1. Field of the Invention
The present invention relates to a maintenance mechanism for cleaning and protecting a print head of a printing machine of the ink jet printing system wherein printing is performed by jetting ink droplets onto a receiving medium.
2. Description of the Related Art
Ink-jet printing machines generally have three modes of operations which include a printing operation for printing on a receiving medium, a capping operation for protecting a print head and preventing nozzles from drying, and a wiping operation for cleaning by wiping surfaces of the nozzles of the print head.
According to the conventional example mentioned above, a main body of the printing machine requires a further widthwise (the primary scanning direction) increase of space, such that the slide case 6 may be allowed to move a distance L2 from the one end of the primary scanning movement relative to the main frame 1 thereby permitting a sequence of oblique sliding movements of the maintenance mechanism. Specifically, the space represented by L2 in the figure is required to permit the slide case 6 to move up and down or to permit the sliding projections C in loose fit with the cam grooves B to slidably move in conjunction with the movement of the carriage 2. This requires the further widthwise increase of space of the printing machine, which results in an increased widthwise dimension of the machine.
As a solution to this problem, for example, Japanese Unexamined Patent Publication JP-A 2000-203042 (2000) discloses an arrangement wherein a maintenance station is disposed within the printing region. In this case, a motor conventionally provided for driving a sheet feed roller or feed roller is utilized for driving the maintenance station. However, such an arrangement encounters a complicated structure of a drive force transmission mechanism and an increased number of components thereof. Consequently, a driving system has a complicated structure of a complicated control, which results in increased costs.
On the other hand, U.S. Pat. No. 5,455,609 discloses an arrangement employing the following drive force transmission mechanism for vertically moving the maintenance station. The transmission mechanism is arranged such that a worm gear mounted to an output shaft of a motor is meshed with a wheel gear, which is meshed with a rack. Unfortunately, this arrangement also suffers the complicated structure of the driving system.
In view of the foregoing, an object of the invention is to provide a less costly print head maintenance mechanism accomplishing a compact and simple construction by negating the need for the further widthwise increase of space for permitting the print head maintenance mechanism to move up and down.
The invention provides a print head maintenance mechanism for use in an ink jet printing machine in which printing is carried out by driving a carriage carrying a print head, the maintenance mechanism comprising:
a cap for preventing a nozzle provided at the print head from drying;
a cap holder retaining the cap and allowed to move along directions orthogonal to a primary scanning direction and a secondary scanning direction of the print head;
a first cam which is rotated at a predetermined position;
first biasing means for biasing the cap holder against the first cam;
a wiper for cleaning by wiping a surface of the nozzle provided at the print head;
a second cam which is rotated at a predetermined position;
a wiper holder retaining the wiper and allowed to move along directions orthogonal to the primary scanning direction and the secondary scanning direction of the print head; and
second biasing means for biasing the wiper holder against the second cam,
wherein the first and second cams are mounted to a single cam shaft, and
wherein the cam shaft is rotated through one revolution for switching the cap holder and wiper holder between a printing mode position for permitting a normal printing operation, a capping mode position for sealing the surface of the nozzle at the print head with the cap, and a wiping mode position for cleaning by wiping the nozzle surface with the wiper.
According to the invention, the cam shaft assembled with the two cams is rotated through one revolution thereby permitting the maintenance mechanism to be switched to the three mode positions. Therefore, the maintenance mechanism may be constructed in a simple structure of an easy control, which results in a low cost fabrication of the maintenance mechanism.
