The present invention relates to an image forming apparatus such as a printer, a facsimile apparatus, a copying machine, or a multifunction machine having all functions of the above apparatuses. More particularly, the present invention relates to an image forming apparatus which can adjust a gap between a face of a recording head and a sheet according to a thickness of the sheet, and can mount a recording head unit on a carriage with ease and accuracy. The present invention also relates to a computer program for controlling a print operation of the image forming apparatus.
Up to now, in some of image forming apparatuses such as a facsimile apparatus and a copying machine, a dot-like image is formed on a sheet by placing an ink ribbon on a surface of the sheet and striking the ink ribbon with dot pins of a recording head, or an image is formed on a sheet by discharging ink drops to the sheet from a nozzle of an ink jet head as in an ink jet type image forming apparatus. In these image forming apparatuses, since a gap between a face of a recording head and a sheet significantly affects print quality, there have been devised various image forming apparatuses each of which is provided with a mechanism capable of adjusting the gap between the face of the recording head and the sheet according to a thickness of the sheet.
For example, in JP 5-104817A, an image forming apparatus is disclosed in which: a carriage mounted with a dot pin type recording head is attached on a guide shaft positioned in parallel with a platen and laterally slidably; and an eccentric shaft decentered with respect to an axis of this guide shaft is pivoted by a contact and separation mechanism, thereby making it possible to adjust a distance (gap) between a head face of the recording head and a sheet.
In addition, in JP 11-348373A, an image forming apparatus is disclosed in which a gap adjustment member is positioned displaceably in a position opposed to an ink jet type recording head across a sheet conveying path.
With these image forming apparatuses, for example, an operator executes gap adjustment by selecting and inputting a sheet type to be used with an input unit of a computer or the like according to a thickness of a sheet on which an image is to be printed and actuating a drive motor of the contact and separation mechanism (gap adjustment member) in response to an input signal from the input unit, or the operator executes manual adjustment by actuating the contact and separation mechanism (gap adjustment member) with a manual lever. In the above-related arts, the carriage or the gap adjustment member is actuated such that the face of the recording head moves away from or close to the surface of the sheet in a parallel manner.
On the other hand, in image forming apparatuses disclosed in JP 8-300768A and JP 10-250184A, one end of a carriage mounted with a recording head is slidably and pivotably attached to a guide shaft with a round shaft shape, a lever provided on the other end side of the carriage is attached to a guide plate, which guides the other end side of the carriage, pivotably around a spindle, an eccentric cam is provided around the spindle, and a projection is provided in a hold portion of the lever. Further, the guide plate is nipped by the eccentric cam and the projection vertically. According to selection of a pivotal position of the lever, in a state in which the guide plate is nipped by a major diameter portion of the eccentric cam and the projection, a gap between a face of the recording head and a sheet is set to be large as the carriage pivots around the spindle. On the contrary, in a state in which the guide plate is nipped by a minor diameter of the eccentric cam and the projection, the gap is set to be small. The lever is manually operated by an operator.
However, in order to select and input a sheet type to be used with the input unit of the computer or the like to adjust a gap to a predetermined amount as described above, a complicated electric mechanism member is required. In addition, in the image forming apparatus in which the lever is operated manually, unless a user knows that the lever is manually operated, the user cannot perform gap adjustment and an image is formed with an inappropriate gap with respect to a thickness of a sheet, which provides inconveniences such as a waste of sheets and a waste of time.
In addition, in the case of the ink jet type image forming apparatus, there are provided a chip type in which a recording head is directly attached to a carriage which is reciprocatingly movable in a direction crossing a conveying direction of a recording medium, and another type in which a recording head unit is detachably mounted on a carriage and an ink cartridge (ink tank) is further detachably mounted thereon. In both the types, positioning of the recording head (recording head unit) to the carriage significantly affects print quality.
For example, in JP 2001-18416A, a carriage is provided with a receiving portion including four side plates and a bottom plate to provide upper open end, and a covering portion is provided on one side of the open end. While one end of the recording head unit is inserted below the covering portion, the other end thereof is pivoted downward to be dropped into the receiving portion, and the other end side of the recording head unit is pressed by a pressing lever provided in the other side plate of the carriage for positioning the recording head.
However, in the related art described in JP 2001-18416A, a nozzle portion in the recording head unit is faced with a nozzle placing portion which is constituted by the side plate having a cut away portion and vertically provided in a direction perpendicular to the pair of parallel side plates. Therefore, there is a problem in that a pressing force of the pressing lever does not act on the positioning of the nozzle portion at all and the recording head unit tends to be unsteady with respect to the receiving portion of the carriage and also tends to positionally deviate.
Besides, since the recording head unit is inserted obliquely downward with respect to the receiving portion as described above, there is also a problem in that mounting work thereof is not easy.
Moreover, as a flow of a basic operation of an ink jet printer of this type, first, after moving the carriage to a retract position at the time of sheet feeding, a sheet is fed so as to reach a position directly below a position to which the recording head is moved. Thereafter, movement of the carriage and conveyance of sheets are alternately performed according to a print command or a paper feed command. Thereafter, when the ink jet printer receives a paper supply command following the paper feed command without receiving the print command, after the carriage is moved to the retract position at the time of sheet feeding, feeding of a sheet is performed according to the paper feed command, and sheet discharge is performed such that the sheet is guided to a sheet discharge portion through the position directly below the position of the movement of the recording head. In addition, after printing of one page is finished, in order to detect ink empty, it is necessary to move the carriage to a position where an ink empty detection sensor is positioned. Alternatively, after printing of all pages is finished, it is necessary to move the carriage to a head protection position.
Consequently, in the above-mentioned image forming apparatus, many positioning operations are performed for moving and stopping the carriage, supplying and discharging sheets, and the like. Thus, there is a waste of movements in operations related to printing which are performed from supply to discharge of sheets, and speeding-up of printing cannot be realized easily.
For example, a reference for determination on stop of the carriage for reversing the carriage from deceleration to acceleration during printing is substantially fixed without any change from a reference for moving the carriage to a retract position at the time of sheet feeding and discharge, a head protection position, a flushing position, or the like to determine that the carriage stops. Thus, a time required for an entire reciprocal movement of the carriage is never shortened.
In addition, prior to discharge of a sheet according to a sheet discharge command, it is necessary to move the carriage to the retract position for sheet feeding or discharge. Thus, time is wasted by an amount of time required for moving the carriage from a print end position to the retract position at the time of sheet feeding and discharge, and sheet discharge cannot be performed promptly.
The present invention has been established in order to solve these problems, and it is an object of the present invention to provide an image forming apparatus which makes it possible to adjust a size of a gap between a recording head and a recording medium by a simple operation of only moving a carriage in a reciprocating scanning direction.
Another object of the present invention is to provide an image forming apparatus which can, with a simple structure, realize accurate positioning of a recording head unit to a carriage and make the recording head unit detachably attachable.
Still another object of the present invention is to provide an image forming apparatus which can perform high speed printing, and to provide a computer program for realizing operations of such an apparatus.
In order to attain the above-mentioned objects, the present invention provides an image forming apparatus which includes: a frame extending in a direction crossing a conveying direction of a recording medium; a guide shaft positioned in parallel with the frame; a carriage provided to reciprocate along the guide shaft and is mounted with a recording head; and a gap adjustment mechanism which adjusts a gap between the recording head and the recording medium. The gap adjustment mechanism is provided with abutment portions which come into slide contact with the frame and move in parallel with the frame together with the carriage. The abutment portions have different heights. The heights of the abutment portions are switched during the movement of the carriage to a predetermined position in one direction parallel with the frame and movement of the carriage to a predetermined position in the other direction. Accordingly, the gap between the recording head and the recording medium can be adjusted.
According to such a structure, since the abutment portion having a desired height is selected by moving the carriage to the predetermined positions laterally along the frame. Therefore, the abutment portion comes into slide contact with a slide contact portion of the frame, so that the gap between the recording head and the recording medium can be automatically changed. And a trouble can be eliminated for an operator to manually change the gap between the recording head and the recording medium every time an image is formed.
Here, in the gap adjustment mechanism, a switching portion for selecting and switching any one of the abutment portions, and pushing means for pushing and actuating the switching portion are further provided independently from the carriage. The pushing means pushes the switching portion during the movement of the carriage in one direction parallel with the frame and during the movement of the carriage in the other direction, so that any one of the abutment portions is selected and the gap between the recording head and the recording medium is adjusted.
According to such a structure, since the pushing means provided separately from the switching portion pushes the switching portion during the movement of the carriage, switching of the abutment portions is performed reliably, and timing for switching can be easily taken.
