The present application claims priority from Japanese patent application number 2011-034939, filed on Feb. 21, 2011, the entire contents of which are incorporated by reference herein.
1. Field of the Invention
The present invention relates to an image forming apparatus employing inkjet printing.
2. Description of the Related Art
As an image forming apparatus such as a printer, a facsimile machine, a copier, a plotter, and a multifunction apparatus combining several of the capabilities of the above devices, for example, an inkjet recording apparatus including an ink droplet discharge head to impact ink droplets and form images on a medium while conveying the medium by adhering the ink droplets to, for example, a sheet, is known.
Such an image forming apparatus employing the droplet discharge recording method includes a serial-type inkjet printer, which performs printing while scanning the print head by a carriage unit in a direction perpendicular to a sheet conveyance direction, i.e., in a main scanning direction. For a serial-type inkjet printer to perform printing properly, a device to detect a position of the carriage and its extent of movement is necessary. For example, JP-2006-187905A discloses a method using an elongated linear encoder scale in the carriage shifting direction.
However, disposing the linear encoder scale 7 near the carriage 1 causes a problem in that a user contacts the encoder scale inadvertently and possibly damages it, sheet powder from the paper medium attaches to the encoder scale to smear it, or ink mist as a by-product of the ink droplets is generated and the fine ink droplets coat the surface of the linear encoder scale. If the linear encoder scale 7 is damaged or smeared, the encoder sensor 8 cannot correctly count the scale marks and the position of the carriage 1 cannot be controlled correctly. Accordingly, the linear encoder scale has been designed to be replaceable.
The carriage 1 as illustrated in
As a countermeasure, a hole can be provided in a side surface of the carriage for preventing the linear encoder scale from detaching. The linear encoder scale is passed through both the detachment prevention hole and the slit of the encoder scale. With this structure, because the linear encoder scale is supported by an inner wall of the detachment prevention hole in the side surface of the carriage, the linear encoder scale does not easily detach from the encoder sensor.
However, because the linear encoder scale needs to be laterally inserted into the detachment prevention hole on the carriage side surface, the detachment prevention hole cannot be easily observed by human eyes and mounting the long encoder scale to the detachment prevention hole is difficult.
The present invention was created to solve the above problem and provides an image forming apparatus that facilitates mounting of the linear encoder scale.
The present invention provides an image forming apparatus including an openable through-hole forming member with respect to the carriage. Therefore, the section with concave-shaped cross-section of the encoder sensor if observed from the carriage moving direction can be exposed. With this structure, the through-hole forming member can be open with respect to the carriage and the linear encoder scale can be mounted to the encoder sensor through the open concave-shaped portion thus exposed, facilitating mounting the through-hole.
These and other objects, features, and advantages of the present invention will become more readily apparent upon consideration of the following description of the preferred embodiments of the present invention when taken in conjunction with the accompanying drawings.
Hereinafter, preferred embodiments of the present invention will now be described with reference to accompanying drawings.
In the present description, the medium may be referred to as “sheet” but not limited thereto, and includes a recorded medium, recording medium, transfer medium, recording sheet, and the like. The image forming apparatus means an apparatus to perform image formation by impacting ink droplets to various media such as paper, thread, fiber, fabric, leather, metals, plastics, glass, wood, ceramics, and the like. “Image formation” means not only forming images with text or graphics having meaning but also forming images without intrinsic meaning such as patterns (and simply impacting the droplets to the medium). Similarly, the term “ink” is not limited thereto but used as an inclusive term for every type of printable liquid, including DNA samples, registration and pattern materials, etc.