Thus, the invention is adapted to shift the cap holder and the wiper holder along the directions orthogonal to the primary scanning direction and the secondary scanning direction by way of rotation of the first and second cams. Specifically, in a case where the ink jet printing machine is disposed in a horizontal position, the cap holder and the wiper holder are shifted vertically so as to be switched to the printing mode position for permitting the normal printing operation, the capping mode position for sealing the surface of the nozzle at the print head, and the wiping mode position for cleaning by wiping the nozzle surface. Hence, the invention only needs to provide a space allowing for the vertical movements of the cap holder and the wiper holder, negating the need for the further widthwise increase of space. The provision of the print head maintenance mechanism does not require the ink jet printing machine to be further increased in the widthwise dimension so that the printing machine can accomplish a compact design. In addition, the rotation of a single cam shaft brings the two cams into rotation to switch the maintenance mechanism to the three mode positions. This ensures positive maintenance operations. Furthermore, the invention implements the switching function in a simple construction of an easy control, contributing to the low cost fabrication of the maintenance mechanism.
In addition, the invention accomplishes the switching to the three mode positions by rotating the cam shaft assembled with the two cams through one revolution and hence, the maintenance mechanism may be constructed in a simple construction of an easy control, which results in the low cost fabrication of the maintenance mechanism.
In the invention, it is preferable that the first biasing means for biasing the cap holder against the first cam comprises a pair of tension springs disposed at places on one of the diagonal lines of the cap holder as equi-spaced from the cam shaft.
According to the invention, the pair of tension springs as the first biasing means are disposed at places on one of the diagonal lines of the cap holder as equi-spaced from the cam shaft so that the cap holder may be biased against the cam in a well-balanced fashion. In addition, the first biasing means has a simple construction, contributing to the low cost fabrication of the maintenance mechanism.
In the invention, it is preferable that the second biasing means for biasing the wiper holder against the second cam comprises a pair of tension springs disposed at places on opposite sides of the cam shaft as equi-spaced from an axis of the wiper holder orthogonal to the cam shaft.
According to the invention, the pair of tension springs as the second biasing means are disposed at places on the opposite sides of the cam shaft as equi-spaced from the axis of the wiper holder orthogonal to the cam shaft so that the wiper holder may be biased against the cam in a well-balanced fashion. In addition, the second biasing means has a simple construction, contributing to the low cost fabrication of the maintenance mechanism.
Thus, the invention permits the wiper holder to be biased against the cam in a well-balanced fashion because the pair or tension springs as the second biasing means are disposed at places on the opposite sides of the cam shaft as equi-spaced from the axis of the wiper holder. Furthermore, the invention implements the second biasing means in a simple construction, thus offering the less costly maintenance mechanism.
In the invention, it is preferable that the first biasing means for biasing the cap holder against the first cam comprises a pair of tension springs disposed at places on one of the diagonal lines of the cap holder as equi-spaced from the cam shaft, and that the second biasing means for biasing the wiper holder against the second cam comprises a pair of tension springs disposed at places on opposite sides of the cam shaft as equi-spaced from an axis of the wiper holder orthogonal to the cam shaft.
According to the invention, the pair of tension springs as the first biasing means for the cap holder are disposed at places on one of the diagonal lines of the cap holder as equi-spaced from the cam shaft while the pair of tension springs as the second biasing means for the wiper holder are disposed at places on the opposite sides of the cam shaft as equi-spaced from the axis of the wiper holder. Hence, the first and second biasing means are capable of biasing the cap holder and the wiper holder against the first cam and the second cam in a well-balanced fashion, respectively. Furthermore, the first and second biasing means have simple constructions, thus contributing to the low cost fabrication of the maintenance mechanism.
Other and further objects, features, and advantages of the invention will be more explicit from the following detailed description taken with reference to the drawings wherein:
Now referring to the drawings, preferred embodiments of the invention are described below.
A print head maintenance mechanism according to one embodiment of the invention will hereinbelow be described with reference to the accompanying drawings.
Caps 27a, 27b for preventing nozzles (not shown) provided at the print heads 23, 24 from drying are mounted to cap holders 33a, 33b as constantly biased upward by helical compression springs 31a, 31b. The cap holders 33a, 33b are vertically movably mounted to one L6 of maintenance stations which is disposed on one side of the main frame 21 with respect to a primary scanning direction, or on the left side as seen in the FIG. 1.