In addition, the pushing means include first pushing means for pushing the switching portion in one direction, and second pushing means for pushing the switching portion in the other direction. The first pushing means pushes the switching portion in one direction during the movement of the carriage in the direction parallel with the frame. The second pushing means pushes the switching portion in the other direction during the movement of the carriage in the other direction, so that any one of the abutment portions is selected, and the gap between the recording head and the recording medium can be adjusted.
Since the pushing means are provided in several forms including the first pushing means and the second pushing means in accordance with the lateral movements of the carriage, precise control becomes possible.
In addition, the pushing means are provided in the frame, the heights of the abutment portions are switched by the pushing means between the movement of the carriage in one direction and the movement thereof in the other direction. And the abutment portions with the different heights come into slide contact with the frame selectively, so that the gap between the recording head and the recording medium can be adjusted. Further, the pushing means are positioned at substantial terminal ends of the movement paths of the carriage in one direction and the other direction, respectively.
By providing the pushing means in the frame, the abutment portions provided in the carriage which comes into slide contact with the frame and laterally moves can be switched reliably. Accordingly, the structure can be simplified without providing a complicated pushing mechanism anew.
The present invention further provides an image forming apparatus which includes: a frame extending in a direction crossing a conveying direction of a recording medium, the frame being provided with a horizontal portion having a sliding surface; a guide shaft positioned in parallel with the horizontal portion of the frame; a carriage provided to reciprocate along the guide shaft and mounted with a recording head; and a switching block member provided in the carriage. The switching block member can be changed in posture between the movement of the carriage in one direction parallel with the horizontal portion of the frame and the movement of the carriage in the other direction. The switching block member is provided with several abutment portions with different heights which come into slide contact with the sliding surface of the frame according to the posture change. Pushing means is provided in the frame to switch the posture of the switching block member during the movement of the switching block member. The abutment portions with different heights selectively come into slide contact with the frame to adjust a gap between the recording head and the recording medium.
The switching block member provided with the plural abutment portions to come into slide contact with the frame is utilized as a switching mechanism of the abutment portion. Accordingly, it becomes possible to switch the abutment portions by simply pushing the switching block member with the pushing means. And the switching mechanism with a reduced space and a simple structure can be realized.
Here, it is preferable that the carriage is constituted pivotably about an axis of the guide shaft, and a portion where the abutment portions of the switching block member abut against a slide contact portion of the frame is positioned on the opposite side of the recording head across the guide shaft.
The slide contact portion of the switching block member with respect to the frame is positioned on the opposite side of the recording head across the guide shaft, so that it becomes possible to adjust the gap between the recording head and the recording medium simply through adjustment of the carriage to pivot around the guide shaft. The adjustment accuracy is improved.
In addition, it is preferable that the recording head is mounted on the carriage such that a print side thereof faces downward. A portion close to one side of a lower end of the carriage is slidably supported by the guide shaft. The frame has a vertical portion which extends in a vertical direction along a back of the carriage and is in a position higher than the guide shaft. The switching block member is positioned so as to face the sliding surface on the opposite side of the side, where the carriage is located, of the vertical portion of the frame, and is made pivotal with respect to the carriage via a horizontal axis perpendicular to a moving direction of the carriage and to the vertical portion of the frame.
The slide contact portion of the switching block member with respect to the frame is placed in an upper portion of an opposite surface of a surface, where the carriage is located, of the vertical portion of the frame on the back of the carriage. Accordingly, the existing frame can be utilized, and inspection and maintenance such as attachment. And replacement work of the switching block member can be performed easily.
In addition, biasing means for holding the posture changed at the time when the switching block member crosses a dead center of pivoting is connected to the switching block member.
When the biasing means crosses the dead center, since the switching block member can hold a posture, the switched abutment portion is never switched unnecessarily and is held reliably.
In addition, the pushing means are provided in positions where the pushing means can abut against the block member during the movement of the carriage in one direction and during the movement of the carriage in the other direction. Further, the pushing means includes first pushing means positioned on one end side of a moving range of the carriage for switching the plural abutment portions with different heights at the time of movement of the carriage to the one side. The pushing means has second pushing means positioned on the other end side of the moving range of the carriage for switching the plural abutment portions with different heights during the movement of the carriage to the other end side.
Since the switching block can engage with the frame to change its posture during the movement of the carriage, switching failure is less likely to occur.
The present invention further provides an image forming apparatus which includes: a frame extending in a direction crossing a conveying direction of a recording medium; a guide shaft positioned in parallel with the frame; a carriage provided to be reciprocatingly movable to the guide shaft and is mounted with a recording head; and a gap adjustment mechanism adjusting a gap between the recording head and the recording medium adjustable. The gap adjustment mechanism includes a first abutment portion adhered to the carriage, a second abutment portion which projects to or retracts in the carriage during the movement in one direction parallel with the frame and during the movement in the other direction. The second abutment portion has a height different from that of the first abutment portion. And pushing means performs switching between the projection and the retraction of the second abutment portion during the movement of the carriage in one direction and during the movement of the carriage in the other direction. During the movement of the carriage, the first or second abutment portion comes into slide contact with the frame selectively, so that the gap between the recording head and the recording medium can be adjusted.
According to such a structure, the first abutment portion is fixed to the carriage, the second abutment portion having a height different from that of the first abutment portion is caused to retract or project by the pushing means. And the first abutment portion or the second abutment portion selectively comes into slide contact with the frame. Therefore, the structure is simple, and it becomes possible to realize remarkable improvement of accuracy with which at least the first abutment portion comes into slide contact with the frame.
Here, the pushing means are preferably constituted by left and right side plates of the frame.
The left and right side plates of the image forming apparatus are utilized as the pushing means, so that new components and mechanisms are not required. Thus, it becomes possible to improve dimensional accuracy of the pushing means as well.
In addition, the carriage is provided pivotably around an axis of the guide shaft, and a portion where the first and second abutment portions with different heights selectively come into slide contact with the frame is positioned on the recording head side across the guide shaft.
The slide contact portion of these first and second abutment portions with respect to the frame is positioned on the recording head side across the guide shaft, so that it becomes possible to adjust the gap between the recording head and the recording medium simply through adjustment of the carriage to pivot about the guide shaft. And adjustment accuracy is improved.
In addition, the recording head is mounted on the carriage such that a print side thereof faces downward. A portion close to one side of a lower end of the carriage is slidably supported by the guide shaft. The frame has a vertical portion which extends in a vertical direction to above the carriage along a back of the carriage at a position higher than the guide shaft. An upper part of the vertical portion is bent vertically downward and a lower end of a bent portion is positioned to be adjacent to an upper surface of the carriage. The first and second abutment portions are positioned so as to slide facing a vertical surface of the bent portion of the frame, which is a surface on the opposite side of the side where the carriage is located.
Simply by bending the upper part of the frame on the back of the carriage and bringing an edge portion of the vertical surface of the frame close to the upper surface of the carriage from above the carriage, the existing frame can be utilized as a slide contact portion. The solid frame is utilized as the slide contact portion, so that adjustment accuracy can be improved.
In addition, the second abutment portion comes into slide contact with the frame when it projects. The first abutment portion comes into slide contact with the frame when the second abutment portion retracts.
The present invention further provides an image forming apparatus which includes: a frame extending in a direction crossing a conveying direction of a recording medium; a guide shaft positioned in parallel with the frame; a carriage provided to reciprocate along the guide shaft and mounted with a recording head; a switching portion provided in the carriage; and pushing means which are in an abutment relationship with the switching portion in relation to movement of the carriage. The switching portion including a first abutment portion which is adhered to the carriage and selectively comes into slide contact with the frame, and a movable second abutment portion which projects higher than the first abutment portion and is received lower than the first abutment portion. The pushing means including first pushing means which is positioned at substantial one terminal end of a moving range of the carriage in one direction, and causes the second abutment portion to retract by pushing the switching portion in one direction. The pushing means further includes second pushing means which is positioned at the substantial other terminal end of the moving range of the carriage in the other direction and causes the second abutment portion to project by pushing the switching portion in the other direction. The first abutment portion comes into slide contact with the frame in parallel thereto by moving the carriage to the substantial one terminal end to receive the second abutment portion. The second abutment portion comes into slide contact with the frame in parallel thereto by moving the carriage to the substantial other terminal end to cause the second abutment portion to project. Thus, a gap between the recording head and the recording medium can be adjusted.
In the above-mentioned structure, the pushing means are preferably positioned within the moving range of the carriage and outside a printable range.
In addition, it is preferable that the first pushing means changes the abutment portions with different heights so as to reduce the gap between the recording head and the recording medium. The second pushing means changes the abutment portions with different heights so as to increase the gap between the recording head and the recording medium.