The print section 20 further includes a guide rod 4 installed at lateral side plates and configured to support the carriage 1 so that the carriage 1 slidably moves in the main scanning direction (which is a direction perpendicular to the conveyance direction of the sheet 10 in
The sub-tanks 12 of respective colors each are communicated with ink tanks 15 of respective colors via an ink supply tube 16 and are supplied with ink. The ink tanks 15 are replaceable. The carriage 1 slidably engages the guide rod 4 at a rear side of the carriage (downstream in the sheet conveyance direction). A main scanning motor 6 drives to rotate a drive pulley 18 and a driven pulley 19, and a timing belt 5 is stretched over the pulleys 18 and 19. The timing belt 5 is fixed to the carriage 1 so that the carriage 1 moves and scans in the main scanning direction.
To convey the sheet 10 placed in the sheet cassette 40 toward a position below the print head 2, the printer section 20 further includes a sheet feed roller 21 and a friction pad 22, both to separate and convey the sheet 10 from the sheet cassette 40 one by one, a guide member 23 to guide the sheet 10, a conveyance roller 24 to convey the sheet 10 while reversing it, another conveyance roller 25 to be pressed against a peripheral surface of the conveyance roller 24, and a front end roller 26 to define a conveyance angle of the sheet 10 from the conveyance roller 24. The conveyance roller 24 is driven to rotate by a sub scanning motor 27 via a gear train.
Further, a conveyance belt 9 corresponding to the moving range of the carriage 1 in the main scanning direction is disposed to guide the sheet 10 conveyed from the conveyance roller 24 at a side below the print head 2. The sheet 10 is charged by a charger 30. The conveyance belt 9 attracts the charged sheet 10 conveyed thereto and serves to remain the sheet surface to be in parallel with the print head. A sheet discharge roller 33 configured to send the sheet 10 to the sheet discharge tray 46 is disposed downstream of the sheet conveyance direction of the conveyance belt 9.
In addition, the printer body 100 may further include a sheet reverse unit 43 and a sheet feed unit 50 as options. The sheet reverse unit 43 includes a secondary conveyance roller 34 and a third conveyance roller 35. After the print head 2 forms images on the first surface of the sheet 10, the conveyance roller 24 is reversed so that the sheet 10 is pulled inside the printer body 100, the second conveyance roller 34 and the third conveyance roller 35 disposed inside the sheet reverse unit 43 convey the sheet 10 while reversing it to the conveyance roller 24. Then, the sheet 10 is conveyed below the print head 2 with its second surface faced toward the print head 2 and the print head 2 forms images on the second surface of the sheet 10. The sheet feed unit 50 includes a second sheet feed roller 36, a friction pad 37, a sending-out roller 38, and the like, and contains a lot of paper of the same or different size as the sheet feed cassette 40 contains. The paper can be selected from either the sheet feed cassette 40 or the sheet feed unit 50.
The carriage 1 includes a plurality of print heads 2 each configured to discharge ink droplets. The endless timing belt 5 is mounted on the carriage 1 and the timing belt 5 is rotatably driven by the main scanning motor 6, so that the carriage 1 moves along the guide rod 4 in the main scanning direction. At the same time, an encoder sensor 8 disposed at the carriage 1 reads the scale marks of the linear encoder scale 7 elongated in the carriage moving direction and disposed at least in the scanning range of the main scanning direction of the carriage 1 so that the scanned position of the carriage 1 can be detected. Then, each time the sheet 10 is conveyed by the conveyance belt 9 in the sub-scanning direction by a certain constant length, the carriage 1 is being scanned and the print head 2 discharges the ink to form an image on the sheet 10. The linear encoder scale 7 is disposed in the vicinity of the carriage 1 so that the encoder sensor 8 can read the scale marks on the scale 7. In addition, the linear encoder scale 7 is exposed along the range scanned by the carriage 1.
The encoder sensor 8 includes the slit 81 which is a groove to pass through the linear encoder scale 7. In the slit 81 are a light emitter and a light receiver each disposed on opposite surfaces inside the slit 8 with a predetermined distance therebetween. The linear encoder scale 7 is passed through between the light emitter and the light receiver, so that the encoder sensor 8 reads the scale marks on the linear encoder scale 7, thereby detecting a position of the carriage 1.
