The present invention relates to an ink jet head, a method for inspecting an actuator, a method for manufacturing an ink jet head, and an ink jet recording apparatus.
In recent years, high-density ink jet heads that are produced by using a so-called “transfer process” have been proposed in the art, as disclosed in, for example, Japanese Laid-Open Patent Publication No. 10-286953. A transfer process is an advantageous process as a method for producing a high-density head. A method for producing a head using a transfer process is as follows, for example.
First, a separate electrode is formed on a single crystal MgO substrate. Then, a piezoelectric member, being a perovskite-type dielectric thin film made of PZT, is formed on the separate electrode. Furthermore, a vibration plate that functions also as a common electrode is formed on the piezoelectric member by a sputtering method, or the like. Thus, a thin film actuator is produced. Then, the actuator on the substrate is attached to a pressure chamber plate, and the whole or part of the substrate is thereafter removed.
However, it was difficult to produce a line type ink jet head with the transfer process as described above for the following reasons.
In a line type ink jet head, the length of the head in the longitudinal direction needs to be greater than the paper width of the recording paper. For example, in order to record information on A4-size paper, the length of the head in the longitudinal direction needs to be 210 mm or more. Therefore, the length of the single crystal MgO substrate also needs to be 210 mm or more. However, while a single crystal MgO substrate is produced from a rock lump of MgO, the entire rock lump cannot be used, but what can actually be used is only a portion thereof. Therefore, in order to produce a single crystal MgO substrate whose length is 210 mm or more, it is necessary to provide a lump of MgO of such a length, thereby requiring very large equipment. Even if such a single crystal MgO substrate can be produced, the yield will be poor. Therefore, such a substrate will be a very costly material.
Moreover, in a transfer process, it is necessary to deposit, by a sputtering method, or the like, PZT on a single crystal MgO substrate. However, it requires very large equipment to deposit PZT over a large area. In addition, the yield lowers when one attempts to obtain a film that is uniform in properties such as the piezoelectric property and the thickness and that has no crack therein. Therefore, the manufacturing cost becomes very high.
For the reasons as described above, it was difficult to use a transfer process for a conventional line type ink jet head in view of the quality and the cost.
Moreover, along with the increase in the density of ink jet heads, there is an increasing demand for improving the reliability thereof. In the prior art, inspection of an ink jet head including actuators is performed after transferring the actuators onto a pressure chamber block.
With the conventional method, however, when a defect was included in an actuator, it was necessary to waste the pressure chamber block along with the actuator even if the pressure chamber block itself had no problem. In other words, it was not possible to waste only the actuator while using the non-defective pressure chamber block.
The present inventors have devised a way of effectively using a transfer process for a line type ink jet head, in which a plurality of actuators are provided for each pressure chamber block by dividing an actuator, which was a single component in the prior art, into a plurality of actuators. In such an ink jet head using a plurality of actuators, even if a defect is included in one actuator, the other actuators may be non-defective. If inspection is performed after transferring the actuators onto the pressure chamber block as in the prior art, the actuators cannot be wasted individually, whereby it is necessary to waste non-defective actuators along with defective actuators. However, this leads to an increase in the material cost and the manufacturing cost. It also lowers the yield. In view of this, it is preferred to perform an early inspection on individual actuators before they are transferred onto the pressure chamber block, and to waste the defective actuators individually.
Moreover, an ink jet head including a plurality of nozzles, a plurality of pressure chambers respectively communicated to the nozzles, and an actuator for pressurizing or depressurizing an ink in each pressure chamber so as to discharge the ink through each nozzle, has been widely used in the prior art in a recording apparatus such as a printer. In such an ink jet head, the nozzles are arranged in a direction perpendicular to the scanning direction at a minute pitch that corresponds to a predetermined dot density.
In recent years, however, the recording image quality has been improved, and the actuators and the nozzles are arranged with an increasing density. For example, in an ink jet head for recording information at 600 dpi, the nozzles are arranged at a minute pitch of 42.3 μm.
However, as the density of actuators and nozzles increases, it becomes more difficult to ensure uniformity in the properties of the actuators and to process the nozzles properly. If the properties are not uniform among the actuators or if the nozzles are misshaped, it is no longer possible to discharge a predetermined amount of ink droplets through the nozzles and to stably form ink dots of a predetermined size on the recording medium. Therefore, along with the increase in the density, there is a higher possibility that some of the large number of actuators and nozzles may be incapable of forming an ink dot of the predetermined size.
For example, where some actuators have an inferior performance, such actuators can only form ink dots that are slightly smaller than the predetermined size. Such small dots, if dispersed, cannot be distinguished by human eyes. However, if small dots D2 are aligned in a continuous single row, as illustrated in
The present invention has been made in view of the above, and has an object to provide a line type ink jet head that can be produced by a transfer process, and to realize an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc., for a line type ink jet head and a recording apparatus having the same.
Moreover, another object of the present invention is to provide an inspection method for inspecting an actuator before it is attached to a pressure chamber block, a method for manufacturing an ink jet head that effectively utilizes the inspection method, and an ink jet recording apparatus utilizing the manufacturing method.
Moreover, still another object of the present invention is to improve the quality of character-printing or image-printing by preventing a white streak as described above from occurring.
An ink jet head of the present invention is an ink jet head, including a plurality of line heads arranged in a scanning direction, wherein: each line head includes: a pressure chamber block including a common liquid chamber for storing an ink, a plurality of pressure chambers communicated to the common liquid chamber, and a plurality of nozzles respectively communicated to the pressure chambers; and a plurality of actuator blocks each including a piezoelectric element, a first electrode and a second electrode for applying a voltage across the piezoelectric element, and a vibration plate, the plurality of actuator blocks being arranged on one surface of the pressure chamber block so that more than one of the pressure chambers of the pressure chamber block are covered by the vibration plate; and the actuator blocks of each line head are arranged in a head longitudinal direction with adjacent ones of the actuator blocks being spaced apart from each other, and the actuator blocks of the line head are shifted from the actuator blocks of another line head in the head longitudinal direction while partially overlapping with the actuator blocks of the other line head in the head longitudinal direction.
In this way, a plurality of actuator blocks are provided for each pressure chamber block, whereby the size of each actuator block can be reduced. Therefore, it is possible to realize an improved uniformity in properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc.
Moreover, in each line head, the actuator blocks are spaced apart from one another, whereby the actuator blocks will not physically overlap with each other even if the error in the shape of the actuator blocks is large or if the positional precision of the actuator blocks is somewhat low. Thus, it is possible to improve the yield.
Since the actuator blocks of each line head are shifted in the head longitudinal direction from the actuator blocks of another line head, the actuator blocks are arranged at intervals in the head longitudinal direction for each line head alone. However, for the plurality of line heads as a whole, the actuator blocks are arranged with no gap therebetween in the head longitudinal direction. Particularly, the actuator blocks of each line head are arranged so as to partially overlap with the actuator blocks of another line head, whereby the actuator blocks as a whole are arranged with no gap therebetween in the head longitudinal direction. Therefore, actuators can be arranged at a predetermined interval in the head longitudinal direction.
In one embodiment, the line heads include a plurality of line heads of a same shape; and the line heads of the same shape are shifted from one another in the head longitudinal direction.
In one embodiment, in each of the line heads of the same shape, a plurality of actuator blocks are arranged at a predetermined interval that is shorter than a length of each actuator block in the head longitudinal direction; and the line heads of the same shape are shifted from each other in the head longitudinal direction so that the actuator block of one line head is located between the actuator blocks of the other line head with respect to the head longitudinal direction.
Thus, by arranging the line heads of the same shape so as to be shifted from each other in the head longitudinal direction, the actuator blocks as a whole are arranged with no gap therebetween in the head longitudinal direction. Since the line heads are of the same shape, it is not necessary to separately manufacture a plurality of types of line heads of different shapes, thus reducing the cost by employing a uniform line head shape.
In one embodiment, the line heads include at least a pair of line heads of a same shape; and the pair of line heads are arranged in point symmetry with each other.
In one embodiment, in each of the line heads of the same shape, a plurality of actuator blocks are arranged at a predetermined interval that is shorter than a length of each actuator block in the head longitudinal direction; and the line heads of the same shape are arranged in point symmetry with each other so that the line heads are aligned with each other at both ends in the head longitudinal direction and so that the actuator block of one line head is located between the actuator blocks of the other line heads with respect to the head longitudinal direction.
Thus, a pair of line heads of the same shape are arranged in point symmetry with each other, whereby the actuator blocks as a whole are arranged with no gap therebetween in the head longitudinal direction. Since the line heads are of the same shape, it is not necessary to separately manufacture a plurality of types of line heads of different shapes, thus reducing the cost by employing a uniform line head shape.
Since the line heads are aligned with each other at both ends thereof in the head longitudinal direction, the length of the head in the longitudinal direction is reduced as compared to a case where they are shifted from each other at both ends thereof.
In one embodiment, the actuator blocks of the plurality of line heads as a whole are arranged in a staggered pattern.
Thus, the actuator blocks are arranged in a staggered pattern, and the actuator blocks are arranged with no gap therebetween in the head longitudinal direction.
In one embodiment, the line heads discharge an ink of a same type.
In this way, it is possible to obtain an ink jet head that discharges an ink of a single color.
In one embodiment, the line heads form line head groups each including a plurality of line heads that discharge an ink of a same type; a plurality of such line head groups are provided in the scanning direction so as to discharge inks of different types.