The pushing means for switching projection and retraction of the second abutment portion are provided in the substantial terminal ends of the moving ranges in one direction and in the other direction of the carriage. The pushing means are positioned outside the print range, so that printing can be executed without the pushing means affecting a print operation.
In addition, it is preferable that the recording head is an ink jet head for discharging ink to perform recording. The recording head is provided with a cap mechanism for performing capping with respect to the recording head at substantially the same position as or on an outer side of a position where the second pushing means completes an operation at the time of movement of the carriage.
According to such a structure, the second abutment portion is retracted by the first pushing means of the pushing means. The first abutment portion comes into slide contact with the frame to reduce the gap between the recording head and the recording medium. The second abutment portion is projected by the second pushing means, and the second abutment portion comes into slide contact with the frame to adjust the gap between the recording head and the recording medium to be large. In this structure, a capping position is positioned at the same position as or on an outer side of the position where the second pushing means completes an operation. That is, the recording head is capped reliably in a state in which the gap between the recording head and the recording medium is large. Accordingly, it is unlikely that ink drops leaked from a nozzle portion of the recording head to the outside at the time of replacement of an ink cartridge are rubbed against a wall of the capping mechanism to soil the capping mechanism.
In addition, the first pushing means is positioned on an outer side of a printable range in reducing the gap between the recording head and the recording medium to perform a print operation. Alternatively, the first pushing means is positioned on an outer side of a printable range in reducing the gap between the recording head and the recording medium to perform a print operation and in an outside position at least of a portion which is required for accelerating or decelerating the carriage.
The first pushing means is positioned on an outer side of the print range in reducing the gap between the recording head and the recording medium to perform a print operation. Alternatively, the first pushing means is positioned more outside than a position made by adding the acceleration and deceleration portion of the carriage to the print range. Therefore, when the gap is reduced to perform a print operation, it becomes possible to perform a continuous print operation with high accuracy at a constant carriage speed while keeping a predetermined gap.
In addition, the recording head is an ink jet head for discharging ink to perform recording. A flushing mechanism for performing preliminary discharge at substantially the same position as or on an inner side of a position where the first pushing means completes an operation.
The second abutment portion is retracted by the first pushing means of the pushing means. The first abutment portion comes into slide contact with the frame to narrow the gap between the recording head and the recording medium. The second abutment portion is projected by the second pushing means. The second abutment portion comes into slide contact with the frame to widen the gap between the recording head and the recording medium. In this structure, since the flushing position is positioned at the same position as or on an inner side of the position where the first pushing means complete an operation, during printing in a state in which the gap is small, it becomes possible to perform flushing in the state of the gap.
In addition, the second pushing means is positioned on an outer side of a print range in increasing the gap between the recording head and the recording medium to perform a print operation. Alternatively, the second pushing means is positioned on an outer side of a print range in increasing the gap between the recording head and the recording medium to perform a print operation and in an outside position at least of a portion which is required for accelerating or decelerating the carriage.
The second pushing means is positioned on an outer side of the print range in increasing the gap between the recording head and the recording medium to perform a print operation. Alternatively, the second pushing means is positioned on an outer side of a position made by adding the acceleration and deceleration portion of the carriage to the print range. Therefore, when the gap is increased to perform a print operation, it becomes possible to perform a continuous print operation with high accuracy at a constant carriage speed while keeping a predetermined gap.
In addition, switching of the abutment portions with different heights by the pushing means is executed before a print operation on the recording medium is started based upon an instruction from a host computer connected to the image forming apparatus.
At this point, a changing operation of the abutment portions with different heights by the pushing means is executed so as to increase the gap based upon an instruction from the host computer indicating that an envelope has been selected as the recording medium. Alternatively, a changing operation of the abutment portions with different heights by the pushing means is executed so as to reduce the gap based upon an instruction from the host computer indicating that a plain paper has been selected as the recording medium.
When the host computer is used, since the switching of the abutment portions (gap between the recording head and the recording medium) by the pushing means is performed before a print operation is started according to an instruction of sheet type selection, it becomes possible to perform printing with a gap suitable for a sheet.
The present invention further provides an image forming apparatus which includes: a carriage reciprocates in a direction crossing a feeding direction of a recording medium; and a recording head unit which is detachably mounted to the carriage. In the carriage, portions being pressed are provided to project on both left and right sides of the recording head unit. An upward opening head receiving portion, which receives the recording head unit and has left and right side plates engaging with the portions to be pressed, is formed in the carriage. The left and right side plates are provided with elastic pressing members for pressing the portions to be pressed and locking portions for locking the elastic pressing members.
According to such a structure, the recording head unit can be easily attached to and detached from the upward opening head receiving portion. And the recording head unit can be pressed uniformly on the portions to be pressed on both the left and right sides thereof with the pair of left and right elastic pressing members from the carriage side.
Here, it is preferable that the head receiving portion of the carriage is provided with a bottom supporting portion and a back supporting portion, both of which respectively support a bottom and a back other than a nozzle portion of the recording head unit. The recording head unit is biased against the bottom supporting portion and the back supporting portion by the elastic pressing members.
According to such a structure, an upper space on the opposite side of the back can be secured wide, so that it becomes easy to insert/take out the recording head unit with respect to the head receiving portion. In addition, the recording head unit can be efficiently pressed only to the respective supporting portions of the bottom and the back of the carriage by the respective elastic pressing members. And positioning of the recording head unit with respect to the receiving portion of the carriage can be performed accurately.
In addition, it is preferable that the portions being pressed are pressed obliquely downward by the elastic pressing members, such that a pressing force of the elastic pressing members to the back supporting portion becomes larger than a pressing force thereof to the bottom supporting portion.
According to such a structure, it is unnecessary to increase strength (rigidity) of the bottom supporting portion compared with strength (rigidity) of the back supporting portion in the carriage, and the carriage never becomes bulky.
In addition, it is preferable that the elastic pressing members are constituted by wire springs. Ends of the wire springs are pivotably mounted on external surfaces of the left and right side plates of the carriage. And the locking portions include first locking portions provided on the external surfaces of the left and right side plates of the carriage for pressing and locking longitudinal middle portions of the wire springs obliquely downward, and second locking portions for locking free ends of the wire springs not to allow the free ends to be unlocked in an external direction of the side plates.
According to such a structure, since attaching and detaching operations of the wire springs can be performed outside the carriage, the operations can be performed easily. Further, a method of applying a load of a pressing force through the wire springs to the portions being pressed of the recording head unit is set in the first locking portions. Posture holding of the wire springs can be executed in the second locking portions. Accordingly, handling work of the wire springs becomes easy.
In addition, it is preferable that the recording head unit has an upward opening ink cartridge receiving portion for detachably receiving an ink cartridge. And the carriage is provided with a pressing lever for pressing the ink cartridge against the recording head unit.
According to such a structure, since the ink cartridge is pressed against the recording head unit through the pressing lever under a state in which the recording head unit is fixed to the carriage and does not deviate positionally, mounting work of respective components of the recording head unit and the ink cartridge can be performed reliably and easily.
In addition, it is preferable that a pressing force of the pressing lever is set such that the ink cartridge is directed toward a bottom of the recording head unit.
Consequently, adhesion of the recording head unit and the ink cartridge is improved, and leakage of ink from a connecting portion between both the members can be avoided.
The present invention further provides an image forming apparatus which includes: a carriage reciprocating substantially perpendicular to a feeding direction of a sheet; a recording head mounted on the carriage for performing printing on the sheet; reciprocating movement means which moves the carriage repeatedly and reciprocatingly by accelerating the carriage in one direction into a constant speed state, decelerating the carriage after the constant speed state of a short time, and decelerating the carriage after accelerating it in the opposite direction into the constant speed state again. First determining means determines that the carriage is stopped when decelerated to a speed equal to or lower than a first speed if the carriage moved by the reciprocating movement means stops at a predetermined position. Second determining means determines that the carriage is stopped when decelerated to a speed equal to or lower than a second speed higher than the first speed if the carriage moved by the reciprocating movement means performs printing.
According to such an image forming apparatus, criteria for determination on stop of the carriage reciprocatingly moving at the print time can be varied according to an operation state. When printing is performed, time required for the entire reciprocating movement is reduced by partially making the determination on stop earlier. And high-speed printing can be performed easily.
Here, it is preferable that an encoder for detecting a moving speed of the carriage is provided. And as to the carriage under deceleration, when a detection signal is not obtained from the encoder for a first time, the first determining means determines that the carriage has stopped at that point. When a detection signal is not obtained from the encoder for a second time shorter than the first time, the second determining means determines that the carriage has stopped at that point.
According to such an image forming apparatus, a stop determination point for determining that the carriage has stopped can be varied in terms of timing according to a detection signal from the encoder.