Although the linear encoder scale 7 is illustrated to have a certain thickness to facilitate understanding of the structure, the linear encoder scale 7 is in general formed of a transparent film member on which scale marks are printed. The encoder sensor 8 counts the scale marks on the linear encoder scale 7 by using non-transparent portions on which scale marks are printed and transparent portions on which scale marks are not printed.
As described above, the scale marks on the linear encoder scale 7 are read by the encoder sensor 8. The encoder sensor 8 includes the light emitter and the light receiver disposed with a certain distance therebetween, through which the linear encoder scale 7 is passed, thereby reading the scale marks. Specifically, the encoder sensor 8 has a concave-shaped cross-section with an upper open end if seen from the carriage moving direction. The concave-shaped portion is the slit 81 and the linear encoder scale 7 is passed through the slit 81. Accordingly, because the upper end of the slit 81 of the encoder sensor 8 is open, when the user inadvertently contacts the linear encoder scale 7, the linear encoder scale 81 detaches from the encoder sensor 8 through the opening of the slit 81. Accordingly, in the present embodiment, a hole for preventing the linear encoder scale 7 from coming off is provided on a side surface of the carriage 1. The linear encoder scale 7 is passed through both the detachment prevention hole and the slit 81 of the encoder scale 8. With this structure, because the linear encoder scale 7 is supported by an inner wall of the detachment prevention hole disposed on the carriage 1, the linear encoder scale 7 does not easily detach from the encoder sensor 8 even though the user mistakenly contacts the linear encoder scale 7.
In order to pass the linear encoder scale 7 through the slit 81 of the encoder sensor 8, the linear encoder scale 7 can be laterally inserted into the encoder sensor 8 from the carriage 1 disposed at a front as illustrated by an arrow A in
A detachment prevention hole 70 is a through-hole configured to extend in the carriage moving direction in which the linear encoder scale 7 passes through and to prevent the linear encoder scale 7 from detaching from the encoder sensor 8. In the present embodiment, a sensor cover 60 configured to cover the encoder sensor 8 and serving as a through-hole forming member along with the side surface of the carriage 1 is disposed as a detachment prevention hole 70. The sensor cover 60 is rotatable about a hinge 61 serving as a rotation shaft and is openable with respect to the carriage 1.
During the normal printing operation, as illustrated in
By contrast, when the linear encoder scale 7 is to be replaced, the sensor cover 60 is rotated counterclockwise to be open with respect to the carriage 1 as illustrated in
In this case, because mounting the linear encoder scale 7 to the encoder sensor 8 is easier from above the encoder sensor 8, the slit 81 of the encoder sensor 8 is preferably formed to be an upper open concave-shaped cross-section (upside open slit) if seen from the carriage moving direction.
The detachment prevention hole 70 is a through-hole configured to extend in the carriage moving direction in which the linear encoder scale 7 passes through and to prevent the linear encoder scale 7 from detaching from the encoder sensor 8. In the present embodiment, a sensor cover 62 configured to cover the encoder sensor 8 and serving as a through-hole forming member along with the side surface of the carriage 1 is detachably disposed to the carriage 1.
During the normal printing operation, the sensor cover 62 is attached to the carriage 1 as illustrated in
By contrast, when the linear encoder scale 7 is to be replaced, the sensor cover 62 is lifted upwards and is removed as illustrated in
In addition, because the sensor cover 62 is detachably attachable to the carriage 1, more freeness in accessing the detachment prevention hole 70 is achieved.
In general, a carriage cover is detachably attached to the carriage 1 for the replacement and maintenance of the parts inside the carriage 1. When a sensor cover 64 detachably disposed to the carriage 1 and configured to form the detachment prevention hole 70 of the linear encoder scale 7 along with the side wall of the carriage 1 as a through-hole forming member is concurrently used as a carriage cover, the number of parts or devices to detach and attach the cover can be decreased and the manufacturing cost can be reduced.