Thus, a plurality of line heads each discharging an ink of the same type are arranged in the scanning direction, thereby forming a line head group. In the line head group, the actuator blocks as a whole are arranged with no gap therebetween in the head longitudinal direction. A plurality of such line head groups are arranged in the scanning direction, thereby obtaining an ink jet head that discharges inks of different types. Note that the inks of different types may be either different types of inks of the same color or inks of different colors. If inks of different colors are used, a color image can be formed.
In one embodiment, the line heads discharge inks of different types.
Thus, the line heads discharge inks of different types, thereby obtaining an ink jet head that discharges inks of different types.
Another ink jet head of the present invention is an ink jet head, including: a pressure chamber block including a common liquid chamber for storing an ink, a plurality of pressure chambers communicated to the common liquid chamber, and a plurality of nozzles respectively communicated to the pressure chambers; and a plurality of actuator blocks each including a piezoelectric element, a first electrode and a second electrode for applying a voltage across the piezoelectric element, and a vibration plate, the plurality of actuator blocks being arranged on one surface of the pressure chamber block so that more than one of the pressure chambers of the pressure chamber block are covered by the vibration plate, wherein: the pressure chambers of the pressure chamber block form a plurality of pressure chamber rows arranged in a head longitudinal direction, each pressure chamber row including more than one of the pressure chambers that are arranged in a direction inclined from the head longitudinal direction; the pressure chamber rows are arranged parallel to one another; each of the actuator blocks is formed in a parallelogram shape having a side that is parallel to a row direction of each pressure chamber row; and the actuator blocks are arranged in the head longitudinal direction so as to be spaced apart from one another.
In this way, a plurality of actuator blocks are provided for each pressure chamber block, whereby the size of each actuator block can be reduced. Thus, a transfer process can be effectively utilized. Therefore, it is possible to realize an improved uniformity of piezoelectric elements of actuator blocks in terms of properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc.
Moreover, in the pressure chamber block, the pressure chamber rows are arranged parallel to one another, and the row direction of the pressure chamber rows is inclined from the head longitudinal direction, with the pressure chambers being shifted from one another in the scanning direction (i.e., the direction perpendicular to the head longitudinal direction). Therefore, although the pressure chambers are arranged at a minute interval in the head longitudinal direction for the head as a whole, the interval between adjacent pressure chambers is increased in each pressure chamber row by the shift between pressure chambers in the scanning direction. Similarly, although the interval between pressure chamber rows is a minute interval with respect to the head longitudinal direction, it is relatively large with respect to the direction perpendicular to the row direction of the pressure chamber rows.
Herein, each actuator block is formed in a parallelogram shape having a side that is parallel to the row direction of the pressure chamber rows. Therefore, even if the actuator blocks are arranged in the head longitudinal direction so as to be spaced apart from one another, the actuator blocks will cover all the pressure chambers, with no pressure chamber being left uncovered, for the head as a whole because of the large interval between the pressure chamber rows in the direction perpendicular to the row direction thereof. Thus, although the actuator blocks are arranged at intervals, a plurality of actuators are arranged at a minute interval in the head longitudinal direction so as to correspond to the respective pressure chambers for the head as a whole.
Thus, the actuator blocks can be arranged so as to be spaced apart from one another, whereby the actuator blocks will not physically overlap with each other even if there is an error in the shape or arrangement of the actuator blocks. Therefore, an error in the shape or arrangement of the actuator blocks can be tolerated to a considerable degree, thereby improving the yield.
One possible arrangement pattern for arranging the actuator blocks so as to be spaced apart from one another is one where the actuator blocks are arranged in a staggered pattern. However, with such an arrangement pattern, it is necessary to provide two rows of actuator blocks, thereby increasing the length of the head in the scanning direction. In contrast, with an ink jet head as described above, it is not necessary to provide two rows of actuator blocks, thereby reducing the length of the head in the scanning direction. Therefore, it is possible to downsize the head. Moreover, if the head is long in the scanning direction, the recording medium is likely to be bent, whereby the recording operation is likely to be unstable. However, with an ink jet head as described above, the length of the head in the scanning direction is reduced, whereby the recording medium is less likely to be bent. Therefore, a stable recording operation can be performed.
In one embodiment, the pressure chambers of the pressure chamber block are arranged at a predetermined interval with respect to the head longitudinal direction so that a longitudinal direction of each pressure chamber is perpendicular to the head longitudinal direction; the pressure chambers of each pressure chamber row are arranged at the predetermined interval; and the pressure chamber at one end of a pressure chamber row and the pressure chamber at one end of an adjacent pressure chamber row are arranged at the predetermined interval.
In one embodiment, the pressure chambers of the pressure chamber block are arranged at a predetermined interval with respect to the head longitudinal direction so that a longitudinal direction of each pressure chamber is perpendicular to the head longitudinal direction; at least two pressure chambers included in each pressure chamber row are arranged at an interval that is a multiple of the predetermined interval; and at least one of the pressure chambers included in each pressure chamber row is provided between two pressure chambers included in an adjacent pressure chamber row with respect to the head longitudinal direction.
In one embodiment, the pressure chambers of the pressure chamber block are arranged at a predetermined interval with respect to the head longitudinal direction so that a longitudinal direction of each pressure chamber is inclined from the head longitudinal direction; the pressure chambers of each pressure chamber row are arranged at the predetermined interval; and the pressure chamber at one end of a pressure chamber row and the pressure chamber at one end of an adjacent pressure chamber row are arranged at the predetermined interval.
In one embodiment, the pressure chambers of the pressure chamber block are arranged at a predetermined interval with respect to the head longitudinal direction so that a longitudinal direction of each pressure chamber and a row direction of each pressure chamber row are parallel to each other; at least two pressure chambers included in each pressure chamber row are arranged at an interval that is a multiple of the predetermined interval; and at least one of the pressure chambers included in each pressure chamber row is provided between two pressure chambers included in an adjacent pressure chamber row with respect to the head longitudinal direction.
In this way, at least two pressure chambers of each pressure chamber row are arranged at an interval that is a multiple of the predetermined interval (see FIG. 19), the interval between these pressure chambers is increased. Therefore, interference is less likely to occur between the actuators corresponding to these pressure chambers. In other words, crosstalk is less likely to occur. Therefore, the ink discharging performance is improved.
Moreover, since the longitudinal direction of each pressure chamber and the row direction of the pressure chamber rows are parallel to each other (see FIG. 21), each actuator block has a side that is parallel to the longitudinal direction of each pressure chamber. Therefore, the length of another side of the actuator block can be reduced, thereby further reducing the size of the actuator block. Moreover, the interval between the actuator blocks can be further increased.
In one embodiment, the pressure chamber block includes a plurality of sets of the common liquid chamber, the nozzles, the pressure chamber rows and the actuator blocks, the plurality of sets being arranged in a scanning direction.
In this way, a plurality of sets of the common liquid chamber, the nozzles, the pressure chamber rows and the actuator blocks are arranged in the scanning direction (see FIG. 23), whereby effects as those described above can be obtained with a head that discharges inks of different types, similarly to the case described above where a plurality of line type ink jet heads are provided in the scanning direction. If inks of different colors are used, a color image can be formed.
In one embodiment, the actuator block includes a conductive vibration plate that functions also as the second electrode, instead of including the second electrode and the vibration plate.
In this way, it is possible to reduce the number of components of each actuator block.
Still another ink jet head of the present invention includes: a head body including two or more nozzle rows each including a plurality of nozzles, wherein one or more of the nozzles of at least one nozzle row is located along a same line in a scanning direction with one or more of the nozzles of another nozzle row; and an actuator for causing an ink to be discharged from the nozzles, wherein the actuator causes an ink of a same type to be discharged, alternately by one shot or by a number of shots, from the nozzles that are located along the same line in the scanning direction.
Still another ink jet head of the present invention includes at least two head blocks arranged in a scanning direction, each head block including a head body in which one or more nozzle row including a plurality of nozzles is formed, and an actuator for causing an ink to be discharged from the nozzles, wherein: the head blocks are arranged so that one or more of the nozzles of at least one head block is located along a same line in a scanning direction with one or more of the nozzles of another head block; and the actuators of the head blocks cause an ink of a same type to be discharged, alternately by one shot or by a number of shots, from the nozzles that are located along the same line in the scanning direction.
In an ink jet head as described above, an ink of the same type is discharged alternately from nozzles that are located on the same line in the scanning direction, whereby the ink discharged from the nozzles alternately forms ink dots on the recording medium. If one of the nozzles (or the actuators, etc., corresponding to the nozzles) is incapable of discharge a predetermined amount of ink, the ink discharged from the nozzle forms an ink dot of a size different from that of a normal ink dot. However, since the ink dots are formed alternately as described above, ink dots of the different size will not be aligned in a continuous row in the scanning direction. Therefore, a white streak is prevented from occurring.
Still another ink jet head of the present invention is an ink jet head, including: a pressure chamber block including a common liquid chamber for storing an ink, a plurality of pressure chambers communicated to the common liquid chamber, and a plurality of nozzles respectively communicated to the pressure chambers; and an actuator including a piezoelectric element, a first electrode and a second electrode for applying a voltage across the piezoelectric element, and a vibration plate, the actuator being arranged on the pressure chamber block so that the pressure chambers of the pressure chamber block are covered by the vibration plate, wherein: the pressure chambers of the pressure chamber block form a plurality of pressure chamber rows arranged in a head longitudinal direction and in a scanning direction, each pressure chamber row including more than one of the pressure chambers arranged in a direction that is inclined from the head longitudinal direction; at least one pressure chamber of a pressure chamber row is located along a same line in the scanning direction with at least one pressure chamber of another pressure chamber row, and nozzles that correspond to the pressure chambers located along the same line in the scanning direction are also located along a same line in the scanning direction; and the actuator causes an ink of a same type to be discharged, alternately by one shot or by a number of shots, from the nozzles that are located along the same line in the scanning direction.