In addition, it is preferable that the recording head is an ink jet head according to an ink jet system. And the first determining means determines stop of the carriage according to the first speed at the time of movement to a head protection position, a retract position, or a flushing position.
According to such an image forming apparatus, unlike the case in which the carriage is moved to the head protection position, the retract position, and the flushing position, determination on stop of the carriage can be made earlier when the carriage is reciprocatingly moved for printing.
The present invention further provides an image forming apparatus which includes: a carriage reciprocating substantially perpendicular to a feeding direction of a sheet; a recording head mounted on the carriage for performing printing on the sheet; reciprocating movement means which reciprocates the carriage substantially perpendicular to the feeding direction of a sheet to apply printing to the sheet with the recording head, and on the other hand. When the carriage reverses for reciprocating movement, the apparatus performs feeding of the sheet in association therewith. And carriage movement control means controls movement of the carriage, in which the reciprocating movement means accelerates the carriage in one direction into a constant speed state, decelerates the carriage after it undergoes the constant speed state of a short time, and decelerates the carriage after it is accelerated in the opposite direction into the constant speed state again, thereby repeatedly reversing the carriage to move it reciprocatingly. When discharge of a sheet is performed, the apparatus retracts the carriage to the outside of a reciprocating movement portion of the carriage. The carriage movement control means brings the carriage into the constant speed state with the reciprocating movement means according to the print command, when it receives a sheet discharge command indicating that discharge of a sheet is to be performed together with a paper feed command indicating that feeding of a sheet is to be performed without any other print command following a print command indicating that printing is to be performed by the recording head. The carriage movement control means retracts the carriage to the outside of the reciprocating movement portion continuously with the reciprocating movement means according to the sheet discharge command immediately after the printing ends.
According to such an image forming apparatus, feeding of a sheet is never performed even if a paper feed command is received immediately before a sheet discharge command prior to discharge of the sheet according to the sheet discharge command, and the carriage is retracted to the outside of the reciprocating movement portion immediately after last printing. Therefore, sheet discharge can be performed promptly following a print operation according to a last print command. And high-speed printing can be performed easily.
The present invention further provides an image forming apparatus which includes: a carriage reciprocating substantially perpendicular to a feeding direction of a sheet; a recording head mounted on the carriage for performing printing on the sheet; a gap adjustment mechanism which automatically switches a gap between the sheet and the recording head at a gap switching position located outside a reciprocating movement portion of the carriage. Reciprocating movement means accelerates the carriage in one direction into a constant speed state, decelerates the carriage after the constant speed state of a short time, and decelerates the carriage after it is accelerated in the opposite direction into the constant speed state again, thereby repeatedly reversing the carriage to move it reciprocatingly. The reciprocating movement means moves the carriage to the gap switching position. Carriage movement control means moves the carriage to the gap switching position with the reciprocating movement means during feeding of a sheet.
According to such an image forming apparatus, in automatically switching a gap, since the carriage is moved to the gap switching position at the time of feeding a sheet, the sheet feeding is not delayed due to the gap switching. And high-speed printing can be performed easily.
The present invention further provides a computer program for controlling an image forming apparatus which reciprocatingly moves a carriage substantially perpendicular to a feeding direction of a sheet and performs printing to the sheet with a recording head mounted on the carriage. The computer program including: a reciprocating movement program for accelerating the carriage in one direction into a constant speed state, decelerating the carriage after the constant speed state of a short time, and decelerating the carriage after accelerating it in the opposite direction into the constant speed state again, so that the carriage can repeatedly reciprocates. A first determination program determines that the carriage is stopped when decelerated to a speed equal to or lower than a first speed, if the carriage moved based upon the reciprocating movement program is stopped at a predetermined position. A second determination program determines that the carriage is stopped when decelerated to a speed equal to or lower than a second speed higher than the first speed if the carriage is reciprocatingly moved based upon the reciprocating movement program to perform printing.
According to such a computer program, by operating a CPU based on the computer program, criteria for determination on stop of the carriage reciprocatingly moving at the print time can be varied according to an operation state. When printing is performed, time required for the entire reciprocating movement is reduced by partially making the determination on stop of the carriage earlier. And high-speed printing can be performed easily.
The present invention further provides a computer program for controlling an image forming apparatus which reciprocatingly moves a carriage substantially perpendicular to a feeding direction of a sheet to perform printing to the sheet with a recording head mounted on the carriage. When the carriage is reversed for reciprocating movement, the apparatus performs feeding of the sheet. The computer program including: a reciprocating movement program for accelerating the carriage in one direction into a constant speed state, decelerating the carriage after the constant speed state of a short time, and decelerating the carriage after accelerating it in the opposite direction into the constant speed state again, thereby repeatedly reciprocating the carriage. When discharge of a sheet is performed, the apparatus retracts the carriage to the outside of a reciprocating movement portion of the carriage. And a carriage movement control program brings the carriage into the constant speed state based upon the reciprocating movement program according to the print command, when a sheet discharge command indicating that discharge of a sheet is to be performed is received together with a paper feed command indicating that feeding of a sheet is to be performed without any other print command following a print command indicating that printing is to be performed by the recording head mounted on the carriage. The apparatus retracts the carriage to the outside of the reciprocating movement portion continuously based upon the reciprocating movement program according to the sheet discharge command immediately after the printing ends.
According to such a computer program, by operating the CPU based upon the computer program, feeding of a sheet is never performed even if a paper feed command is received immediately before a sheet discharge command prior to discharge of the sheet according to the sheet discharge command. The carriage is retracted to the outside of the reciprocating movement portion immediately after last printing. Therefore, sheet discharge can be performed promptly following a print operation according to a last print command. And high-speed printing can be performed easily.
The present invention further provides a computer program for controlling an image forming apparatus which reciprocatingly moves a carriage substantially perpendicular to a feeding direction of a sheet to perform printing to the sheet with a recording head mounted on the carriage. The apparatus is provided with a gap adjustment mechanism for automatically switching a gap between the sheet and the recording head. The computer program includes a reciprocating movement program for accelerating the carriage in one direction into a constant speed state, decelerating the carriage after the constant speed state of a short time, and decelerating the carriage after accelerating it in the opposite direction into the constant speed state again, thereby repeatedly reversing and reciprocating the carriage. The program moves the carriage to a switching position of the gap located outside a reciprocating movement portion of the carriage. A carriage movement control program moves the carriage to the switching position of the gap based upon the reciprocating movement program during feeding of a sheet.
According to such a computer program, by operating the CPU based upon the computer program, the carriage is moved to the switching position of the gap at the time of feeding of a sheet in order to automatically switch the gap. Therefore, sheet feeding is not delayed due to the switching of the gap. And high-speed printing can be performed easily.
Next, an image forming apparatus according to a first embodiment of the present invention will be described based upon
As shown in
In
Moreover, although not illustrated, a transmitter/receiver (handset) for performing conversation with other telephone sets is mounted on a cradle protrudingly provided outward so as to protrude from a side of the main lower case 1a. In addition, speakers for call-out and monitor are fixed to a rear side or the like of a right side in the main lower case 1a.
An ink jet printer is roughly divided into a mechanism for conveying a sheet (not shown) and a mechanism for performing printing on the sheet. The sheet conveying mechanism is constituted by the sheet supply tray 3 serving as a sheet set portion, a sheet supply roller 21, a sheet separation piece 120, a sheet sensor 80, a registration roller 22, conveying rollers 23 and 24, and a sheet discharge tray 26 which are positioned along a sheet conveying path, as well as a not-shown feed motor for driving the respective rollers 21, 22, and 23. The printing mechanism is constituted by a carriage 10 reciprocatingly moving substantially perpendicular to a feeding direction of a sheet, a recording head 15 provided below the carriage 10, a platen 25 positioned to be opposed to the recording head 15, a guide shaft 11 and a frame 12 which support the carriage 10, a linear encoder 82 and an encoder slit 83 for detecting a moving position of the carriage, as well as a DC motor for reciprocatingly moving the carriage 10, an ink tank mounted on the carriage 10, and the like, which are not illustrated.
On the sheet supply tray 3, a large number of sheets are stacked and are brought into a standby state for being fed in a posture in which a leading edge of each sheet abuts against the sheet separation piece 120. When the sheet supply roller 21 rotates in the clockwise direction, one sheet contacting the sheet supply roller 21 is separated from the sheet separation piece 120 and fed into the printer and a leading edge of the sheet abuts against the sheet sensor 80 before long, whereby a position of the sheet is detected. Then, when the sheet is fed by a predetermined amount, a leading edge of the sheet reaches the registration roller 22 and a direction of the sheet is adjusted. When the sheet further moves, it is brought into a state in which it is nipped between the registration roller 22 and the conveying roller 23, whereby the sheet supplying operation ends.