The user is not expected to uncover the carriage cover from its original purpose and the serviceperson uncovers it for the replacement of parts and maintenance services. Therefore, there is no problem in removing the carriage cover at the same time when the linear encoder scale 7 is replaced by the serviceperson.
Although the first embodiment shows a case in which the sensor cover is openable by rotating it about the rotating shaft, the sensor cover and the carriage cover can be commonly used in the first embodiment similarly to the second embodiment and the same effect can be obtained.
A board disposed on the carriage 1 and to which the encoder sensor 8 is fixed includes mostly a device to transmit a signal to the carriage 1. To facilitate maintenance of the board on which the encoder sensor 8 is fixed, a sensor cover 66 concurrently serving as a carriage cover is preferably removable from the carriage 1 so as to allow an access to the board as illustrated in
As aforementioned, the image forming apparatus according to the embodiment of the present invention includes: a print head 2 to form an image on a sheet of paper 10; a carriage 1 including the print head 2 and configured to scan in the main scanning direction; a linear encoder scale 7 with scale marks and elongated in the carriage moving direction to detect a position of the carriage 1; an encoder sensor 8 disposed on a side wall of the carriage 1 including a slit 81 with an upper open end having a concave-shaped cross-section if seen from the carriage moving direction, and the encoder sensor 8 configured to read the scale marks of the linear encoder scale 7 by passing the linear encoder scale 7 through the slit 81; and a sensor cover disposed on the side wall of the carriage 1, configured to cover the encoder sensor 8 and serving as a through-hole forming member to form a detachment prevention hole 70 being a through-hole extending in the carriage moving direction in which the linear encoder scale 7 is passed through. The sensor cover is disposed openable with respect to the carriage 1. As aforementioned, because the sensor cover is openable with respect to the carriage 1, when the sensor cover is open, the detachment prevention hole 70 is exposed and the concave-shaped open portion of the slit 81 of the encoder sensor 8 can be open and exposed. With this structure, the sensor cover is open with respect to the carriage 1 and the detachment prevention hole 70 is exposed, and the linear encoder scale 7 can be mounted to the encoder sensor 8 from the concave-shaped open portion exposed of the slit 81. With this structure, the workability can be improved compared to the case in which the linear encoder scale 7 is inserted into the slit 81 of the encoder sensor 8 by inserting the linear encoder scale 7 into the detachment prevention hole 70 from a lateral side of the carriage 1.
Further, according to the embodiment of the present invention, a hinge 61 serving as a rotation shaft to rotatably support the sensor cover with respect to the carriage 1 is provided so that the sensor cover 60 is rotatable about the hinge 61 to be open with respect to the carriage 1 and to expose the detachment prevention hole 70 to outside.
Further, according to the embodiment of the present invention, the sensor cover 62, 64, or 66 is detachably attached to the carriage 1. Therefore, without disposing a part such as a hinge, the sensor cover 62, 64, or 66 can de removed from the carriage 1 and the detachment prevention hole 70 can be exposed.
Furthermore, according to the embodiment of the present invention, the sensor cover 64 or 66 concurrently serves as a carriage cover to cover the inside the carriage. Thus, by integrally forming the sensor cover and the carriage cover, the number of parts and devices for attach- and detachment of the cover may be reduced, and the cost reduction can be achieved.
Further, the slit 81 of encoder sensor 8 has a concave-shaped cross-section with an upper open end if seen from the carriage moving direction. Because mounting the linear encoder scale 7 to the encoder sensor 8 is easier from above, the slit 81 of the encoder sensor 8 preferably has an upper open concave-shaped cross-section.
Additional modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the invention may be practiced other than as specifically described herein.
Number | Date | Country | Kind |
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2011-034939 | Feb 2011 | JP | national |
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Entry |
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Chinese official action dated Jan. 10, 2014 in corresponding Chinese patent application No. 2012 10 03 9651.2. |
Number | Date | Country | |
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20120212543 A1 | Aug 2012 | US |