In this way, an ink of the same type is discharged alternately from nozzles that are located on the same line in the scanning direction, whereby a white streak is prevented from occurring.
In one embodiment, the actuator includes a plurality of actuator blocks each having an area that is smaller than the pressure chamber block; the actuator blocks are arranged in the head longitudinal direction and in the scanning direction; and adjacent ones of the actuator blocks are spaced apart from each other in the scanning direction while partially overlapping with each other with respect to the head longitudinal direction.
In this way, an actuator includes a plurality of actuator blocks, whereby the size of each actuator block can be small even if the pressure chamber block is of a relatively large size such as those in a line type head. Therefore, the actuator blocks can be produced by a so-called “transfer process”, whereby it is possible to realize an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc.
Moreover, adjacent actuator blocks are spaced apart from each other, whereby the actuator blocks will not physically overlap with each other even if the positional precision of the actuator blocks is somewhat low or if the error in the shape of the actuator blocks is somewhat large. On the other hand, since adjacent actuator blocks are arranged so as to partially overlap with each other with respect to the head longitudinal direction, all the pressure chambers arranged in the head longitudinal direction are reliably covered by the actuator blocks with no pressure chamber being left uncovered. Therefore, although a plurality of actuator blocks are used, the production error and the positioning error thereof can be tolerated to a considerable degree, thereby improving the yield.
Still another ink jet head of the present invention is an ink jet head, including: a pressure chamber block including a common liquid chamber for storing an ink, a plurality of pressure chambers communicated to the common liquid chamber, and a plurality of nozzles respectively communicated to the pressure chambers; and an actuator including a piezoelectric element, a first electrode and a second electrode for applying a voltage across the piezoelectric element, and a vibration plate, the actuator being arranged on the pressure chamber block so that the pressure chambers of the pressure chamber block are covered by the vibration plate, wherein: the pressure chambers of the pressure chamber block form a plurality of pressure chamber rows arranged in a head longitudinal direction, each pressure chamber row including more than one of the pressure chambers arranged in a direction that is inclined from the head longitudinal direction; at least one pressure chamber of a pressure chamber row is located along a same line in the scanning direction with at least one pressure chamber of another pressure chamber row, and nozzles that correspond to the pressure chambers located along the same line in the scanning direction are also located along a same line in the scanning direction; and the actuator causes an ink of a same type to be discharged, alternately by one shot or by a number of shots, from the nozzles that are located along the same line in the scanning direction.
In this way, an ink of the same type is discharged alternately from nozzles that are located on the same line in the scanning direction, whereby a white streak is prevented from occurring.
In one embodiment, the actuator includes a plurality of actuator blocks each in a parallelogram shape having an area that is smaller than the pressure chamber block and having a side that is parallel to a row direction of the pressure chamber rows; the actuator blocks are arranged in the head longitudinal direction; and adjacent ones of the actuator blocks are spaced apart from each other.
In this way, even if the pressure chamber block is of a relatively large size, the actuator blocks can be produced by a so-called “transfer process”, whereby it is possible to realize an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness.
Moreover, the row direction of the pressure chamber rows is inclined from the head longitudinal direction, and the pressure chambers are shifted from one another in the scanning direction. Therefore, although the pressure chambers are arranged at a minute interval in the head longitudinal direction for the head as a whole, the interval between adjacent pressure chambers is increased in each pressure chamber row by the shift between pressure chambers in the scanning direction. Similarly, although the interval between pressure chamber rows is a minute interval with respect to the head longitudinal direction, it is relatively large with respect to the direction perpendicular to the row direction of the pressure chamber rows.
Herein, each actuator block is formed in a parallelogram shape having a side that is parallel to the row direction of the pressure chamber rows. Therefore, even if the actuator blocks are arranged in the head longitudinal direction so as to be spaced apart from one another, the actuator blocks will cover all the pressure chambers, with no pressure chamber being left uncovered, for the head as a whole because of the large interval between the pressure chamber rows in the direction perpendicular to the row direction thereof. Thus, although the actuator blocks are arranged at intervals, a plurality of actuators are arranged at a minute interval in the head longitudinal direction so as to correspond to the respective pressure chambers for the head as a whole.
Thus, the actuator blocks can be arranged so as to be spaced apart from one another, whereby the actuator blocks will not physically overlap with each other even if there is an error in the shape or arrangement of the actuator blocks. Therefore, an error in the shape or arrangement of the actuator blocks can be tolerated to a considerable degree, thereby improving the yield.
In addition, it is not necessary to provide two rows of actuator blocks, thereby reducing the length of the head in the scanning direction. Therefore, it is possible to downsize the head. Moreover, if the head is long in the scanning direction, the recording medium is likely to be bent, whereby the recording operation is likely to be unstable. However, with an ink jet head as described above, the length of the head in the scanning direction is reduced, whereby the recording medium is less likely to be bent. Therefore, a stable recording operation can be performed.
Still another ink jet head of the present invention is an ink jet head, including a plurality of line heads arranged in a scanning direction, wherein: each line head includes: a pressure chamber block including a common liquid chamber for storing an ink, a plurality of pressure chambers communicated to the common liquid chamber, and a plurality of nozzles respectively communicated to the pressure chambers; and an actuator including a piezoelectric element, a first electrode and a second electrode for applying a voltage across the piezoelectric element, and a vibration plate, the actuator being arranged on the pressure chamber block so that the pressure chambers of the pressure chamber block are covered by the vibration plate, wherein the pressure chambers of the pressure chamber block form a plurality of pressure chamber rows arranged in a head longitudinal direction, each pressure chamber row including more than one of the pressure chambers arranged in a direction that is inclined from the head longitudinal direction; the line heads are arranged so that one or more pressure chamber of at least one line head is located along a same line in the scanning direction with one or more pressure chamber of another line head, and the nozzles that correspond to the pressure chambers located along the same line in the scanning direction are also located along a same line in the scanning direction; and the actuators of the line heads cause an ink of a same type to be discharged, alternately by one shot or by a number of shots, from the nozzles that are located along the same line in the scanning direction.
In this way, an ink of the same type is discharged alternately from nozzles that are located on the same line in the scanning direction, whereby a white streak is prevented from occurring.
In one embodiment, the actuator of each line head includes a plurality of actuator blocks each having an area that is smaller than the pressure chamber block; the actuator blocks of each line head are arranged in the head longitudinal direction so that adjacent ones of the actuator blocks are spaced apart from each other; and the line heads are arranged so that the actuator block of each line head partially overlaps with the actuator block of another line head with respect to the head longitudinal direction.
In this way, the production of an actuator block by a transfer process is facilitated, whereby it is possible to realize an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness.
In one embodiment, the actuator blocks are arranged in a staggered pattern.
Thus, the actuator blocks are arranged in a staggered pattern, whereby the actuator blocks as a whole are arranged with no gap therebetween in the head longitudinal direction.
In one embodiment, the actuator includes a conductive vibration plate that functions also as the second electrode, instead of including the second electrode and the vibration plate.
In this way, the number of components of each actuator block is reduced.
In one embodiment, a plurality of ink jet heads as described above are provided for inks of different types and are arranged in the scanning direction.
In this way, effects as those described above can be obtained with an ink jet head that discharges inks of different types. If inks of different colors are used, effects as those described above can be obtained with an ink jet head that forms a color image.
A method for inspecting an actuator of the present invention is a method for inspecting an actuator including a piezoelectric element, and a first electrode and a second electrode that are provided on opposite sides of the piezoelectric element, the method including: a step of producing an actuator forming member in which the first electrode, the piezoelectric element and the second electrode are deposited in this order on a substrate, with a portion of the first electrode being exposed; and an inspection step of inspecting a property of the piezoelectric element by contacting inspection probes to the exposed portion of the first electrode and the second electrode.
With an inspection method as described above, the exposed portion is formed in the first electrode with the first electrode, the piezoelectric element and the second electrode being deposited on the substrate, whereby it is easy to contact the inspection probes to the first electrode and the second electrode. Then, a property of the actuator is inspected by, for example, contacting the inspection probes to the exposed portion of the first electrode and the second electrode by pressing the inspection probes thereonto, and supplying a predetermined voltage or current between the first electrode and the second electrode. Therefore, before attaching the actuator to the pressure chamber block, the property thereof can be easily inspected.
In one embodiment, the step of producing an actuator forming member includes: a step of depositing the first electrode on the substrate; and a step of depositing the piezoelectric element and the second electrode on the first electrode while blocking a portion of the first electrode using a mask so that the portion becomes an exposed portion.
In one embodiment, the step of producing an actuator forming member includes: a step of depositing the first electrode, the piezoelectric element and the second electrode in this order on the substrate; and a step of etching a portion of the second electrode and the piezoelectric element so that a portion of the first electrode becomes an exposed portion.
In one embodiment, the step of producing an actuator forming member includes: a step of depositing the first electrode and the piezoelectric element in this order on the substrate; a step of depositing the second electrode on the piezoelectric element while blocking a portion of the piezoelectric element using a mask so that the portion of the piezoelectric element becomes an exposed portion; and a step of etching the exposed portion of the piezoelectric element so that a portion of the first electrode becomes an exposed portion.