Thereafter, printing is performed on the sheet nipped by the registration roller 22 and the conveying roller 23 via the recording head 15. At the time of the print operation, the sheet is fed by a fixed width via the registration roller 22 and the conveying roller 23 every time printing of the fixed width is finished. When a trailing edge of the sheet reaches a predetermined position, a sheet discharge operation is started and the entire sheet finally reaches the sheet discharge tray 26 via the conveying roller 23, whereby the sheet discharge operation ends.
A lower rear end of the carriage 10 in the recording portion 2 is slidably and pivotably mounted on the guide shaft 11 of a round shaft shape on a surface (front) side of a lower part of the horizontally oblong frame 12 (
In the carriage 10, left and right side plates 32 (
On the other hand, the recording head unit 15 is a color ink jet recording head of a cartridge type and is detachably mounted downward to the carriage 10. The recording head 15 for executing color recording has four nozzle portions 15a for discharging inks of colors of cyan, yellow, magenta, and black on its lower surface side. Ink cartridges 16 for the respective colors in which inks to be supplied to the recording head 15 can be detachably mounted on an upper surface side of the recording head 15 as shown in
As shown in
On external surfaces of the left and right side plates 15c and 15c of the recording head unit 15, the engaging pins 34 and 34 (see
Moreover, abutment projections 46 and 46 projecting backward are formed in portions close to the upper end on both the left and right sides of the rear plate 15d (see
In order to accurately perform positioning and firmly fix the recording head unit 15 positioned in an upward opening head receiving portion D1 in the carriage 10, first, as shown in
On the other hand, the lower ends sides (free end sides) of the respective wire springs 36 are locked so as not to move upward by the first locking portions 37 which protrude outwardly from the side plates 32. Moreover, the free end sides of the respective wire springs 36 are prevented from coming off to the outside of the side plates 32 by second locking portion 39 of a hook shape formed obliquely downward.
If the wire springs 36 are locked in this way, as shown in
Consequently, a pressing force of the recording head unit 15 against the rear supporting portions 49 of the carriage 10 is made larger than its pressing force in the direction toward the bottom supporting portions 33 to ensure close attachment of the recording head unit 15 to the rear plate 31 with high rigidity in the carriage, and it is unnecessary to make the rigidity of the bottom supporting portions 33 large. Moreover, the recording head unit 15 can be mounted on the carriage 10 firmly so as not to wobble, and posturing and positioning of the recording head unit 15 become easy. Furthermore, since the head receiving portion D1 is opened largely with respect to the front side of the carriage 10 (and consequently the front side of the printer apparatus 1), attachment and detachment work of the recording head unit 15 from the front side of the printer apparatus 1 becomes extremely easy.
Next, a structure for attachment and detachment of the ink cartridges 16 will be described. As shown in
A pressing block 66 for pressing the upper surface in each ink cartridge 16 downward is mounted on a portion close to a free end on a lower surface of each pressing lever 17. The lower surface of the pressing lever 17 is formed with a downward C-shape recess in its cross-section, and the pressing block 66 is movable vertically and is unable to drop. Further, the pressing block 66 is biased downward via a biasing spring 67 positioned between a top board of the pressing lever 17 and the pressing block 66. Further, a pressing point of the ink cartridge 16 pressed by this pressing block 66, i.e., a position of the pressing force in the Y direction, is set to be in the vicinity of a manifold port 62 in the recording head unit 15. Consequently, in a fixed state in which the recording head unit 15 is pressed in the XY direction of the carriage 10 by the wire spring 36, since the recording head unit 15 does not shift in the XY direction any more, the ink cartridge 16 can be mounted firmly without applying a large load of external force to the bottom supporting portions 33 and 33 of the carriage 10 by pressing the recording head unit 15 downward in the Y direction with the pressing levers 17 via the ink cartridge 16.
Note that, since the pressing lever 17 is loosely fit with respect to the pivotably supporting shaft 63 via the mounting holes 64 which has a vertically oblong shape, when the upper portion on the opening end side of the pressing lever 17 is pushed downward, in a state in which the ink cartridge 16 is pressed by the pressing block 66 on the front side of the pressing lever 17, the base end side of the pressing lever 17 moves upward around the pressing point of the pressing block 66 with respect to the ink cartridge 16, and a vertical locking surface 68 of the pressing lever 17 locks a front end surface 69a in a top cover plate 69 of the carriage 10 and the posture of the pressing lever 17 is held (see
Note that, as shown in
As shown in
In
L1 represents a recordable (printable) range of a plain paper, on which characters or the like can be printed on plain paper. Note that a range of L2 including the recordable (printable) range L1 therein is a range of carriage return in the case of printing on plain paper and is located on the left side of the large gap switching position. In other words, the large gap switching position is in a position on the right side of the right end position of L2, And, the home position (capping position) is in a position on the further right side of the large gap switching position. On the other hand, the flushing position is at least in a position on the left side of the left end position of the recordable range L1, and the small gap switching position is in a position on the left side of the flushing position and on the left side of the left end position of L2. In addition, L3 represents a recordable range where printing is performed on a thick medium such as an envelope, which is narrower than the recordable range L1 for plain paper and is set on the inner side of L1. For printing, the carriage 10 is constituted to be reciprocatingly movable in a range of L4 made by adding the acceleration and deceleration portions (ΔL) to both left and right sides of L3, respectively.
An adjustment mechanism 30 of a gap between the face of the recording head 15 and the sheet P will be described based on
A bracket portion 40 facing rearward and downward is integrally formed on the upper end side of the rear plate 31 in the carriage 10 via a pair of left and right bracket coupling portions 40a. A switching block member 13 made of synthetic resin to be pivotably mounted on the bracket portion 40 is formed in a fan shape viewed from the front (viewed from the back) as shown in
On the front surface side of the switching block member 13, as shown in
On the other hand, the frame 12 has a horizontal rail portion 12b which is bent forward at a position higher than the slide contact portion 12a. A first pushing piece 56, which is cut and raised in a substantially vertical direction and serves as first pushing means for switching and guiding the lateral pivot posture of the switching block member 13, is provided in the vicinity of a left end of the horizontal rail portion 12b (left side of the flushing portion 29). A second pushing piece 57 having a chevron shape (reverse V shape) viewed from the front is provided as second pushing means in the vicinity of a right end of the horizontal rail portion 12b (in substantially a center in the lateral direction of the maintenance portion 27) (see
Next, the case in which printing is performed on plain paper by the printer apparatus 1 will be described. The carriage 10 located in the home position (cap position) 28 of
In this case, in
Subsequently, the carriage 10 is moved in a right direction (direction of arrow B) of
That is, in the case of performing printing on plain paper, it is necessary to move the carriage 10 in the range of L2 made by adding the acceleration and deceleration portions (ΔL) to both left and right sides of the recordable range L1 for plain paper, respectively. However, even when the carriage 10 moves to a right end position of L2, a gap is still kept small (the switching abutment portion 55 does not abut against the second pushing piece 57 of a chevron shape).
Therefore, a pushing operation by the second pushing piece 57 for increasing the gap is performed in a position on the further right side of the right end position of L2. Furthermore, the home position (capping position) 28 is in a position on the right side of the position where the pushing operation is performed. On the other hand, a flushing position is at least on the left side of the left end position of the recordable range L1. The pushing operation by the first pushing piece 56 for reducing the gap is set to be performed in a position on the further left side of the flushing position and on the left side of the left end position of L2. Thus, at least while the carriage 10 reciprocatingly moves within the range of L2, printing on plain paper is performed with the gap kept small. In addition, during the printing, for example, even when flushing is performed for every fixed time, the flushing operation is performed with the gap kept small.
In the case of performing printing on a thick envelope, unless the gap is increased, the envelope moving in a sheet conveying path is brought into contact with the nozzle portions 15a to soil a surface of the envelope with ink. Thus, the gap is adjusted to be wider (see
Therefore, since the first abutment portion 52 with a larger height on the front surface of the switching block member 13 on the upper side of the carriage 10 slides to the slide portion 12a on the back of the frame 12 extending vertically, the lower surface side of the carriage 10 is raised and caused to pivot upward about the guiding axis 11 (counterclockwise direction in
That is, in the case of performing printing on an envelope, the recordable range L3 for the envelope is narrower than the recordable range L1 for plain paper and is set on the inner side of L1. Thus, when the carriage 10 is moved in the range of L4 made by adding the acceleration and deceleration portions (ΔL) to both left and right sides of L3, respectively, even when the carriage 10 has moved to the left end position of L4, and, moreover, when the carriage 10 has moved to the flushing position, the gap is still kept large (the switching abutment portion 55 does not collide with the first pushing piece 56 standing substantially vertically).
