The present invention relates to an ink-jet head that discharges a liquid and a manufacturing method thereof, and an ink-jet recording apparatus.
In recent years, various technologies have been actively studied whereby luminous elements or filters used in displays or the like, and also microlenses or the like, are formed directly by discharging various liquids using ink-jet technology.
With such a technology whereby a device is created using ink-jet technology, performance requirements with respect to the ink-jet head are more stringent than hitherto.
One aspect of performance required of the ink jet head is impact positioning of ink drops discharged from a nozzle.
Various proposals have hitherto been made as methods of improving the impact positioning capability of the ink-jet head (see Patent Document 1 and Patent Document 2, for example).
An ink-jet head described in Patent Document 1 is equipped with a nozzle pipe provided with a nozzle that discharges ink at its tip, a piezoelectric element attached to the nozzle pipe, a head unit that holds the nozzle pipe and piezoelectric element, and a head case in which a plurality of head units are provided.
A head unit is configured so as to be freely attachable to and removable from the head case. A head unit and head case are aligned while observing the nozzle position of the tip of the nozzle pipe by means of a magnifying glass, and after alignment, are fixed by means of a screw, adhesive, or the like.
By means of this method, an ink-jet head can be provided that offers good alignment precision of a plurality of nozzles.
Meanwhile, an ink-jet recording apparatus described in Patent Document 2 improves ink drop rectilinearity and reduces satellite occurrence through a contrivance of the waveform that passes through the ink-jet head, and thereby improves impact positioning capability.
In addition to these systems, ink-jet heads have been proposed that achieve good impact positioning capability through improvement of nozzle processing precision, such as the nozzle shape and the spacing of nozzles (hereinafter referred to as “nozzle pitch”), improvement of the precision of alignment of a nozzle and pressure chamber, water-repellent film formation on the nozzle plate, and so forth,
Patent Document 1: Japanese Patent Application Laid-Open No. SHO 63-74645
Patent Document 2: Japanese Patent Application Laid-Open No. HEI 9-226106
Problems to be Solved by the Invention
With a conventional ink-jet head, normally an operation whereby ink is sucked from a nozzle is necessary when the head is first filled with ink, and later, when an operation is performed to remove contaminating air bubbles inside the ink-jet head.
The usual method of sucking ink from a nozzle is as follows. The nozzle part is cut off from the atmosphere by a cap that seals the nozzle part, and then air inside the cap is sucked out by means of a pump, negative pressure is created inside the cap, and ink is sucked from the nozzle.
However, with an above-described conventional ink-jet head, the area of the tip of a nozzle is extremely small, and it is very difficult to seal this part with a cap.
A possible method of sealing the nozzle part is to seal nozzle parts across a plurality of nozzles by means of a cap.
However, with an above-described conventional ink-jet head, no contrivance of any kind is provided for suction by means of a cap among a plurality of nozzles, and therefore when a cap is fitted and suction is performed by a pump, air seeps in from gaps between the nozzles, a sufficient degree of negative pressure cannot be achieved inside the cap, and suction of ink inside the ink jet head cannot be performed satisfactorily.
On the other hand, this kind of ink-jet head requires higher impact positioning capability in line with higher device densities, and higher impact positioning capability is also required of an above-described conventional ink-jet head.
However, with an above-described conventional ink-jet head, although considerable improvements have been made in impact positioning capability, consideration has not been given to cases in which the temperature changes.
Therefore, with an above-described conventional ink-jet head, nozzle pitch varies due to thermal expansion and contraction caused by ink-jet head temperature changes, and the desired impact positioning capability cannot be attained.
To avoid such thermal expansion and contraction due to ink-jet head temperature changes, it is desirable to maintain a constant environmental temperature at which an ink-jet recording apparatus is used, and prevent the temperature of the ink-jet head from changing.
However, a method whereby the environmental temperature at which an ink-jet recording apparatus is used is kept constant is not a satisfactory method since it entails large-scale equipment
For this kind of ink-jet recording apparatus, a method has been proposed that makes it possible to for highly viscous ink to be discharged by having the ink-jet head actively heated to, and maintained at, a predetermined temperature, raising the temperature of ink in the ink-jet head, and lowering the viscosity of the ink.