In this way, the actuator forming member can be easily produced.
In one embodiment, the inspection step includes a step of attaching a conductive paste material to one or both of the exposed portion of the first electrode and the second electrode, and contacting the inspection probes to the first electrode or the second electrode via the paste material.
In an inspection method as described above, the inspection probes are contacted to the exposed portion of the first electrode and the second electrode via the paste material. Then, a predetermined voltage or current, etc., is supplied between the first electrode and the second electrode to inspect the property of the actuator. The inspection probes are firmly fixed to the electrodes by the paste material, whereby the electrical contact between the inspection probes and the electrodes is ensured without pressing the inspection probes thereonto with a strong force. Therefore, an adverse influence in the property inspection due to the inspection probe pressing force is minimized.
In one embodiment, the inspection step includes a step of measuring one or both of a relative dielectric constant and a dielectric loss of the piezoelectric element.
In this way, the relative dielectric constant or the dielectric loss of the piezoelectric element is measured, and the property of the actuator is evaluated based on the measured value.
In one embodiment, the inspection step includes a step of measuring a piezoelectric constant of the piezoelectric element.
In this way, the piezoelectric constant of the piezoelectric element is measured, and the property of the actuator is evaluated based on the measured value.
A method for manufacturing an ink jet head of the present invention is a method for manufacturing an ink jet head, the ink jet head including: a pressure chamber block including a common liquid chamber for storing an ink, a plurality of pressure chambers communicated to the common liquid chamber, and a plurality of nozzles respectively communicated to the pressure chambers; and a plurality of actuator blocks each including at least a piezoelectric element, and a first electrode and a second electrode for applying a voltage across the piezoelectric element, the plurality of actuator blocks being arranged on one surface of the pressure chamber block, wherein before attaching the actuator blocks to the pressure chamber block, each of the actuator blocks is inspected by the inspection method as described above.
Another method for manufacturing an ink jet head of the present invention includes: a step of producing a plurality of actuator forming members in each of which a first electrode, a piezoelectric element and a second electrode are deposited in this order on a substrate whose area is smaller than a pressure chamber plate, with a portion of the first electrode being exposed; an inspection step of inspecting a property of each piezoelectric element by contacting inspection probes to the exposed portion of the first electrode and the second electrode of each actuator forming member; a step of producing an actuator block on the substrate by depositing a vibration plate on the second electrode of each actuator forming member having undergone the inspection; a step of attaching each actuator block, together with the substrate, on one surface of the pressure chamber plate so that more than one of the pressure chambers provided in the pressure chamber plate are covered by the vibration plate of the actuator block; a step of removing each substrate; a step of patterning the first electrode of each actuator block; a step of attaching a channel plate on the other surface of the pressure chamber plate, the channel plate including therein an ink channel for guiding an ink from the pressure chambers to nozzles and a common liquid chamber; and attaching a nozzle plate including the nozzles therein to the channel plate.
Another method for manufacturing an ink jet head of the present invention includes: a step of producing a plurality of actuator forming members in each of which a first electrode, a piezoelectric element and a second electrode are deposited in this order on a substrate whose area is smaller than a pressure chamber plate, with a portion of the first electrode being exposed; an inspection step of inspecting a property of each piezoelectric element by contacting inspection probes to the exposed portion of the first electrode and the second electrode of each actuator forming member; a step of attaching each actuator forming member having undergone the inspection on one surface of the pressure chamber plate so that more than one of the pressure chambers provided in the pressure chamber plate are covered by the second electrode of the actuator forming member; a step of removing each substrate; a step of patterning the first electrode of each actuator forming member; a step of attaching a channel plate on the other surface of the pressure chamber plate, the channel plate including therein an ink channel for guiding an ink from the pressure chambers to nozzles and a common liquid chamber; and attaching a nozzle plate including the nozzles therein to the channel plate.
With a manufacturing method as described above, each actuator block is inspected before attaching a plurality of actuator blocks to the pressure chamber block by a transfer process, whereby it is possible to attach only the non-defective actuator blocks to the pressure chamber block by removing defectives in advance. Therefore, it is not necessary to waste some defectives along with non-defective actuator blocks after the attachment, thereby eliminating the waste of actuator blocks.
If the second electrode functions also as the vibration plate, it is possible to realize a cost reduction by reducing the number of components.
An ink jet recording apparatus of the present invention includes: an ink jet head as described above; and movement means for relatively moving the ink jet head and a recording medium with respect to each other in a scanning direction.
Another ink jet recording apparatus of the present invention includes: an ink jet head manufactured by a manufacturing method as described above; and movement means for relatively moving the ink jet head and a recording medium with respect to each other.
FIG. 36A and
Preferred embodiments of the present invention will now be described with reference to the drawings.
<Embodiment 1>
As illustrated in
The ink jet head 5 includes two line heads arranged next to each other in the scanning direction X, i.e., a first line head 1 and a second line head 2. The configuration of the line heads 1 and 2 will be described later.
The ink jet recording apparatus 90 includes a pair of carrier rollers 8 and 8 and a pair of feeding rollers 7 and 7, with the recording medium 9 being sandwiched between the feeding rollers 7 and 7 and between the carrier rollers 8 and 8. The carrier rollers 8 and 8 form movement means for relatively moving the ink jet head 5 and the recording medium 9 with respect to each other. The recording medium 9 is carried in the scanning direction X by the rotation of the carrier rollers 8 and 8.
A recording medium holding member 6 in the form of a flat plate is provided below the ink jet head 5. Note that the recording medium holding member 6 is not limited to a flat plate member but may alternatively be a cylindrical member, for example, as long as it keeps the recording medium 9 and the ink jet head 5 opposing each other with a constant interval therebetween. The recording medium 9 passes through between the ink jet head 5 and the recording medium holding member 6. The recording medium 9 is carried by the carrier rollers 8 and 8 while being sandwiched between the feeding rollers 7 and 7, and thus is placed under a tension by the rollers 7 and 8. In this way, the recording medium 9 forms a flat surface on the recording medium holding member 6 without being bent. Thus, ink droplets discharged from the ink jet head 5 land on the recording medium 9 with a high precision.
Note that although not shown, the recording medium 9 on the recording medium holding member 6 can be made even flatter by electrically attracting the recording medium 9 by giving an electrostatic charge to the recording medium holding member 6. Therefore, means for giving an electrostatic charge to the recording medium holding member 6 may be provided.
Next, the general configuration of the first line head 1 and the second line head 2 will be described with reference to
The actuator block 40 is provided with a piezoelectric element 30, being a perovskite-type dielectric thin film having a thickness of 0.5 μm to 8 μm and made of PZT (see FIG. 4). First electrodes 15 for providing potentials individually, lead sections 16 for supplying a voltage to the first electrodes 15, and input terminals 17 connected to an FPC 13 as a control plate, are arranged on the surface of each piezoelectric element 30. The first electrodes 15 and the lead sections 16 are made of a conductive material (e.g., Pt) having a thickness of about 0.1 μm.
As illustrated in FIG. 5 and
As illustrated in
Next, the configuration of the line heads 1 and 2 will be described in detail. Note however that since the first line head 1 and the second line head 2 are line heads of the same shape, only the first line head 1 will be described below, and the description of the second line head 2 will be omitted.
Note however that the alignment means 25 is not limited to physical means, but may be other means. For example, an alignment marker may be provided on each plate, and the plates may be aligned with one another using optical means.
As illustrated in
The ink supply port 19 and the ink channel inlet 20 are provided on the bottom surface of each pressure chamber 22. The ink supply port 19 communicates the common liquid chamber 18 and the pressure chamber 22 to each other. The inside of the common liquid chamber 18 is filled with an ink. The common liquid chamber 18, in its central portion thereof, diverges into two liquid chamber rows extending in the head longitudinal direction Y, and the two liquid chamber rows merge together at both ends thereof. The ink tube port 12 is provided in the end portions so that the ink is supplied through the ink tube ports 12 to the common liquid chamber 18.
First, a substrate 60 having a size of 20 mm×25 mm and made of MgO, Si, SUS, etc., is provided. In the present embodiment, an MgO substrate is used.
Then, as illustrated in
Then, as illustrated in
Then, as illustrated in
Then, as illustrated in
Then, as illustrated in
In the line heads 1 and 2 of the present embodiment, the nozzles 37, 37, . . . , are arranged at a small pitch for a high density in the head longitudinal direction Y. Therefore, when one attempts to arrange the substrate blocks 61 in a single row with no gap therebetween, even a slight error in the size or shape among the substrate blocks 61 or a slight error in the arrangement may result in the substrate blocks 61 and 61 overlapping each other. If such a contact between the substrate blocks 61 and 61 occurs, the yield lowers. In view of this, in the present embodiment, the two line heads 1 and 2 are shifted from each other in the head longitudinal direction by a distance that is one half of the pitch of the substrate blocks 61 so as to accommodate densely arranged nozzles. In this way, for the line heads 1 and 2 as a whole, the nozzles 37, 37, . . . , are arranged with a high density at a predetermined pitch in the head longitudinal direction Y, and the pressure chambers 22, 22, . . . , are also arranged with a high density in the head longitudinal direction Y. Moreover, the substrate blocks 61 are also arranged with no gap therebetween in the head longitudinal direction Y.
After the attachment of the substrate blocks 61 as described above, the substrate 60 is etched away by using an acidic solution, as illustrated in FIG. 7F.