Therefore, printing on the envelope is performed with the gap kept large at least while the carriage 10 reciprocatingly moves within the range of L4. In addition, during the printing, for example, even when flushing is performed for every fixed time, the flushing operation is performed with the gap kept large. Consequently, when the flushing is performed, it is unnecessary to idly move the carriage 10 to a position, where the switching abutment portion 55 abuts against the second pushing piece 57 of a chevron shape, each time the flushing is performed. Thus, a printing operation on the envelope can be carried out promptly.
Note that, when the carriage 10 moves to the home position 28, for example, even in a state in which the gap is switched to be small, since the gap dimension G1 is switched to be large in a position before the home position, the respective caps 28a are reliably capped keeping a predetermined correspondence relationship with respect to the nozzle portions 15a at the time of movement of the carriage 10 to the home position 28. In addition, a replacement position of the ink cartridge is set to a right side of a pushing position where the gap is switched to be small (position where the switching abutment portion 55 collides with the first pushing piece 56 extending substantially vertically), whereby an interference state can be prevented in which ink drops leaked to the outside from the nozzle portions 15a at the time of replacing the ink cartridge are rubbed against a wall of the maintenance portion 27.
Note that, as shown in
Moreover, in a state in which the carriage 10 is retracted to the home position 28, when the carriage 10 is subjected to an impulsive load causing the carriage 10 to move further in the right direction, for example, when the product is dropped by mistake when it is transported, intense collision of the carriage 10 against the regulating piece provided in the frame 12 can be eased by the projection 58, and damages to the switching block member 13 can be prevented.
The printer apparatus 1 as described above is provided with a usual function for, according to various instructions from an operation to be inputted in response to various key operations in the operation panel portion 6, executing setting of various processing operations, reading of an original image with the original reading unit 5, conversion of the original image into transmission data, conversion of the transmission data into a code, transmission and reception of facsimile data to be transmitted to another facsimile apparatus via communication network such as telephone lines, decoding of received data, and recording of the decoded facsimile data on a sheet P with a recording unit. In addition to this function, the printer apparatus 1 is also provided with a copy processing function for reading an original with a contact image sensor (CIS) of the original recording unit 5 and forming a color image on the sheet P with each unit of the recording portion, a printer processing function for receiving print data transmitted via a printer cable or wireless means such as infrared rays from an external apparatus such as a not-shown personal computer (host computer) and forming a color image on the sheet P according to the data, and a scanner processing function for transmitting image data read with the original reading unit 5 to the external apparatus.
The CPU 230 controls whole operations of the printer apparatus. The NCU 231 is connected to the public telephone lines to perform network control. The RAM 232 provides a work area for the CPU 230 and a development area of print data. The modem 233 performs modulation and demodulation of facsimile data. The ROM 234 has stored therein a program which the CPU 230 should execute. The NVRAM 235 stores data and various kinds of information. The gate array 236 functions as an interface between the CPU 230 and the recording portion 2, the reading portion 5, the operation portion 6a, and the display portion 6b. The codec 237 performs coding and decoding of data. The DMAC 238 mainly writes data in and reads it out from the RAM 232. The reading portion 5 reads an image from an original or the like according to control of the CPU 230. The recording portion 2 performs aforementioned various operations according to control of the CPU 230. In addition, according to an operation of the operation portion 6a, an input signal from a user is transmitted to the CPU 230 and different kinds of information is displayed on the display portion 6b.
The CPU 230 realizes: reciprocating movement means which makes the carriage 10 repeatedly and reciprocatingly movable by accelerating the carriage 10 in one direction to bring it into a constant speed state, decelerating the carriage after making it undergo the constant speed state for a short time, and decelerating the carriage after accelerating it in the opposite direction to bring it into the constant speed state again; first determining means which, in stopping in a predetermined position the carriage 10 reciprocatingly moved by the reciprocating movement means, determines that the carriage is stopped when it is decelerated to a speed equal to or lower than a first speed; and second determining means which, when the carriage 10 is reciprocatingly moved by the reciprocating movement means to perform printing, determines that the carriage is stopped when decelerated to a speed equal to or lower than a second speed higher than the first speed.
The CPU 230 further realizes: reciprocating movement means which, when discharge of a sheet is performed, retracts the carriage 10 to the outside of a reciprocating movement portion of the carriage 10; and carriage movement control means which brings the carriage 10 into the constant speed state with the reciprocating movement means according to the print command when it receives a sheet discharge command indicating that discharge of a sheet is to be performed together with a paper feed command indicating that feeding of a sheet is to be performed without any other print command following a print command indicating that printing is to be performed by the recording head mounted on the carriage 10. The carriage movement control means retracts the carriage 10 to the outside of the reciprocating movement portion continuously with the reciprocating movement means according to the sheet discharge command immediately after the printing ends.
The CPU 230 further realizes: reciprocating movement means which moves the carriage 10 to a gap switching position located outside a reciprocating movement portion of the carriage 10; and carriage movement control means which moves the carriage 10 to the gap switching position during feeding of a sheet P.
On the other hand, there is a computer program, which is stored in the ROM 234, for executing control for reciprocatingly moving a carriage 10 substantially perpendicular to a feeding direction of a sheet to apply printing to the sheet with a recording head 15 mounted on the carriage 10. The computer program includes: a reciprocating movement program for accelerating the carriage 10 in one direction to bring it into a constant speed state, decelerating the carriage after making it undergo the constant speed state for a short time, and decelerating the carriage after accelerating it in the opposite direction to bring it into the constant speed state again, thereby making the carriage repeatedly and reciprocatingly movable; a first determination program for, in stopping the carriage reciprocatingly moved based upon the reciprocating movement program, determining that the carriage is stopped when decelerated to a speed equal to or lower than a first speed; and a second determination program for, when the carriage is reciprocatingly moved based upon the reciprocating movement program to perform printing, determining that the carriage is stopped when decelerated to a speed equal to or lower than a second speed higher than the first speed.
Further, there is a computer program, which is stored in the ROM 234, for controlling, when the carriage 10 reverses for reciprocating movement, feeding of a sheet P in association therewith. The computer program includes: a reciprocating movement program for accelerating the carriage 10 in one direction to bring it into a constant speed state, decelerating the carriage 10 after making it undergo the constant speed state for a short time, and decelerating the carriage 10 after accelerating it in the opposite direction to bring it into the constant speed state again, thereby repeatedly reversing the carriage 10 to move it reciprocatingly, and on the other hand, when discharge of a sheet P is performed, retracting the carriage 10 to the outside of a reciprocating movement portion of the carriage 10; and a carriage movement control program for, when a sheet discharge command to the effect that discharge of the sheet P is to be performed is received together with a paper feed command to the effect that feeding of the sheet P is to be performed without any other print command following a print command to the effect that printing is to be performed by the recording head 21 mounted on the carriage 10, bringing the carriage 10 into the constant speed state based upon the reciprocating movement program according the print command, and on the other hand, immediately after the printing ends, retracting the carriage 10 to the outside of the reciprocating movement portion continuously based upon the reciprocating movement program according to the sheet discharge command.
Further, there is a computer program, which is stored in the ROM 234, for executing control for automatically switching a gap between the sheet P and the recording head 15. The computer program includes: a reciprocating movement program for accelerating the carriage 10 in one direction to bring it into a constant speed state, decelerating the carriage 10 after making it undergo the constant speed state for a short time, and decelerating the carriage 10 after accelerating it in the opposite direction to bring it into the constant speed state again, thereby repeatedly reversing the carriage 10 to move it reciprocatingly, and on the other hand, moving the carriage 10 to a switching position of the gap located outside a reciprocating movement portion of the carriage 10; and a carriage movement control program for moving the carriage 10 to the switching position of the gap based upon the reciprocating movement program during feeding of the sheet P.
Next, operations will be described based upon
In starting print processing, first, the CPU 230 causes the carriage 10 to move from the head protection position to the retract position at sheet feeding time (S1).
In addition, during the movement of the carriage 10, the CPU 230 starts sheet feed (S2). Consequently, the sheet P is fed into the inside via the sheet supply roller 21.
Simultaneously with feeding the sheet P in this way, the CPU 230 monitors the movement of the carriage 10 according to whether or not an output interval of encoder signals from the linear encoder 82 has exceeded, for example, 100 ms (S3).