The maintenance station L6 is allowed to move up and down as guided by a guide boss 36 standing upright from the main frame 21 and a guide rail 43 formed by bending a part of the main frame 21. The maintenance station L6 is biased toward a bottom of the main frame 21, or downwardly as seen in
One 28a of wipers for cleaning by wiping surfaces of the nozzles is fixed to a wiper holder 29a. The wiper holder 29a is vertically movably retained and guided by a guide member standing upright from the maintenance station L6 on one side. The wiper holder 29a is also biased toward the bottom of the main frame 21 or downwardly as seen in
The other wiper 28b is fixed to a wiper holder 29b. The wiper holder 29b is vertically movably retained and guided by a guide member standing upright from the other maintenance station R21 fixed to place on the other side of the main frame 21 with respect to the primary scanning direction, or on the right side as seen in the FIG. 1. The wiper holder 29b is constantly biased against a second cam 34d at its bottom by means of a pair of tension springs 30b as second biasing means stretched between the wiper holder 29b and the maintenance station R21.
The first cams 34a, 34c and the second cams 34b, 34d are fixedly mounted to a single cam shaft 34. A motor 51 (dedicated to the maintenance mechanism) operatively connected with the cam shaft 34 is rotated thereby shifting the cap holders 33a, 33b and the wiper holders 29a, 29b in a direction orthogonal to the primary scanning direction or to a secondary scanning direction of the carriage 22. Specifically, in a case where the main frame 21 is mounted in a horizontal position, the cap holders and wiper holders are shifted vertically, so as to be switched to three mode positions which include a printing mode position for permitting a normal printing operation (see FIGS. 1 and 2), a wiping mode position for cleaning by wiping the nozzle surfaces (see FIGS. 3 and 4), and a capping mode position for sealing the nozzle surfaces (see FIGS. 5 and 6).
The cap holders 33a, 33b are formed, for example, in a square shape in section taken at right angles to its axis. The pair of tension springs as the pair of the first biasing means 32 are disposed at places on one of the diagonal lines of each cap holder 33a, 33b in section taken at right angles to its axis as equi-spaced from the cam shaft 34. The pair of tension springs 32 have the same spring constant.
The pair of tension springs as the pair of the second biasing means 30a are disposed at places on opposite sides of an axis L1 of the wiper holder 29a orthogonal to the cam shaft 34 as equi-spaced from the cam shaft 34. The pair of tension springs 30a have the same spring constant.
The pair of tension springs as the pair of the second biasing means 30b are disposed at places on opposite sides of an axis L2 of the wiper holder 29b orthogonal to the cam shaft 34 as equi-spaced from the cam shaft 34. The pair of tension springs 30b have the same spring constant.
The pair of the first biasing means 32 for biasing the maintenance station L6 downwardly are disposed at symmetrical places with respect to an axis of the cam shaft 34 or equi-spaced from abutment places between the cap holders 33a, 33b and the cams. Hence, the cap holders 33a, 33b are biased against the first cams 34a, 34c in a well-balanced fashion. Likewise, the wiper holder 29a on one side is also biased against the second cam 34b by means of the pair of the second biasing means 30a disposed at symmetrical places with respect to the axis of the cam shaft 34 or equi-spaced from an abutment place between the wiper holder 29a and the second cam 34b. Therefore, the wiper holder 29a is biased in a stable manner. Similarly, the other wiper holder 29b is also biased against the second cam 34d by means of the pair of the second biasing means 30b, 30b disposed at symmetrical places with respect to the axis of the cam shaft 34 or equi-spaced from an abutment place between the wiper holder 29b and the second cam 34d. Therefore, the wiper holder 29b is biased in a stable manner. Such a simple construction ensures that the cap holders 33a, 33b and the wiper holders 29a, 29b are positively moved up and down, thus contributing to the low cost fabrication of the maintenance mechanism.