Then, a mask (not shown) produced by an aligner with a high precision is positioned by using the alignment means 25 provided in the pressure chamber plate 21, after which the first electrode 15 is patterned so as to form the first electrodes 15 and the lead sections 16 in a predetermined shape, as illustrated in FIG. 7G. Thus, the first electrodes 15 and the lead sections 16 can be formed with a high precision by aligning the pressure chamber plate 21 and the mask with each other by using the alignment means 25.
Then, as illustrated in
Then, as illustrated in
Note that, in the present embodiment, the attachment process is performed in the following order: the pressure chamber plate 21→the channel plate 38→the nozzle plate 36. Alternatively, the pressure chamber plate 21 and the channel plate 38 may be attached to each other after attaching the channel plate 38 and the nozzle plate 36 to each other.
Moreover, in the present embodiment, the vibration plate 14 and the second electrode 50 are formed separately (see FIG. 4). However, in a case where the vibration plate 14 is made of a conductive material such as chrome, the vibration plate 14 may function also as the second electrode 50. Therefore, a second electrode and vibration plate 14 may be provided, as illustrated in
Moreover, a conductive material such as Cu or Ti may be provided as an intermediate layer between the piezoelectric element 30 and the vibration plate 14 for the purpose of improving the voltage endurance and increasing the attachment strength.
Moreover, the piezoelectric element 30 may be patterned and divided along with the first electrode 15, as illustrated in FIG. 9. In this way, the vibration plate 14 is more flexible so that a greater displacement can be obtained with the same voltage being applied.
Moreover, by patterning the first electrode 15 immediately after the formation of the first electrode 15 on the substrate 60 as illustrated in
Moreover, while the first electrode and the second electrode are the separate electrode and the common electrode, respectively, in the present embodiment, they may be reversed. That is, the first electrode and the second electrode may alternatively be the common electrode and the separate electrode, respectively.
Moreover, in the present embodiment, the pressure chambers 22, 22, . . . , of the pressure chamber rows 22A and 22B are arranged in a single row, as illustrated in FIG. 3. Alternatively, the pressure chambers 22, 22, . . . , may be arranged alternately in the head longitudinal direction Y, as illustrated in
According to the present embodiment, each actuator includes a plurality of actuator blocks 40, with a plurality of actuator blocks 40 being arranged for each pressure chamber block 41, whereby it is possible to reduce the size of each actuator block 40. Therefore, a transfer process can be effectively utilized.
Moreover, the ink jet head 5 includes the two line heads 1 and 2, in each of which the actuator blocks 40 are arranged so as to be spaced apart from one another, whereby it is possible to prevent the actuator blocks 40 and 40 from overlapping each other. On the other hand, for the line heads 1 and 2 as a whole, the actuator blocks 40 are arranged with no gap therebetween in the head longitudinal direction Y, whereby the actuators can be formed for all of the nozzles 37 and the pressure chambers 22.
Moreover, in the present embodiment, the first line head 1 and the second line head 2 are line heads of the same shape. Thus, the ink jet head 5 is provided by combining together a plurality of line heads of the same type. Therefore, it is not necessary to manufacture two types of line heads separately, whereby it is possible to suppress the manufacturing cost.
Moreover, if one of the line heads breaks down, only the line head can be replaced so that it is possible to continue to use the other line head, thereby reducing the maintenance cost as compared to a conventional head in which the entire head is replaced when a portion thereof breaks down.
As described above, according to the present embodiment, it is possible to achieve an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc.
<Embodiment 2>
The arrangement pattern of the actuator blocks 40, the pressure chambers 22, the nozzles 37, etc., in the line heads 51 and 52 is the same as that of Embodiment 1. In the present embodiment, one end of each of the line heads 51 and 52 is slightly extended in the head longitudinal direction Y, and the line heads 51 and 52 are aligned with each other in the scanning direction X at both ends thereof Due to the symmetric arrangement of the first line head 51 and the second line head 52, the actuator block 40 of one line head is located between the actuator blocks 40 and 40 of the other line head with respect to the head longitudinal direction Y. Moreover, the actuator block 40 of one line head partially overlaps with the actuator block 40 of the other line head with respect to the head longitudinal direction Y. Also in the present embodiment, the actuator blocks 40 are arranged in a staggered pattern for the ink jet head 5A as a whole.
Therefore, the present embodiment also provides effects as those of Embodiment 1. Furthermore, according to the present embodiment, the first line head 51 and the second line head 52 are aligned with each other at both ends thereof, thereby facilitating the attachment of the line heads 51 and 52.
<Embodiment 3>
As illustrated in
An ink jet head 55 includes a first head group 71 for discharging a black ink, a second head group 72 for discharging a cyan ink, a third head group 73 for discharging a magenta ink, and a fourth head group 74 for discharging a yellow ink. The first head group 71, the second head group 72, the third head group 73 and the fourth head group 74 are arranged in this order in the scanning direction X. Each of the first to fourth head groups 71 to 74 includes the first line head 1 and the second line head 2 and has a configuration as that of the ink jet head 5 of Embodiment 1. The ink tanks 11 storing a black ink, a cyan ink, a magenta ink and a yellow ink are connected to the first to fourth head groups 71 to 74, respectively, via the ink tubes 10.
The ink jet head 55 according to the present embodiment includes the plurality of head groups 71 to 74 for discharging inks of different colors, whereby effects as those of Embodiment 1 can be obtained with an ink jet recording apparatus that forms a color image.
Note that one or more of the first to fourth head groups 71 to 74 may be provided by using the first line head 51 and the second line head 52 of Embodiment 2. In such a case, effects as those of Embodiment 2 can be obtained with an ink jet recording apparatus that forms a color image.
<Embodiment 4>
As illustrated in
The ink jet head 62 of the present embodiment includes the first line head 63 and the second line head 64 having the same shape. The first line head 63 and the second line head 64 are arranged in the scanning direction X while being shifted from each other in the head longitudinal direction Y.
Each of the line heads 63 and 64 includes pressure chambers 22a for a black ink, pressure chambers 22b for a cyan ink, pressure chambers 22c for a magenta ink, and pressure chambers 22d for a yellow ink. For each color of ink, the pressure chambers 22a to 22d are arranged in a staggered pattern, and are arranged in the head longitudinal direction Y at a pitch of 600 dpi. The pressure chambers 22a to 22d for different color inks are arranged so as to be aligned with one another in the scanning direction X.
A common liquid chamber 18a for a black ink, a common liquid chamber 18b for a cyan ink, a common liquid chamber 18c for a magenta ink, and a common liquid chamber 18d for a yellow ink, are arranged in the scanning direction X. Each of the common liquid chambers 18a to 18d extends in the head longitudinal direction Y, and is provided with the ink tube port 12 at both ends thereof.
Each actuator block 40 covers a plurality of pressure chambers 22a to 22d. Specifically, the pressure chambers 22a to 22d for four colors are covered together by a single actuator block 40. Note that the arrangement pattern of the actuator blocks 40 is as that of Embodiment 1.
In the ink jet head 62 of the present embodiment, the pressure chambers 22a to 22d for four colors are covered by a single actuator block 40, whereby the pressure chambers can be arranged at a higher density. Moreover, it is possible to increase the number of actuators included in each actuator block 40. Therefore, it is possible to downsize the head, reduce the number of manufacturing steps, and reduce the cost.
Note that while the first line head 63 and the second line head 64 are shifted from each other in the head longitudinal direction Y in the present embodiment as in Embodiment 1, it is needless to say that the first line head 63 and the second line head 64 may alternatively be arranged in point symmetry with each other as in Embodiment 2.
<Embodiment 5>
In Embodiment 3, four sets of first and second line heads are provided, and inks of four colors of black, cyan, magenta and yellow are used. Alternatively, two, three, five or more sets of first and second line heads may be provided, and inks of two, three, five or more colors may be used.
Moreover, in Embodiment 4, pressure chambers for two, three, five or more colors may alternatively be provided for each line head, instead of providing pressure chambers for four colors.
Moreover, different types of inks of the same color may alternatively be used.
<Embodiment 6>
As illustrated in
Referring to FIG. 16 and
As illustrated in
The configuration of the actuator block 140 is substantially the same as that of the actuator block 40 of Embodiment 1, and therefore only the difference therebetween will be described below. Moreover, the configuration of the pressure chamber block 141 is substantially the same as that of the pressure chamber block 41 of Embodiment 1, and therefore only the difference therebetween will be described below.
As illustrated in
Specifically, a plurality of pressure chamber rows 122A to 122H are formed in the pressure chamber plate 121, each pressure chamber row including four pressure chambers 22 arranged in a direction that is inclined with respect to the head longitudinal direction Y. In other words, each of the pressure chamber rows 122A to 122H includes four pressure chambers 22 arranged in an upper right to lower left direction in FIG. 17. The pressure chamber rows 122A to 122H are arranged at a constant interval in the head longitudinal direction Y. Note that although only eight sets of pressure chamber rows 122A to 122H are shown in FIG. 16 and
A row direction R1 of each of the pressure chamber rows 122A to 122H is parallel to an inclined side H1 (see
The line heads 101 to 104 can be manufactured in a manner similar to that for the line head of Embodiment 1.
Also in the present embodiment, each actuator includes a plurality of actuator blocks 140, and a plurality of actuator blocks 140 are arranged for each pressure chamber block 141, whereby the size of each actuator block 140 can be reduced. Therefore, a transfer process can be effectively utilized. Thus, it is possible to achieve an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc.