When it is determined that the output interval of encoder signals has exceeded 100 ms and the carriage 10 has stopped (S3: YES), the CPU 230 causes the carriage 10 to move to the flushing position in order to perform flushing of ink (S4). Then, when it is determined that the output interval of encoder signals has exceeded 100 ms and the carriage 10 has stopped (S5: YES), the CPU 230 issues an instruction for performing a flushing operation (S6). Thereafter, if the apparatus is not set in a print mode for thick paper for printing on an envelope or the like (S7: NO), the CPU 230 causes the carriage 10 to move to the gap switching position (S8). Note that, such a switching operation of a gap is performed by the time when the sheet P being conveyed reaches the registration roller 22 such that the recording head 15 of the moving carriage 10 is not brought into contact with the sheet P. Note that, although the operation of S8 is effective when printing is performed on plain paper with the printer apparatus set in the thick paper mode at first, the carriage 10 is kept in a state in which it is stopped in the retract position at sheet feeding time when it is unnecessary to switch a gap.
Thereafter, when the CPU 230 determines that the output interval of encoder signals has exceeded 100 ms and the carriage 10 has stopped (S9: YES), and detects a leading edge position of the sheet P by the sheet sensor 80, and the leading edge of the sheet P is then sent out from the registration roller 22 by a predetermined amount, and the CPU 230 ends the sheet feed accordingly (S10).
Then, after controlling the DC motor to accelerate the carriage 10 to a certain speed, the CPU 230 causes the carriage 10 to move at a constant speed along one direction (forward path). The CPU 230 controls the recording head 15 while the carriage 10 is moving at the constant speed, so that printing is performed (S11). That is, while the carriage 10 is moving on the sheet P at the constant speed, ink is injected from the nozzle arrays 15A and 15B of the recording head 15 and deposits on the sheet P with a fixed width, so that printing is performed.
When the printing in one direction is finished, the CPU 230 controls the DC motor to decelerate the carriage 10 (S13) while performing feeding of the sheet P (S12).
Moreover, during the deceleration of the carriage 10, the CPU 230 monitors whether or not the output interval of encoder signals from the linear encoder 82 has exceeded, for example, 5 ms (S14).
When the output interval of encoder signals has exceeded 5 ms (S14: YES), the CPU 230 determines that the carriage 10 has stopped and executes printing of the next line when the feeding of the sheet P ends. Note that, considering the determination time in the order of 5 ms, the carriage 10 cannot be in a completely stopped state but may be slightly moving. In addition, when the feeding of the sheet P ends during the deceleration of the carriage 10, since the printing of the next line is started immediately, a slight load is applied to the DC motor when the carriage 10 is accelerated in the opposite direction in such a state. However, since the carriage 10 starts to accelerate in the opposite direction in the middle of the predetermined acceleration and deceleration portion, a reverse operation of the carriage 10 is performed promptly.
The CPU 230, which controls two-way printing as described above, is constituted so as to perform the two-way printing for each print command while sequentially receiving print commands and storing them. Such a CPU 230 determines whether or not a sheet discharge command has been received together with a last print command (S20). Note that, after the last print command, the sheet discharge command may be issued for processing subsequent to a paper feed command.
When the sheet discharge command has been received together with the last print command (S20: YES), after accelerating the carriage 10 to a certain speed according to the last print command, the CPU 230 performs printing of a last line by controlling the recording head 15 while the carriage 10 is moving at the constant speed (S21).
Thereafter, upon finishing the printing of the last line, the CPU 230 causes the carriage 10 to move to the retract position at sheet discharge time without stopping the carriage 10 once in the acceleration and deceleration portion according to the sheet discharge command (S23). That is, when the paper feed command is caused to wait for processing before the sheet discharge command, the CPU 230 neglects this paper feed command to cause the carriage 10 to move to the retract position at sheet discharge time immediately after the printing of the last line. When the CPU 230 determines that the output interval of encoder signals has exceeded 100 ms and the carriage 10 has stopped (S24: YES), the sheet P is thus discharged promptly without a wasteful feeding operation of the sheet P (S25).
Thereafter, the CPU 230 causes the carriage 10 to move to the initial head protection position (S26). When the CPU 230 determines that the output interval of encoder signals has exceeded 100 ms and the carriage 10 has stopped (S27: YES), the CPU 230 ends this print processing.
When it is determined in S27 that the output interval of encoder signals has not exceeded 100 ms and the carriage 10 is moving (S27: NO), the CPU 230 stands by for the next processing until it determines that the carriage 10 comes into a stopped state.
When it is determined in S24 that the output interval of encoder signals has not exceeded 100 ms and the carriage 10 is moving (S24: NO), the CPU 230 stands by for the next processing until it determines that the carriage 10 comes into a stopped state.
When the last print command and the sheet discharge command have not been received in S20 (S20: NO), the CPU 230 returns to S11 to continue the two-way printing.
In S14, when the carriage 10 is moving in deceleration even in the time interval set to 5 ms during the two-way printing (S14: NO), the CPU 230 stands by for execution of the next operation until the carriage 10 comes into the stopped state.
When it is determined in S9 that the output interval of encoder signals has not exceeded 100 ms and the carriage 10 is moving (S9: NO), the CPU 30 stands by for the next processing until it determines that the carriage 10 comes into a stopped state.
In S7, when the printer apparatus is set in the thick paper mode from the beginning and it is unnecessary to switch the mode in S7 (S7: NO), the CPU 230 proceeds to S10.
When it is determined in S5 that the output interval of encoder signals has not exceeded 100 ms and the carriage 10 is moving (S5: NO), the CPU 230 stands by for the next processing until it determines that the carriage 10 comes into a stopped state.
When it is determined in S3 that the output interval of encoder signals has not exceeded 100 ms and the carriage 10 is moving (S3: NO), the CPU 230 stands by for the next processing until it determines that the carriage 10 comes into a stopped state.
Therefore, according to the multifunction facsimile and printer apparatus which is provided with the above-mentioned ink jet printer, a reference for determination for stopping the carriage 10 in the head protection position, the retract position, or the gap switching position (in the above-mentioned example, the time interval of 100 ms during which the movement of the carriage 10 is detected based upon the encoder signals) and a reference for determining that the carriage 10 is in the stopped state when the carriage 10 in the middle of printing is reversed (in the above-mentioned example, the time interval of 5 ms during which the movement of the carriage 10 is detected based upon the encoder signals) are different therebetween. That is, when printing is performed, determination on stop as timing for reversing the carriage 10 is set earlier than timing in causing the carriage 10 to move to each predetermined position to stop there. Consequently, time required for the entire reciprocating movement of the carriage 10 at the printing time is reduced and speeding-up can be realized easily.
In addition, prior to the discharge of the sheet P according to the sheet discharge command, feeding of the sheet P is never performed even if there is the paper feed command received immediately before receiving the sheet discharge command, and the carriage 10 moves to the retract position at sheet discharge time immediately after the last printing. Thus, the sheet discharge can be performed promptly following the print operation according to the last print command and speeding-up can be realized easily.
Moreover, simultaneously with the feeding of the sheet P, the carriage 10 moves to the gap switching position, whereby the gap is automatically switched. Thus, sheet feed is not delayed due to switching of the gap, and speeding-up can be realized easily.
The gap dimension G1 is switched to two types, a small one and a large one in the above-mentioned first embodiment, switching to three types if gaps can be executed in a gap adjustment mechanism 30a according to this embodiment. As shown in
In that case, only the second highest abutment portion 59b abuts against the slide contact portion 12a of the frame 12 when the switching abutment portion 55 is selected to be in a state in which it has passed over the lower pushing piece 61a but has not passed over the higher pushing piece 61b. Only the highest third abutment portion 59c abuts against the slide contact portion 12a of the frame 12 when the switching abutment portion 55 passes over the higher pushing piece 61b. Accordingly, the carriage 10 pivots around the guide shaft 11 and the cap dimension G1 can be switched to one of three types of small, medium, and large.
In the gap adjustment mechanisms 30 and 30a according to the first and second embodiments, the abutment portions with different heights of the switching block member 13 are switched to perform size adjustment of the gap by utilizing the first pushing piece 56 and the second pushing piece 57 provided in the frame 12, respectively, according to the reciprocating lateral movement of the carriage 10. The third embodiment relates to a gap adjustment mechanism which is capable of increasing accuracy of gap formation while further miniaturizing and simplifying a structure for adjustment of the gap.
An upper perspective view of a carriage 10b in accordance with this embodiment is shown in
As shown in
Next, details of the actuator portion 102 will be described based upon
When the pushing means pushing down the second projected portion 105 moves the switching lever 103 in a C direction shown in the figure (
On the other hand, when the pushing means pushing down the first projected portion 104 moves the switching lever 103 in a D direction shown in
In addition, the first abutment portion 101 having the first abutment surface 100 shown in
Subsequently, an action of gap adjustment according to cooperation of the gap adjustment mechanism 30b, which is composed of the first abutment portion 101 and the actuator portion 102, and the frame 12 will be described.