With this type of ink-jet recording apparatus, ink-jet head temperature changes are greater, and nozzle pitch variations are also large, so that it is necessary to consider the effect of nozzle pitch variations on impact positioning capability.
It is an object of the present invention to provide an ink jet head capable of performing ink suction from a nozzle dependably when an ink jet head provided with a plurality of ink discharge units is filled with ink, and when a recovery operation is performed in the event of a discharge defect, and a manufacturing method thereof, together with an ink-jet recording apparatus with good ink drop impact positioning capability capable of constantly maintaining the nozzle pitch of the ink-jet head at a desired value.
Means for Solving the Problems
An ink-jet head of the present invention employs a configuration that includes: a nozzle plate in which a nozzle that discharges ink is formed; a pressure application section that applies pressure to ink; a nozzle plate holding member that holds the nozzle plate; a head plate that holds a plurality of ink discharge units composed of at least said nozzle plate and said pressure application section and said nozzle plate holding member; a sealing member that seals a gap between said ink discharge unit and said head plate so that air does not pass through and supports said ink discharge unit movably with respect to said head plate by itself being deformed; and a fixing member that fixes said ink discharge unit and said head plate after the gap between said ink discharge unit and the head plate is sealed by the sealing member, and alignment of said ink discharge unit with said head plate is performed.
An ink-jet head manufacturing method of the present invention is a manufacturing method of the ink-jet head wherein alignment of the ink discharge unit and the head plate is performed while discharging an ink drop from the ink discharge unit and observing a state of flight of an ink drop discharged from the ink discharge unit.
An ink-jet recording apparatus of the present invention employs a configuration that includes the ink-jet head, and a nozzle pitch detection section that detects spacing of said nozzles of said ink-jet head.
Advantageous Effect of the Invention
According to an ink-jet head and manufacturing method thereof of the present invention, ink suction from a nozzle can be performed dependably when an ink-jet head provided with a plurality of ink discharge units is filled with ink, and when a recovery operation is performed in the event of a discharge defect. Also, according to an ink-jet recording apparatus of the present invention, the nozzle pitch of the ink-jet head can be maintained constantly at a desired value, and an improvement in ink drop impact positioning capability can be achieved.
Embodiments of the present invention will now be described with reference to the accompanying drawings.
As shown in
In
Wall member 3 is of stainless material, and has a φ 200 μm cylindrical hole forming a pressure chamber 6 formed approximately in its center. The exit-side surface of wall member 3 is joined to the entry-side surface of nozzle plate 1.
Elastic member 4 is of approximately 10 μm thick rubber material such as silicone rubber, fluororubber, or the like. Elastic member 4 is formed on the top surface of wall member 3 where there is no hole by means of spin-coating, casting, or the like.
Diaphragm 5 is of stainless material, and is pressed against elastic member 4 by being pushed down by reserve fluid chamber structure 8. Diaphragm 5 has a projecting section on the part opposite pressure chamber 6 on the elastic member 4 side, and the thrust of the elastic member 4 is concentrated in this projecting section. Thus, diaphragm 5 improves the sealing performance of pressure chamber 6 by increasing the contact pressure against elastic member 4. Diaphragm 5 is provided with an ink supply aperture 7 forming a passage between pressure chamber 6 and a reserve fluid chamber 9.
After elastic member 4 has been formed on the top surface of wall member 3 where there is no hole, pressure chamber 6 is formed by covering a through-hole bored to the same extent in elastic member 4 and wall member 3 by means of laser processing, drilling, or the like, from the elastic member 4 side by nozzle plate 1 and diaphragm 5.
Reserve fluid chamber structure 8 is placed in contact with diaphragm 5 so as to cover ink supply aperture 7, and forms reserve fluid chamber 9 with diaphragm 5. Reserve fluid chamber 9 is linked to an ink supply section (not shown).
An electrode (not shown) is formed on piezoelectric element 10 so that an electrical field is applied. A pressure application section is configured by means of this piezoelectric element 10 and diaphragm 5.