Moreover, in the line heads 101 to 104 of the present embodiment, the nozzles 37, 37, . . . , are arranged at a small pitch for a high density in the head longitudinal direction Y, and the pressure chambers 22 are arranged at a minute interval in the head longitudinal direction Y so as to correspond to the nozzles 37. However, the pressure chambers 22 are not arranged in a single row in the head longitudinal direction Y, but are appropriately shifted from one another in the scanning direction X. Therefore, a large gap is ensured between the pressure chambers 22 next to each other along the same line in the head longitudinal direction Y according to the number of pressure chambers 22 that are shifted in the scanning direction X (three in the present embodiment).
The pressure chamber rows 122A to 122H are formed to be parallel to one another, thereby keeping an interval W (see
Therefore, it is not necessary to provide two rows of the actuator blocks 140 in the scanning direction, and it is possible to arrange the actuator blocks 140 in a single row for the pressure chamber block 141. Therefore, the length of the ink jet head 105 in the scanning direction X is reduced, and it is possible to downsize the head. Moreover, since the length in the scanning direction is short, the recording medium 9 is less likely to be bent. Therefore, the interval between the ink jet head 5 and the recording medium 9 is stabilized, and a stable recording operation can be performed.
<Embodiment 7>
As illustrated in FIG. 18 and
Also in the present embodiment, each pressure chamber 22 is formed in an elliptical shape, and the longitudinal direction L1 is perpendicular to the head longitudinal direction Y. The pressure chambers 22 are arranged while being appropriately shifted from one another in the scanning direction X, and as a whole arranged at a constant interval of 600 dpi (42.3 μm) in the head longitudinal direction Y.
Also in the present embodiment, a plurality of pressure chamber rows 122A to 122H are formed. In each of the pressure chamber rows 122A to 122H, the pressure chambers 22 are arranged in an upper left to lower right direction in
In the pressure chamber rows 122A to 122H of the present embodiment, at least two pressure chambers 22 included in each pressure chamber row are arranged at an interval (1200 dpi) twice as much as the constant interval (600 dpi). Specifically, where the pressure chambers included in each of the pressure chamber rows 122A to 122H are denoted as a first pressure chamber 221, a second pressure chamber 222, a third pressure chamber 223 and a fourth pressure chamber 224, the interval is 600 dpi between the second pressure chamber 222 and the third pressure chamber 223, while the interval is 1200 dpi between the first pressure chamber 221 and the second pressure chamber 222 and between the third pressure chamber 223 and the fourth pressure chamber 224 as illustrated in FIG. 19.
Moreover, at least one pressure chamber included in each pressure chamber row is provided between two pressure chambers included in another adjacent pressure chamber row with respect to the head longitudinal direction Y. For example, the fourth pressure chamber 224 of the pressure chamber row 122B is arranged between the first pressure chamber 221 and the second pressure chamber 222 of the pressure chamber row 122C with respect to the head longitudinal direction Y. Therefore, although there are pressure chambers arranged at an interval of 1200 dpi in each of the pressure chamber rows 122A to 122H, a pressure chamber of another pressure chamber row is located between such pressure chambers, whereby the pressure chambers are arranged at a constant interval of 600 dpi for the head as a whole.
Embodiment 7 provides the following effects in addition to those of Embodiment 6. In the present embodiment, the interval between the first pressure chamber 221 and the second pressure chamber 222 and between the third pressure chamber 223 and the fourth pressure chamber 224 in each pressure chamber row is 1200 dpi, which is twice as much as 600 dpi. Therefore, interference is less likely to occur between actuator sections for these pressure chambers, and crosstalk is less likely to occur. Thus, it is possible to improve the ink discharging performance.
<Embodiment 8>
As illustrated in
Also in the present embodiment, each pressure chamber 22 is formed in an elliptical shape. However, in the present embodiment, a longitudinal direction L3 of the pressure chamber 22 is not perpendicular to the head longitudinal direction Y and is inclined with respect to the scanning direction X.
As in Embodiment 6, the pressure chambers 22 are arranged while being appropriately shifted from one another in the scanning direction X, and arranged at a constant interval of 600 dpi in the head longitudinal direction Y.
Also in the present embodiment, a plurality of pressure chamber rows 122A to 122H are formed. In each of the pressure chamber rows 122A to 122H, the pressure chambers 22 are arranged at the constant interval. Moreover, the pressure chambers 22 and 22 located at ends of adjacent pressure chamber rows are also arranged at the constant interval.
A row direction R3 of the pressure chamber rows 122A to 122H is parallel to an inclined side H3 of the actuator block 140. Each actuator block 140 covers two pressure chamber rows.
Embodiment 8 provides the following effects in addition to those of Embodiment 6. In the present embodiment, the longitudinal direction L3 of the pressure chamber 22 is inclined with respect to the scanning direction X, whereby the interval between the pressure chambers 22 and 22 in the direction perpendicular to the longitudinal direction L3 is greater than that in Embodiment 6. Therefore, crosstalk is even less likely to occur. Conversely, if the interval between the pressure chambers 22 and 22 of Embodiment 8 is set to be substantially equal to the interval between the pressure chambers 22 and 22 of Embodiment 6, the pressure chambers 22 can be arranged at a higher density, thereby facilitating the downsizing of the head.
<Embodiment 9>
As illustrated in
Also in the present embodiment, each pressure chamber 22 is formed in an elliptical shape, and a longitudinal direction L4 thereof is inclined with respect to the scanning direction X. The pressure chambers 22 are arranged while being appropriately shifted from one another in the scanning direction X, and as a whole arranged at a constant interval of 600 dpi in the head longitudinal direction.
Also in the present embodiment, a plurality of pressure chamber rows 122A to 122H are formed. Note however that one of two adjacent pressure chamber rows includes three pressure chambers arranged therein while the other pressure chamber row includes four pressure chamber rows arranged therein. Specifically, each of the pressure chamber rows 122A, 122C, 122E and 122G includes three pressure chambers 22 arranged therein, while each of the pressure chamber rows 122B, 122D, 122F and 122H includes four pressure chambers 22 arranged therein.
In each of the pressure chamber rows 122A to 122H, the pressure chambers 22 are arranged in an upper left to lower right direction in
In the present embodiment, the pressure chambers of each pressure chamber row are arranged at an interval (1200 dpi) twice as much as the constant interval (600 dpi). Moreover, for adjacent pressure chamber rows, i.e., 122A and 122B, 122C and 122D, 122E and 122F, and 122G and 122H, a pressure chamber of one of the pressure chamber rows is arranged between pressure chambers of the other pressure chamber row. For example, the first pressure chamber 221 of the pressure chamber row 122A is located between the first pressure chamber 221 and the second pressure chamber 222 of the pressure chamber row 122B. With such an arrangement pattern, the pressure chambers 22 are arranged at a constant interval of 600 dpi for the head as a whole, despite that the pressure chambers are arranged at an interval of 1200 dpi in each pressure chamber row.
Moreover, since the longitudinal direction L4 of the pressure chambers 22 and the row direction R4 of the pressure chamber rows are parallel to each other in the present embodiment, the pressure chamber rows can be arranged closely with one another. In view of this, the pressure chamber rows 122A and 122B, 122C and 122D, 122E and 122F, and 122G and 122H, are arranged closely with each other. Conversely, as the pressure chamber rows in each pair are arranged closely with each other, the pressure chamber rows 122B and 122C, 122D and 122E, and 122F and 122G, are arranged relatively away from each other. In other words, in these pairs, the interval between the pressure chamber rows is greater than that of Embodiments 6 to 8.
Thus, in the present embodiment, two pressure chamber rows covered by each actuator block 140 are arranged closely with each other, whereby a side of the actuator block 140 (the side parallel to the head longitudinal direction Y) can be shortened. Therefore, it is possible to further downsize the actuator block 140. Moreover, the interval between the actuator blocks 140 and 140 (an interval W2 in
<Embodiment 10>
In the ink jet heads 105 of Embodiments 6 to 9, the independent line heads 101 to 104 for different colors are assembled together after alignment in the head longitudinal direction Y so as to align the landing positions of the different color inks with one another. In contrast, in an ink jet recording apparatus 190B according to the present embodiment, the line heads for different colors are integrated into an ink jet head 105B, as illustrated in FIG. 22 and FIG. 23. The pressure chambers 22 of different color inks are arranged on the pressure chamber plate 121B, and the different color inks are supplied to the same ink jet head 105B via the ink tubes 10.
As illustrated in
Where an ink jet head is formed by assembling the independent line heads 101 to 104, it is necessary to precisely align the line heads 101 to 104 with one another. However, according to the present embodiment, it is not necessary to assemble the line heads together. Thus, it is possible to reduce the number of manufacturing steps. Moreover, since a positional shift between the line heads will not occur, a shift in the landing position between different color inks is unlikely to occur.
Note that while the arrangement pattern of the pressure chambers 22 and the actuator blocks 140 in the present embodiment is as that of Embodiment 6, it is needless to say that any of the arrangement patterns of Embodiments 7 to 9 may alternatively be employed. Moreover, two or more of the arrangement patterns of Embodiments 6 to 9 may alternatively be combined together.