That is, since the above state is the same as the state shown in
Note that, when the guide shaft 11 to be a pivotal center of the carriage 10b displaces to the front side (right side in the figure) of the position of the center of gravity of the carriage 10b depending upon a structure of the carriage 10b, it is possible to obtain the same effect even if the first abutment portion 101 and the second abutment portions 109 and 111 are constituted so as to abut against the front surface (right side in the figure) or the upper surface of the frame 12. Various layouts are possible for positions of the abutment portions and the abutment surface (horizontal rail portion) taking into account a piercing position of the guide shaft with respect to the carriage and the center of gravity of the carriage.
As to the printer apparatus according to the above-mentioned structure, an operation for adjusting a gap between the recording head 1 and the upper surface of the platen 25 (which is a surface and a passing route of the sheet P as a recording medium) will be described. For example, when the above-mentioned printer processing function is executed, printer driver software installed in an external apparatus such as a personal computer is started up. Then, a type of a recording medium on which printing (recording) is to be performed (sheet P) is selected. At this time, it is assumed that the gap can be set small if plain paper (e.g., a letter sheet and an A4 sheet) is selected and the gap can be set large if an envelope is selected.
First, the case in which printing is performed on plain paper will be described.
Subsequently, the carriage 10b is moved in a direction of arrow B, and characters can be printed on plain paper within the recordable (printable) range of L1. Note that the range of L2 including the recordable (printable) range L1 is a range of carriage return in the case of printing on plain paper and is located on the left side of a position for performing switching to increase a gap to be described later.
That is, when printing is performed on plain paper, it is necessary to move the carriage 10b in the range of L2 made by adding the acceleration and deceleration portions (ΔL) to both left and right sides of the recordable range L1 for plain paper, respectively. However, even when the carriage 10 moves to a right end position of L2, a gap is still kept small (the second projected portion 105 of the switching lever 103 does not abut against a right side plate 12f).
Therefore, a pushing operation by the right side plate 12f (side frame) serving as second pushing means for increasing a gap is performed in a position on a right side of the right end position of L2. A home position (capping position) 28 is located in substantially the same position as the position where pushing operation is performed. On the other hand, the flushing position is located at least on the left side of the left end position of the recordable range L1, and the pushing operation by the first pushing means for decreasing a gap is set to be performed in a position on the left side of the flushing position and on the left side of the left end position of L2. Thus, at least while the carriage 10b is reciprocatingly moving within the range of L2, printing on plain paper is performed with the gap kept small. In addition, during the printing, for example, when flushing is performed for every fixed time, a flushing operation is performed with the gap kept small as described above.
When printing is performed on a thick envelope, unless a gap is increased, the envelope moving on a sheet conveying path is brought into contact with the nozzle portions 15a to soil a surface of the envelope. Thus, as described above, the gap is changed and adjusted to be large. In this case, for example, if the previous print operation is printing on plain paper, when the carriage 10b is moved in the direction of arrow B in an attempt to retract the carriage 10 toward the home position (cap position) 28 after the printing ends, the second projected portion 105 formed at the right end of the switching lever 103 of the actuator portion 102 is pushed to the left direction in the figure by the right side plate 12f serving as the second pushing means.
Therefore, the actuator portion 102 changes to the state described based on
That is, in the case of performing printing on an envelope, the recordable range L3 for the envelope is narrower than the recordable range L1 for plain paper and is set to be on the inner side of L1. When the carriage 10b is moved in the range of L4 made by adding the acceleration and deceleration portions (ΔL) to both left and right sides of L3, respectively, and the carriage 10b has moved to the left end position of L4, and, moreover, even when the carriage 10b has moved to the flushing position, the gap is still kept large (the first projected portion 104 of the switching lever 103 does not abut against the left side plate 12e).
Therefore, printing on the envelope is performed with the gap kept large at least while the carriage 10b reciprocatingly moves within the range of L4. In addition, during the printing, for example, even when flushing is performed for every fixed time, the flushing operation is performed with the gap kept large. Consequently, when the flushing is performed, it is unnecessary to idly move the carriage 10b to a position, where the first projected portion 104 of the actuator portion 102 abuts against the left side plate 12e to be switched, each time the flushing is performed, so that a printing operation on the envelope can be carried out promptly.
Note that, when the carriage 10 moves to the home position 28, for example, even in a state in which the gap is switched to be small, the switching lever 103 is pushed by the right side plate 12f serving as the second pushing means from a position before the home position. The gap dimension G1 is switched to be large at substantially the same position as the home position.
Next, a structure by which the gap dimension G1 of the third embodiment is switched to, for example, three types will be described. As shown in
In addition, as illustrated, a pushing portion of the right side plate 12f for pushing the switching lever 143 of the lower actuator portion 142a is constituted by a pushing plate 130, a slide pin 132, and a compression coil sprint 131. The pushing plate 130 is made laterally movable on the figure with the slide pin 132 fixed to the right side plate 12f as a reciprocating slide shaft. Thus, when a force for pushing the pushing plate 130 from the left of the figure does not work, the compression coil spring 131 is in a state in which it is extended by an elastic force of the compression coil sprint 131 as shown in
Now, a state is assumed in which the gap between the recording head and the recording medium is adjusted to small. That is, it is assumed that first abutment portions 149 and 151 of the lower actuator portion 142a are retracted, third abutment portions 149b and 151b of the upper actuator portion 142b are retracted, and the first abutment portion 101 (see
When the not-shown carriage 10b continues to move in the B direction from the above-mentioned state of
The multifunction facsimile and printer apparatus according to the present is not limited to the above-mentioned embodiments, and various modifications and improvements are possible within a scope defined in claims. For example, in the above-mentioned embodiments, when printing is performed on plain paper, the carriages 10 and 10b are moved in the range of L2 found by adding the acceleration and deceleration portions (ΔL) to both left and right sides of the recordable range L1 for plain paper, respectively. In addition, when printing is performed on an envelope, the carriage 10 is moved in the range of L4 made by adding the acceleration and deceleration portions (ΔL) to both left and right sides of the recordable range L3 for an envelope, respectively. Thus, there is an advantage that a speed of the carriage 10 in performing an ink discharge operation becomes substantially constant and timing control of ink discharge becomes easy.
However, the present invention is not limited to the above embodiments. For example, when discharge timing of ink is controlled so as to discharge ink even during the acceleration of a carriage, the second pushing piece 57 can be positioned at least on the outer side (right side in
Likewise, when discharge timing of ink is controlled such that ink discharge is possible even during the acceleration of a carriage, a point where the switching lever 102 is switched to make a gap large can be positioned at least on the outer side (right side in
In addition, in the gap adjustment mechanisms in the first and second embodiments, instead of arranging the frame 12 uprightly, the frame 12 may be extended substantially linearly to the opposite side of the nozzle portions 15a across the guide shaft 11. The switching bock member 13 may be provided pivotably on the lower surface side of the carriage 10 such that one of several abutment portions with different heights is selected and come into slide contact (abutment) with the slide contact portion 12a at an end of the frame 12. The present invention can be applied not only to the above-mentioned printer apparatus but also a copying machine and an image scanner of a carriage mount type.
In the third embodiment, the left side plate 12e and the right side plate 12f are utilized as the first and second pushing means, respectively. Depending upon a structure of the printer apparatus 1, it is also possible to provide an extension portion extending to a front side from both side edges of a vertical portion of the frame 12 or provide an extension portion extending downward from both side of a horizontal portion located above the frame 12, thereby using this extension portion as the first and second pushing means.
Further, in the series of procedures in the above-mentioned embodiments, timing at which the carriage 10 makes a complete change from deceleration to acceleration is set to be different at the left and right ends of the reciprocating movement portion in the case of the two-way printing. Such timing may be set to be different in the case of a one-way printing. In addition, the stop determination of 100 ms is also applied to the movement to the flushing position for preventing ink clogging periodically during page printing.
The present invention can be applied not only to the above-mentioned multifunction facsimile/printer apparatus but also to a copying machine, an image scanner of a carriage mounted type, an ink jet printer as a unit, and a serial printer of a dot impact system. The present invention is technically useful.
Number | Date | Country | Kind |
---|---|---|---|
2001-251633 | Aug 2001 | JP | national |
2001-251635 | Aug 2001 | JP | national |
2001-259701 | Aug 2001 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP02/08483 | 8/22/2002 | WO | 00 | 5/19/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/018322 | 3/6/2003 | WO | A |
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Number | Date | Country | |
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20040246284 A1 | Dec 2004 | US |