On the other hand, the cam shaft 34 is disposed directly under the maintenance station L6 and the maintenance station R21 and is rotated by the motor 51 via a cam gear 35 and a gear not shown. An initial position of the cam shaft 34 is detected by means of a position detection switch 42 disposed at a place corresponding to the cam gear 35. The motor 51 is controlled based on a counted number of feed steps, so as to permit the mechanism to be switched to the three mode positions including the printing mode position, capping mode position and wiping mode position.
For a mere reference purpose, preferred rotational angles for the cam shaft 34 to assume the respective mode positions according to the embodiment are listed as below: From normal (printing) mode to wiping mode: 97.1°, From wiping mode to capping mode: 112.2°, and From capping mode to normal (printing) mode: 150.7°.
With such definitions of the rotational angles, rotating the cam shaft 34 through one revolution permits the maintenance mechanism to be switched to the three operation modes. Furthermore, the switching from one operation mode to another may be easily controlled.
The print head maintenance mechanism constructed as described above performs a sequence of operations which are switched from the normal printing mode to the wiping mode including purging of waste ink, and then to the capping mode. The following description explains these operations.
At an input of a print signal from a control system not shown, the control unit 50 firstly rotates the motor 51 to move down the caps 27a, 27b and the wipers 28a, 28b to places out of interference with the print heads 23, 24, as shown in
During the printing operation, a cleaning operation is performed at given time intervals for ensuring a print quality, the cleaning operation including the wiping of the nozzle surfaces and purging cleaning for removing waste ink adhered to nozzle apertures by jetting the ink therethrough. As shown in
After completion of the printing operation, the sheet is discharged by a discharge roller (not shown) toward the front side with respect to the drawing surface of
In the state shown in
In the state shown in
In this state, both the wipers 28a, 28b operate as illustrated in the flow chart of
More specifically, a wipe command signal triggers the wiping operation in Step a1. If the control unit 50 determines in the subsequent Step a2 that the wipe command indicates the wiping of both a color ink and a monochromatic ink, the control proceeds to Step a3 where the carriage 22 is moved from the printing region substantially of the same area as that of a sheet conveyance region shown in
In Step a5, the carriage 22 at the left end is moved toward the printing region along the primary scanning direction, thereby performing the wiping of the color ink. Thus, the wiper 28a cleans by wiping the nozzle surface at the print head 23 for color ink. In the subsequent Step a6, the control unit 50 controllably drives the motor 51 to rotate the cam shaft 34 based on a number of feed steps and a signal from the position detection switch 42, thereby bringing the second cams 34b, 34d into rotation to lower the wipers 28a, 28b to places out of interference with the print heads 23, 24. In the subsequent Step a7, the carriage 22 is moved from the printing region to the other end of the primary scanning movement defined at the right end of the main frame 21, so that the carriage 22 is positioned directly above the other maintenance station R21.
In the subsequent Step a8, the control unit 50 controllably drives the motor 51 to rotate the cam shaft 34 based on a number of feed steps and a signal from the position detection switch 42, thereby bringing the second cams 34b, 34d into rotation to raise the wipers 28a, 28b to the wiping mode positions. In the subsequent Step a9, the carriage 22 at the right end is moved toward the printing region along the primary scanning direction, thereby performing the wiping of the monochromatic ink. Thus, the wiper 28b cleans by wiping the nozzle surface at the print head 24 for monochromatic ink. In the subsequent Step a10, the control unit 50 controllably drives the motor 51 to rotate the cam shaft 34 based on a number of feed steps and a signal from the position detection switch 42, thereby bringing the second cams 34b, 34d into rotation to lower the wipers 28a, 28b to places out of interference with the print heads 23, 24. In the subsequent Step a11, the carriage 22 is moved from the printing region to the right end of the main frame 21, so that the carriage 22 is positioned directly above the other maintenance station R21.
In the subsequent Step a12, the print heads 23, 24 perform the purging cleaning by individually spitting the inks toward the waste ink receiving portion of the maintenance station R21. In the subsequent Step a13, the carriage 22 at the right end is moved to the printing region along the primary scanning direction, so that the printing operation is resumed.