<Embodiment 11>
As illustrated in
Referring to FIG. 25 and
As illustrated in
More specifically, a first block row 340A and a second block row 340B are formed on the pressure chamber block 341. Each of the first block row 340A and the second block row 340B includes a plurality of actuator blocks 340, 340, . . . , arranged at a constant interval in the head longitudinal direction Y. The first block row 340A and the second block row 340B are arranged in the recording medium carrying direction (i.e., the scanning direction X). The actuator blocks 340 and 340 belonging to the same block row are spaced apart from one another in the head longitudinal direction Y. The actuator block 340 belonging to the first block row 340A and the actuator block 340 belonging to the second block row 340B are spaced apart from each other in the scanning direction X and are shifted from each other with respect to the head longitudinal direction Y. For example, the actuator block 340 of the first block row 340A is positioned between the actuator blocks 340 and 340 of the second block row 340B with respect to the head width direction Y.
The configuration of the actuator block 340 is substantially the same as that of the actuator block 40 of Embodiment 1, and therefore only the difference therebetween will be described below. Moreover, the configuration of the pressure chamber block 341 is substantially the same as that of the pressure chamber block 41 of Embodiment 1, and therefore only the difference therebetween will be described below.
As illustrated in
Specifically, a plurality of pressure chamber rows 322A, 322B, 322C and 322D are formed in the pressure chamber plate 321A, each pressure chamber row including four pressure chambers 22 arranged in a direction that is inclined with respect to the head longitudinal direction Y. In other words, each of the pressure chamber rows 322A to 322D includes four pressure chambers 22 arranged in an upper left to lower right direction in FIG. 26. The pressure chamber rows 322A and 322C are adjacent to the pressure chamber rows 322B and 322D, respectively, in the head longitudinal direction Y. On the other hand, the pressure chamber row 322B and the pressure chamber row 322C are shifted from each other in the scanning direction X. Next to the four pressure chamber rows 322A to 322D in the head longitudinal direction Y, another set of the pressure chamber rows 322A to 322D is arranged in a similar pattern. Note that although only two sets of pressure chamber rows 322A to 322D are shown in FIG. 25 and
The pressure chamber row 322B and the pressure chamber row 322C partially overlap with each other with respect to the head longitudinal direction Y. Specifically, one or more of the pressure chambers belonging to the pressure chamber row 322B and one or more of the pressure chambers belonging to the pressure chamber row 322C are located along the same line extending in the scanning direction X. For example, a pressure chamber 321 belonging to the pressure chamber row 322B and a pressure chamber 323 belonging to the pressure chamber row 322C are located along the same line in the scanning direction X. Moreover, a pressure chamber 322 belonging to the pressure chamber row 322B and a pressure chamber 324 belonging to the pressure chamber row 322C are also located along the same line in the scanning direction X.
Note that the pressure chamber row 322D and the pressure chamber row 322A also partially overlap with each other with respect to the head longitudinal direction Y.
The ink supply port 19 and the ink channel inlet 20 are provided on the bottom surface of each pressure chamber 22. The ink supply port 19 communicates the common liquid chamber 18 and the pressure chamber 22 to each other. The inside of the common liquid chamber 18 is filled with an ink. The common liquid chamber 18, in its central portion thereof, diverges into four liquid chamber rows extending in the head longitudinal direction Y, and the four liquid chamber rows merge together at both ends thereof. The ink tube port 12 is provided in the end portions so that the ink is supplied through the ink tube ports 12 to the common liquid chamber 18.
The ink channel inlet 20 is connected to the nozzle 37 via the ink channel 32 (not shown in FIG. 26). Therefore, the nozzles 37 are formed in the same pattern as the pressure chambers 22. As a result, although not shown, the nozzles 37 form a plurality of nozzle rows corresponding respectively to the pressure chamber rows 322A to 322D, and one or more of the nozzles of each nozzle row and one or more of the nozzles of another nozzle row are located along the same line in the scanning direction X.
Ink Discharging Method
Next, an ink discharging method will be described with reference to FIG. 27. In
Method for Manufacturing Ink Jet Head
The line heads 301 to 304 of the present embodiment can be manufactured in a manner similar to that for the line head of Embodiment 1. Then, the ink jet head 305 of the present embodiment is manufactured by assembling together the manufactured line heads 301 to 304.
Effects of the Embodiment
According to the present embodiment, one or more of the nozzles belonging to a nozzle row and one or more of the nozzles belonging to a different nozzle row are located along the same line in the scanning direction X, and ink droplets are discharged alternately from those nozzles, whereby it is possible to prevent a white streak from occurring even when there are some variations in size among ink dots.
As illustrated in
Moreover, according to the present embodiment, each actuator includes a plurality of actuator blocks 340, with a plurality of actuator blocks 340 being arranged for each pressure chamber block 341, whereby it is possible to reduce the size of each actuator block 340. Therefore, a transfer process can be effectively utilized, and it is possible to realize an improved uniformity of thin film actuators in terms of properties such as the piezoelectric property and the thickness, prevention of a crack occurring in the film, improvement in the manufacturing yield, downsizing of the manufacturing equipment, a cost reduction, etc.
<Embodiment 12>
As illustrated in
Each of the head blocks 301A and 302A includes one pressure chamber block 341, and a plurality of actuator blocks 340 attached to the pressure chamber block 341. In each of the head blocks 301A and 302A, the actuator blocks 340 are arranged at a predetermined interval in the head longitudinal direction Y, and the adjacent actuator blocks 340 are spaced apart from each other. The first head block 301A and the second head block 302A are shifted from each other in the head longitudinal direction Y so that the actuator block 340 of one head block is located between the actuator blocks 340 and 340 of the other head block with respect to the head longitudinal direction Y. The actuator blocks 340, 340, . . . , of the first head block 301A and the second head block 302A as a whole are arranged in a staggered pattern. The actuator block 340 of the first head block 301A and the actuator block 340 of the second head block 302A are spaced apart from each other with respect to the scanning direction X, but partially overlap with each other with respect to the head longitudinal direction Y. As a result of such an arrangement pattern, the actuator blocks 340 are as a whole in a continuous arrangement with no gap therebetween in the head longitudinal direction Y.
Also in the present embodiment, one or more of the pressure chambers of each of the pressure chamber rows 322A to 322D and one or more of the pressure chambers of another one of the pressure chamber rows 322A to 322D are located along the same line in the scanning direction X. An ink is discharged alternately from the nozzles corresponding to the pressure chamber 321 and the pressure chamber 323 located along the same line in the scanning direction X. Similarly, an ink is discharged alternately from the nozzles corresponding to the pressure chamber 322 and the pressure chamber 324.
Therefore, Embodiment 12 also provides effects as those of Embodiment 11. Moreover, in the present embodiment, if one of the first head block 301A and the second head block 302A breaks down, only the broken head block can be replaced so that it is possible to continue to use the other head block that is not broken. Therefore, it is not necessary to replace the entire line head, whereby it is possible to reduce the running cost and the maintenance cost.
<Embodiment 13>
As illustrated in FIG. 30 and
As illustrated in
Each actuator block 340 is formed in a parallelogram shape having a side that is parallel to the longitudinal direction of the pressure chamber block 341 (the same direction as the head longitudinal direction Y) and another side H1 that is inclined from the head longitudinal direction Y. The actuator blocks 340 are arranged at a predetermined interval in the head longitudinal direction Y, and adjacent actuator blocks 340 and 340 are spaced apart from each other.
The row direction R1 of each of the pressure chamber rows 322A to 322H is parallel to the inclined side H1 of each actuator block 340. Each actuator block 340 covers two pressure chamber rows.
Also in the present embodiment, a pressure chamber at an end of each of the pressure chamber rows 322A to 322H and a pressure chamber at an end of another one of the pressure chamber rows 322A to 322H are located along the same line in the scanning direction X. An ink is discharged alternately from nozzles corresponding to pressure chambers that are located along the same line.
Therefore, Embodiment 13 also provides effects as those of Embodiment 11.
Moreover, in Embodiment 13, the pressure chamber rows 322A to 322H are formed to be parallel to one another, thereby keeping an interval W (see
Therefore, it is not necessary to provide two rows of the actuator blocks 340 in the scanning direction, and it is possible to arrange the actuator blocks 340 in a single row for the pressure chamber block 341. Therefore, the length of the ink jet head 305 in the scanning direction X is reduced, and it is possible to downsize the head. Moreover, since the length in the scanning direction is short, the recording medium 9 is less likely to be bent. Therefore, the interval between the ink jet head 5 and the recording medium 9 is stabilized, and a high-quality recording operation can be performed.
<Embodiment 14>
As illustrated in
Referring to FIG. 33 and
As illustrated in
More specifically, a first block row 440A and a second block row 440B are formed on the pressure chamber block 441. Each of the first block row 440A and the second block row 440B includes a plurality of actuator blocks 440, 440, . . . , arranged at a constant interval in the head longitudinal direction Y. The first block row 440A and the second block row 440B are arranged in the recording medium carrying direction (i.e., the scanning direction X). The actuator blocks 440 and 440 belonging to the same block row are spaced apart from one another in the head longitudinal direction Y. The actuator block 440 belonging to the first block row 440A and the actuator block 440 belonging to the second block row 440B are spaced apart from each other in the scanning direction X. The actuator block 440 of the first block row 440A and the actuator block 440 of the second block row 440B are shifted from each other with respect to the head longitudinal direction Y. For example, the actuator block 440 of the first block row 440A is positioned between the actuator blocks 440 and 440 of the second block row 440B with respect to the head width direction Y.
The configuration of the actuator block 440 is substantially the same as that of the actuator block 40 of Embodiment 1, and therefore only the difference therebetween will be described below. Moreover, the configuration of the pressure chamber block 441 is substantially the same as that of the pressure chamber block 41 of Embodiment 1, and therefore only the difference therebetween will be described below.