Nozzle plate holding member 11 displaces diaphragm 5 toward wall member 3 via reserve fluid chamber structure 8 by suppressing movement of piezoelectric element 10 in the upward direction in
As shown in
Next, an ink discharge operation of ink discharge unit 12 will be described.
First, ink filling is performed as follows: ink supply section (not shown)→reserve fluid chamber 9→ink supply aperture 7→pressure chamber 6→nozzle 2.
Next, when a predetermined voltage is applied to piezoelectric element 10, piezoelectric element 10 expands in the vertical direction in
Therefore, reserve fluid chamber structure 8 and diaphragm 5 move toward wall member 3 while compressing elastic member 4. Through this movement, the volume of pressure chamber 6 decreases, pressure is applied to the ink held inside pressure chamber 6, and ink is discharged from nozzle 2.
Then, when application of an electrical field to piezoelectric element 10 is canceled, expanding piezoelectric element 10 returns to its original state, and the volume of pressure chamber 6 returns to normal. At this time, ink is added to pressure chamber 6 from ink supply aperture 7, and preparations for the next ink discharge are completed.
With this ink discharge unit 12, ink was actually discharged and the droplet quantity and discharge speed were measured. When using ink with a viscosity of 50 cP, the discharge quantity was 0.3 picoliter, and the discharge speed was 8 m/sec.
Also, with this ink discharge unit 12, the voltage applied to piezoelectric element 10 was varied by ±30%, and variation of the ink drop discharge direction was observed. The result of the observation was that, within a range in which satisfactory ink drops are formed, there was no variation whatever in the ink drop discharge direction.
With a conventional ink-jet head, the discharge direction often changes slightly when the voltage applied to piezoelectric element 10 is varied. The main reason for this is that, when a voltage is applied to ink in pressure chamber 6 and nozzle 2, the pressure distribution of ink in pressure chamber 6 and nozzle 2 varies according to the magnitude of the pressure.
In contrast, in ink discharge unit 12 used in an ink-jet head of this example, the direction of relative movement of diaphragm 5 is virtually parallel to the discharge direction of an ink drop discharged from nozzle 2.
Consequently, with ink discharge unit 12 used in an ink-jet head of this example, pressure distribution in pressure chamber 6 and nozzle 2 is not prone to vary, and it has been made possible to implement a configuration whereby there is no variation in the ink drop discharge direction even if the voltage applied to piezoelectric element 10 is varied.
Next, the configuration of an ink-jet head of this example provided with a plurality of ink discharge units 12 configured in this way will be described.
As shown in
In
Each ink discharge unit 12 is positioned so that its nozzle plate 1 is in close contact with the stepped part of the corresponding recess in head plate 13
The gaps between ink discharge units 12 and recesses in head plate 13 are sealed by means of sealing members 14. Sealing members 14 should preferably be of an elastic, highly airtight material such as silicone rubber, fluororubber, or some other rubber material, for example.
Sealing members 14 in ink-jet head 100 of this example may also be formed so as to fit between nozzle plate 1 of each ink discharge unit 12 and head plate 13.
As shown in
The same kind of material as the ink-repellent film (not shown) formed on nozzle plate 1 of ink discharge unit 12 can be used satisfactorily as the material of ink-repellent film 15.
Ink-repellent film 15 on ink jet head 100 of this example is formed on both the surface of head plate 13 from which ink drops are discharged, and the wall surface of the aperture part through which ink drops pass.
Next, an operation such as ink filling in ink-jet head 100 of this example will be described
As shown in
In
Filling ink discharge units 12 of ink-jet head 100 with ink and so forth is performed by sucking air from inside tube 17 by means of the suction pump while suction cap 16 is tightly adhering to head plate 13.
In ink-jet head 100, since gaps between ink discharge units 12 and the recesses in head plate 13 are sealed by sealing members 14, air does not leak from these gaps when suction is performed by the suction pump.
Therefore, with ink-jet head 100 of this example, negative pressure inside suction cap 16 can be increased satisfactorily, and ink filling and so forth can be carried out satisfactorily.
