack gear 74 start to be engaged with each other. Next, when the second feed tray 61 further moves forward from this state, as illustrated in FIG. 8, the pinion gear 73 moves upward while rotating counterclockwise in FIG. 8 by the engagement between the pinion gear 73 and the rack gear 74. That is, the roller 71 also moves from the separation position illustrated in FIG. 5 to the contact position illustrated in FIG. 8 together with the pinion gear 73, and rotates counterclockwise in FIG. 8. Therefore, the roller 71 contacts the outer peripheral surface P2a1 of the roll P2a, and the roll P2a rotates clockwise in FIG. 8 around the rotation axis C by the roller 71.
Next, when the second feed tray 61 further moves forward, the roller 71 rotates clockwise in FIG. 8 while the pinion gear 73 and the rack gear 74 are engaged with each other. After that, as illustrated in FIG. 9, the pinion gear 73 moves forward of the rack gear 74, and when the engagement therebetween ends, the rotation of the roller 71 also stops. At this time, the roller 71 moves from the contact position illustrated in FIG. 8 to the separation position illustrated in FIG. 9 together with the pinion gear 73. The roll P2a is rotated by the roller 71 in conjunction with the operation of removing the second feed tray 61 from the housing 60, while the pinion gear 73 is engaged with the rack gear 74. As illustrated in FIG. 9, the medium P2 is rerolled by the rotation of the roll P2a, such that the tip of the medium P2 is disposed between a rear end of the conveyance guide 61d and the tray main body 61a. That is, the rotation mechanism 70 is configured to rotate the roll P2a by pulling out the second feed tray 61 from the fully installed state up to a position where the pinion gear 73 is located in front of the rack gear 74 (a position where the engagement between the pinion gear 73 and the rack gear 74 ends), so that the tip of the medium P2 moves from the conveyance path 91 to the front of a contact point between the second paper feed roller 81 and the bottom portion 61a2 of the tray main body 61a illustrated in FIG. 5. When the second feed tray 61 is pulled out from the fully installed state up to the position where the pinion gear 73 is located in front of the rack gear 74, the rotation mechanism 70 may be able to rotate the roll P2a up to a position where the tip of the medium P2 is located below an upper end of the inclined wall portion 61a1 of the tray main body 61a.
After that, the second feed tray 61 is removed from the housing 60, and then the user moves the second feed tray 61 rearward and reinstalls the second feed tray 61 on the housing 60. At this time, while the pinion gear 73 and the rack gear 74 are engaged with each other and the pinion gear 73 rotates clockwise in FIG. 5, the power transmission device 72 does not transmit the rotational force of the pinion gear 73 to the roller 71 such that the roller 71 does not rotate the roll P2a. Therefore, the tip of the medium P2 does not move when the second feed tray 61 is installed to the housing 60, and is in a state of being located in the tray main body 61a, that is, below the upper end of the inclined wall portion 61a1. Even though the second feed tray 61 is pulled out from the housing 60 and then reinstalled to the housing 60 in this manner, the tip of the medium P2 is disposed in the tray main body 61a, such that the tip of the medium P2 does not contact components of the second feeder 80 and the housing 60 when the second feed tray 61 is installed thereon. Therefore, the second feed tray 61 can be installed to the housing 60 without bending the tip of the medium P2.
As described above, according to the feed device 3 of the illustrative embodiment, when the second feed tray 61 is removed from the housing 60, a part of the medium P2 unrolled from the roll P2a is rerolled to the roll P2a, and the tip of the medium P2 is pulled back from the conveyance path 91 into the second feed tray 61. Therefore, when the second feed tray 61 is reinstalled to the housing 60, the tip of the medium P2 hardly contacts the housing 60 and the like, such that the tip thereof is hardly bent. Therefore, even though the second feed tray 61 is attached to and detached from the housing 60, the tip of the medium P2 is hardly bent, thereby making it possible to prevent occurrence of paper feed failure such as jamming of the medium P2 when the medium P2 is fed.
Since the rotation mechanism 70 includes the roller 71, the pinion gear 73, and the rack gear 74, with a relatively simple configuration, the roller 71 can be rotated to rotate the roll P2a when the second feed tray 61 is removed from the housing 60.
Since the second feed tray 61 includes the tray main body 61a and the support base 61b, and the roller 71 is supported by the tray main body 61a, the roll P2a of the medium P2 placed on the support base 61b can be rotated by the roller 71 when the second feed tray 61 is removed from the housing 60.
Since the tray main body 61a is configured to be able to accommodate the cut sheet paper in a state where the support base 61b is removed, it is also possible to feed the cut sheet paper.