If the control unit 50 determines in Step a2 that the wipe command does not indicate the wiping of both the color ink and the monochromatic ink and then determines in Step a14 that the wipe command indicates the wiping of the color ink, the same operations as in Steps a3 to a7 are performed in Steps a15 to a19 for cleaning by wiping the nozzle surface at the print head 23 for color ink. After the purging cleaning is performed in the subsequent Step a12, the printing operation is resumed in Step a13.
If the control unit 50 determines in Step a2 that the wipe command does not indicate the wiping of both the color ink and the monochromatic ink and then determines in Step a14 that the wipe command indicates the wiping of the monochromatic ink rather than the color ink, the same operations as in Steps a7 to all are performed in Steps a20 to a24 for cleaning by wiping the nozzle surface at the print head 24 for monochromatic ink. After the purging cleaning is performed in the subsequent Step a12, the printing operation is resumed in Step a13.
In the state shown in
The capping operation may be performed as illustrated in the flow chart of
More specifically, in response to a print start command given in Step b1, Step b2 is performed where the control unit 50 controllably drives the motor 51 to rotate the cam shaft 34 based on a number of feed steps and a signal from the position detection switch 42, thereby bringing the first cams 34a, 34c into rotation to lower the caps 27a, 27b from the capping mode positions to the printing mode positions. Thus, the caps 27a, 27b are moved away from the nozzle surfaces at the print heads 23, 24. In the subsequent Step b3, the carriage 22 at the standby position is moved to the printing region. In Step b4, the printing operation is started while the carriage 22 reciprocates along the primary scanning direction.
At termination of the printing operation in Step b5, the carriage 22 at the printing region is moved to the standby position in Step b6. In Step b7, the control unit 50 controllably drives the motor 51 to rotate the cam shaft 34 based on a number of feed steps and a signal from the position detection switch 42, thereby bringing the first cams 34a, 34c into rotation to raise the caps 27a, 27b from the printing mode positions to the capping mode positions. Thus, the caps 27a, 27b come into intimate contact with the nozzle surfaces at the print heads 23, 24 for sealing the nozzle surfaces. In the subsequent Step b8, the print heads stay at the standby positions to maintain a capped state until the next print start command is given.
As described above, the cap holders 33a, 33b and the wiper holders 29a, 29b can be vertically shifted by rotating the first cams 34a, 34c and the second cams 34b, 34d, whereby the maintenance mechanism can be switched to the printing mode position for permitting the normal printing operation, the capping mode position for sealing the nozzle surfaces at the print heads 23, 24, and the wiping mode position for cleaning by wiping the nozzle surfaces. Hence, the mechanism only requires a space allowing for the vertical movement of the cap holders 33a, 33b and the wiper holders 29a, 29b, negating the need for the widthwise increase of space. With the print head maintenance mechanism according to one embodiment of the invention as shown in
The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description and all changes which come within the meaning and the range of equivalency of the claims are therefore intended to be embraced therein.
Number | Date | Country | Kind |
---|---|---|---|
P2002-080961 | Mar 2002 | JP | national |
This nonprovisional application claims priority under 35 U.S.C. § 119(a) on Patent Application No(s). 2002-80961 filed in JAPAN on Mar. 22, 2002, which is (are) herein incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
5138343 | Aichi et al. | Aug 1992 | A |
5406317 | Shimamura et al. | Apr 1995 | A |
5455609 | Gast et al. | Oct 1995 | A |
6132027 | Suzuki et al. | Oct 2000 | A |
6398338 | Berg et al. | Jun 2002 | B1 |
20020003553 | Ng | Jan 2002 | A1 |
Number | Date | Country |
---|---|---|
0 913 264 | May 1999 | EP |
11192716 | Jul 1999 | JP |
2000-203042 | Jul 2000 | JP |
2000-233517 | Aug 2000 | JP |
2002-036578 | Feb 2002 | JP |
Number | Date | Country | |
---|---|---|---|
20030179261 A1 | Sep 2003 | US |