Next, the state will be described after an ink filling operation has been performed when ink-repellent film 15 has not been formed on head plate 13.
The result of an ink filling experiment conducted when ink-repellent film 15 had not been formed on head plate 13 was that, as shown in
With this kind of ink-jet head, if ink blobs 18 formed on head plate 13 impinge on nozzle 2 of an ink discharge unit 12, an ink drop discharge defect will occur.
With this kind of ink-jet head, even if ink blobs 18 do not impinge on nozzle 2, hardening or increased viscosity will occur when ink blobs 18 dry, and if these should clog nozzle 2 for some reason, blockage of nozzle 2 will occur, and ink drop discharge will be prevented.
In contrast, with ink-jet head 100 of this example, since ink-repellent film 15 is formed on head plate 13 as shown in
Next, the manufacturing method of ink-jet head 100 of this example will be described.
In
Screw-holes 20 are formed in head plate 13, and leaf springs 19 are fixed to head plate 13 by means of screws 21.
By this means, ink discharge unit 12 is fixed to head plate 13 so that its nozzle plate 1 is positioned on the ink discharge surface side.
Silicone rubber used for sealing member 14 is formed in (fills) the gap between ink discharge unit 12 and head plate 13 after ink discharge unit 12 is fixed to head plate 13 with screws 21.
With ink-jet head 100 of this example, since ink discharge unit 12 is fixed to head plate 13 with screws 21, and sealing member 14 is formed from elastic silicone rubber, ink-jet head 100 has a structure that allows ink discharge unit 12 to be removed from head plate 13.
Next, the method of aligning ink discharge unit 12 with head plate 13 will be described.
In
Above the path of movement of receiving body 23, a camera 25 is positioned in order to observe the recorded image of ink drop 22 formed on receiving body 23,
Ink discharge unit 12 of ink-jet head 100 is sandwiched between a pair of levers 26a and 26b. One lever 25a is supported in a movable fashion by a micrometer 27, and the other lever 26b is supported in a movable fashion via a spring 28.
In this way, ink discharge unit 12 is supported so as to be able to be fixed in a desired position by means of lever 26a, lever 26b, micrometer 27, and spring 28. Although not shown in the figure in order to simplify the explanation, a set of lever 26a, lever 26b, micrometer 27, and spring 28 is also provided in a direction perpendicular to the direction of the row of ink discharge units 12, and movement of ink discharge unit 12 is also possible in this direction.
To perform alignment of ink discharge unit 12 with head plate 13, first, screws 21 shown in
Next, movable stage 24 is moved to a position in which the recorded image of ink drop 22 formed on receiving body 23 can be observed by camera 25, as shown in
To correct this amount of displacement, screws 21 are loosened so that ink discharge unit 12 can be moved, micrometer 27 is rotated and the position of ink discharge unit 12 relative to head plate 13 is shifted, and then screws 21 are tightened again.
By repeating this procedure, alignment of ink discharge unit 12 with head plate 13 can be performed satisfactorily.
As ink discharge unit 12 sealing member 14 is formed from elastic silicone rubber, movement of ink discharge unit 12 is facilitated when moved relative to head plate 13, and a sealed state can be maintained after the move.
Ink drops 22 were actually discharged using an ink jet head 100 equipped with five ink discharge units 12, and the impact positions of ink drops 22 on receiving body 23 were measured.
The results showed that the situation regarding impact on receiving body 23 with this method of aligning ink discharge units 12 with head plate 13 is extremely good, and it was possible to implement an ink-jet head 100 with an error from the desired impact position of ±5 μm.
As described above, in ink-jet head 100 of this example, air can be prevented from passing through gaps between ink discharge units 12 and head plate 13 by sealing those gaps with sealing members 14.
Therefore, with ink-jet head 100 of this example, it is possible for adequate negative pressure to be applied to ink inside ink discharge unit 12 by sucking air from nozzle 2 while suction cap 16 is not in direct contact with nozzle plate 1 but is in contact with head plate 13.