Since the pinion gear 73 has a diameter smaller than that of the roller 71, the pinion gear 73 can rotate relatively more than the roller 71 even though a moving distance when the second feed tray 61 is removed from the housing 60 is short. Therefore, the roller 71 can also rotate by the desired number of times, such that the roll P2a can rotate by the required number of times.
The roller 71 is disposed at the separation position when the rack gear 74 and the pinion gear 73 are not engaged with each other, and is located at the contact position from the separation position when the rack gear 74 and the pinion gear 73 are engaged with each other. Accordingly, in the fully installed state of the second feed tray 61, since the roller 71 is disposed at the separation position, a conveyance load caused by the roller 71 is not generated when the medium P2 is fed.
The rotation mechanism 70 includes the power transmission device 72, thereby making it possible to prevent the tip of the medium P2 from moving and contacting the housing 60 and the like when the second feed tray 61 is installed to the housing 60.
The rotation mechanism 70 rotates the roll P2a so that the tip of the medium P2 when the second feed tray 61 is removed from the housing 60 is disposed below the upper end of the tip portion of the second feed tray 61 (the rear end portion in FIG. 5) when the second feed tray 61 is installed to the housing 60. Accordingly, when the second feed tray 61 is reinstalled to the housing 60, the tip of the medium P2 becomes more difficult to contact the housing 60 and the like.
While the illustrative embodiments of the present disclosure have been described above, the present invention is not limited to the illustrative embodiments, and various modifications can be made without departing from the scope of the claims. For example, the feed device 3 is an additional device installable to and removable from the printer main body 2, but may be integrated with the printer main body 2 and fixed thereto. The housing 11 and the first feed tray 15 of the printer main body 2 may be provided with the rotation mechanism similar to the rotation mechanism 70, and the feed device may be provided in the printer main body 2 itself. In this case as well, the same effect as that of the illustrative embodiments can be obtained.
While the rotation mechanism 70 includes the roller 71, the pinion gear 73, and the rack gear 74, the rotation mechanism 70 may have any configuration and is not particularly limited as long as it is possible to rotate the roll P2a so that the medium P2 is rerolled to the roll P2a when the second feed tray 61 moves forward from the state of being installed to the housing 60 and is removed therefrom. For example, when the second feed tray 61 moves forward, the outer peripheral surface of the roller that contacts below the outer peripheral surface P2a1 of the roll P2a contacts the housing 60, such that the roller may rotate to rotate the roll P2a. In this manner, it may not be required to include the pinion gear 73 and the rack gear 74.
The second feed tray 61 may not include the support base 61b. In this case, a shaft portion may be provided at the center of the roll P2a of the medium P2, and the shaft portion may be rotatably supported by the tray main body 61a. The support base 61b may be fixed to the tray main body 61a. The presser 61c may not be provided in the tray main body 61a. The presser 61c may be provided in the housing 60, and can obtain the same effect as described above.
The pinion gear 73 may have a diameter equal to or larger than that of the roller 71. In this case, the pinion gear 73 is desirably disposed at a position where the pinion gear 73 does not contact the roll P2a. The roller 71 may be located only at the contact position. In this case, it is desirable that the pinion gear 73 and the rack gear 74 are not engaged with each other in a state where the second feed tray 61 is fully installed to the housing 60. By doing so, even though the roll P2a and the roller 71 are in contact with each other, the roller 71 can be rotated by the rotation of the roll P2a, such that a conveyance load caused by the roller 71 can be prevented when the medium P2 is fed.
The rotation mechanism 70 may not include the power transmission device 72. In this case, the medium P2 is rolled up when the second feed tray 61 is removed from the housing 60 until the tip of the medium P2 contacts the housing 60 and the like. Accordingly, it is possible to prevent the tip of the medium P2 from contacting the housing 60 and the like when the second feed tray 61 is installed to the housing 60.
As long as the rotation mechanism 70 can rotate the roll P2a to roll back the medium P2 when the second feed tray 61 is removed from the housing 60, the tip of the medium P2 may be disposed slightly above the upper end of the tip portion of the second feed tray 61 when the second feed tray 61 is installed to the housing 60. In this case as well, when the second feed tray 61 is reinstalled to the housing 60, the tip of the medium P2 hardly contacts the housing 60 and the like, such that the tip thereof is hardly bent.
Hereinabove, the illustrative embodiments describe an example in which the present invention is applied to a printer that performs recording on the paper P, and are not limited thereto. The present invention can be applied to the entire feed device that rotatably accommodates the roll P2a of the medium P2.