As illustrated in
Specifically, a plurality of pressure chamber rows 422A, 422B, 422C and 422D are formed in the pressure chamber plate 421, each pressure chamber row including four pressure chambers 22 arranged in a direction that is inclined with respect to the head longitudinal direction Y. In other words, each of the pressure chamber rows 422A to 422D includes four pressure chambers 22 arranged in an upper left to lower right direction in FIG. 34. The pressure chamber rows 422A and 422C are adjacent to the pressure chamber rows 422B and 422D, respectively, in the head longitudinal direction Y. On the other hand, the pressure chamber row 422B and the pressure chamber row 422C are shifted from each other in the scanning direction X. Next to the four pressure chamber rows 422A to 422D in the head longitudinal direction Y, another set of the pressure chamber rows 422A to 422D is arranged in a similar pattern. Note that although only two sets of pressure chamber rows 422A to 422D are shown in FIG. 33 and
The ink supply port 19 and the ink channel inlet 20 are provided on the bottom surface of each pressure chamber 22. The ink supply port 19 communicates the common liquid chamber 18 and the pressure chamber 22 to each other. The inside of the common liquid chamber 18 is filled with an ink. The common liquid chamber 18, in its central portion thereof, diverges into four liquid chamber rows extending in the head longitudinal direction Y, and the four liquid chamber rows merge together at both ends thereof. The ink tube port 12 is provided in the end portions so that the ink is supplied through the ink tube ports 12 to the common liquid chamber 18.
Actuator Block Inspection Method
Next, inspection on the properties of the actuator block 440 will be described. The property inspection is performed during the manufacturing process of the ink jet head 405.
First, a substrate having a size of 20 mm×25 mm and made of MgO, Si, SUS, etc., is provided. In the present embodiment, an MgO substrate is used.
Then, as illustrated in
Then, as illustrated in
Next, as illustrated in
Note that the shape of the exposed portion 15A of the first electrode 15 is not limited to any particular shape. For example, the exposed portion 15A may be formed in an edge portion of the substrate 60 across the entire width thereof as illustrated in
As illustrated in
The electrical property evaluation is performed as illustrated in the flow chart of FIG. 38. Specifically, first, inspection probes 469 are pressed against the exposed portion 15A of the first electrode 15 and the second electrode 50 of the actuator forming member 466, as schematically illustrated in
Then, the relative dielectric constant ∈r is calculated using the measured value of the electrostatic capacity Cp (step ST12). The relative dielectric constant ∈r is calculated using Expression {circle around (1)} below.
Then, it is determined whether the relative dielectric constant ∈r and the dielectric loss tan δ meet their predetermined acceptable levels (step ST13). Specifically, it is determined whether the condition of relative dielectric constant ∈r≧250 and dielectric loss tan δ≦5[%] is satisfied. If the condition is satisfied, it is determined to be a non-defective (step ST14). If the condition is not satisfied, it is determined to be a defective (step ST15).
After the electrical property evaluation is completed, a mechanical property evaluation is performed. Note however that the mechanical property evaluation is performed by cutting off a portion of the actuator forming member 466 to be a sample 467 (see FIG. 41), and using the sample 467. Therefore, first, a portion of the actuator forming member 466, specifically a portion including the exposed portion 15A of the first electrode 15, is cut off (step ST3) prior to the mechanical property evaluation. For example, a portion of the actuator forming member 466 including the exposed portion 15A is cut off in a strip shape having a size of 20 mm×2 mm, and used as the sample 467.
The mechanical property evaluation is performed as illustrated in FIG. 40. First, as illustrated in
After the attachment of the silver paste 468, one of the inspection probes 469 is contacted to the second electrode 50 via the silver paste 468 while the other is contacted to the exposed portion 15A of the first electrode 15, and the piezoelectric constant d31 of the piezoelectric element 30 is detected under predetermined conditions (e.g., a sine wave whose measured frequency is 500 Hz and whose maximum applied voltage is 30 V or less is applied) (step ST22). The piezoelectric constant d31 is calculated using Expression {circle around (2)} below.
Then, it is determined whether the piezoelectric constant d31 meets a predetermined acceptable level (step ST23). Specifically, it is determined whether the condition of piezoelectric constant d31≧70[C/N] is satisfied. If the condition is satisfied, it is determined to be a non-defective (step ST24). If the condition is not satisfied, it is determined to be a defective (step ST25).
After the inspection as described above, any actuator forming member 466 that has been determined to be a defective in the electrical property evaluation or in the mechanical property evaluation is removed, and only the actuator forming members 466 that have been determined to be non-defectives both in the electrical property evaluation and in the mechanical property evaluation are used in the ink jet head manufacturing process to be described below.
Method for Manufacturing Ink Jet Head
A method for manufacturing an ink jet head according to the present embodiment is substantially the same as the manufacturing method of Embodiment 1, and the present manufacturing method also uses a so-called “transfer process”. Note however that in the ink jet head manufacturing method of the present embodiment, the inspection of actuator forming members 466 as described above is first performed and only the non-defective actuator forming members 466 are used, as described above. Specifically, after the inspection as described above, the vibration plate 14 made of chrome is formed on the second electrode 50 by an RF sputtering method, and thereafter a line head is produced in a manner similar to that of Embodiment 1 (see
Then, the thus produced four line heads are assembled together to obtain the ink jet head 405 that discharges inks of four colors.
Effects of the Embodiment
As described above, according to the present embodiment, the electrical property and the mechanical property of the actuator blocks 440 are inspected before the actuator blocks 440 are transferred onto the pressure chamber block 441, whereby it is possible to remove defectives having poor properties in advance. Therefore, it is possible to manufacture an ink jet head after removing defectives in advance, whereby it is possible to improve the reliability of the ink jet head. Moreover, it is possible to improve the yield of the ink jet head.
Particularly, in the present embodiment, a plurality of actuator blocks 440 are provided for one pressure chamber block 441, whereby it is possible to downsize each actuator block 440 and to manufacture the line heads 401 to 404 by a transfer process using such actuator blocks. Therefore, many actuator blocks 440 will be used. However, since the inspection as described above is performed, it is possible to remove defective actuator forming members 466 while utilizing the other non-defective actuator forming members 466. In a conventional line head, one actuator block was provided for one pressure chamber block 441, whereby if any of the actuator blocks was defective, it was necessary to waste all the actuator blocks including normal ones. However, according to the present embodiment, only the defectives can be wasted, thereby eliminating the waste of materials.
In the mechanical property evaluation, the silver paste 468 is attached to the second electrode 50, and the inspection probe 469 is contacted to the second electrode 50 via the silver paste 468, whereby it is possible to ensure the electrical contact between the inspection probe 469 and the second electrode 50 by lightly contacting the inspection probe 469 to the second electrode 50. Therefore, the pressing force by the inspection probe 469 is reduced, whereby the influence of the pressing force of the inspection probe 469 can be minimized, and it is thus possible to perform the property evaluation accurately.
Variations
Note that the present embodiment employs a mask deposition method for manufacturing the actuator forming member 466, in which the piezoelectric element 30 and the second electrode 50 are formed using a mask so that a portion of the first electrode 15 becomes the exposed portion 15A. However, the method for producing the actuator forming member 466 is not at all limited to the method described above.
For example, as illustrated in
Moreover, as illustrated in
While the first electrode and the second electrode are the separate electrode and the common electrode, respectively, in the embodiments described above, they may be reversed. That is, the first electrode and the second electrode may alternatively be the common electrode and the separate electrode, respectively. Alternatively, the inspection may be performed by pressing the inspection probes 469 against the separate electrode 50 and the first electrode (common electrode) 15 after patterning the second electrode to form the separate electrode 50, as illustrated in FIG. 45.
Also in the electrical property evaluation, the actuator forming member 466 itself may be evaluated by cutting off a portion of the actuator forming member 466 as a sample and evaluating the relative dielectric constant and the dielectric loss of the sample. Moreover, also in the electrical property evaluation, the inspection probe 469 may be contacted to the electrode indirectly via a conductive paste material instead of contacting it directly to the electrode.
The present invention is not limited to the embodiments set forth above, but may be carried out in various other ways without departing from the sprit or main features thereof.
Thus, the embodiments set forth above are merely illustrative in every respect, and should not be taken as limiting. The scope of the present invention is defined by the appended claims, and in no way is limited to the description set forth herein. Moreover, any variations and/or modifications that are equivalent in scope to the claims fall within the scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
2001-021052 | Jan 2001 | JP | national |
2001-021067 | Jan 2001 | JP | national |
2001-023018 | Jan 2001 | JP | national |
2001-023024 | Jan 2001 | JP | national |
This application is a divisional of U.S. patent application Ser. No. 10/057,279 filed on Jan. 25, 2002. The disclosure(s) of the above application(s) is (are) incorporated herein by reference. This application also claims the benefit of Japanese Patent Application Nos. 2001-021052 filed Jan. 30, 2001; 2001-021067 filed Jan. 30, 2001; 2001-023018 filed Jan. 31, 2001; and 2001-023024 filed Jan. 31, 2001. The disclosure(s) of the above application(s) are incorporated herein by reference.
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6705702 | Gunther et al. | Mar 2004 | B2 |
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Number | Date | Country |
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10286953 | Oct 1998 | JP |
Number | Date | Country | |
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20050024428 A1 | Feb 2005 | US |
Number | Date | Country | |
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Parent | 10057279 | Jan 2002 | US |
Child | 10918823 | US |