Consequently, with ink-jet head 100 of this example, filling of ink discharge unit 12 with ink, and recovery in the event of a discharge defect caused by nozzle 2 of ink discharge unit 12, can be performed satisfactorily, and stable ink discharge is possible.
In ink-jet head 100 of this example, ink discharge unit 12 is supported so as to be able to move relative to head plate 13 through the deformation of sealing member 14 made of an elastic material.
Therefore, with ink-jet head 100 of this example, it is possible to move ink discharge unit 12 by a small amount relative to head plate 13 while a sealed state is maintained even after sealing member 14 is formed.
In ink-jet head 100 of this example, ink discharge unit 12 is fixed to head plate 13 in an attachable and removable fashion.
Therefore, with ink-jet head 100 of this example, even after alignment has once been performed, it is possible to carry out removal and realignment.
With ink-jet head 100 of this example, it is possible to replace ink discharge unit 12 if an ink drop 22 discharge defect or ink drop 22 non-discharge occurs.
Thus, ink-jet head 100 of this example enables flexibility at the time of assembly, and maintainability, to be improved.
With ink-jet head 100 of this example, since ink repellence processing has been performed by means of ink-repellent film 15 on the surface of head plate 13 on the side on which ink is discharged, ink tends not to adhere in the vicinity of head plate 13 and nozzle 2.
Consequently, with ink-jet head 100 of this example, it seldom happens that ink adhering to and coagulating on head plate 13 moves to nozzle 2 and causes blockage of nozzle 2, and ink can be discharged in a stable fashion.
With ink-jet head 100 of this example, since ink repellence processing has also been performed by means of ink-repellent film 15 on an aperture part of head plate 13 through which ink drops 22 pass, ink also tends not to adhere to the wall surface of an aperture part of head plate 13, and ink can be discharged in a stable fashion.
A pressure application section in ink-jet head 100 of this example is composed of diaphragm 5 that moves relative to nozzle plate 1 and piezoelectric element 10 that drives diaphragm 5, and the direction of relative movement of diaphragm 5 is virtually parallel to the discharge direction of an ink drop 22 discharged from nozzle 2.
Since ink-jet head 100 of this example uses piezoelectric element 10 in the pressure application section in this way, flexibility with regard to ink selection is improved.
With ink-jet head 100 of this example, since the direction of oscillation of diaphragm 5 is virtually parallel to the ink drop 22 discharge direction, variation of the rectilinearity of an ink drop 22 can be kept small even if the intensity of the pressure applied to the ink is changed, for instance.
In the manufacturing method of ink-jet head 100 of this example, an ink drop 22 is discharged from ink discharge unit 12 onto receiving body 23, and alignment of ink discharge unit 12 and head plate 13 is carried out while observing the impact position of discharged ink drop 22 with camera 25.
Thus, in the manufacturing method of ink-jet head 100 of this example, since alignment of ink discharge unit 12 and head plate 13 is carried out while confirming the final impact position of an ink drop 22 on receiving body 23 with camera 25, ink drop 22 impact position error can be made extremely small.
In ink-jet head 100 of this example, the use of a single-layer piezoelectric element 10 has been shown as an example, but a laminated configuration may also be used for piezoelectric element 10.
A so-called electrostatic actuator using electrostatic force, or a magnetostrictor using magnetic force, may also be used as a pressure application section.
In ink-jet head 100 of this example, discharge of ink drops 22 from nozzle 2 of ink discharge unit 12 has been described as an example, but the liquid discharged from nozzle 2 of ink discharge unit 12 need not be a liquid containing a black or colored coloring material for creating text or a photograph on recording paper, and, for example, a liquid containing electrically conductive particles for electrode formation, a luminescent material used for EL (electroluminescence), a resinous material for creating microlenses, and so forth, can also be used satisfactorily.
With ink-jet head 100 of this example, a configuration in which each ink discharge unit 12 is equipped with one nozzle 2 has been described as an example, but the number of nozzles 2 need not necessarily be one. However, when particular importance is placed on variance of ink drop 22 impact positions, the fewer nozzles 2 there are, the better.
Next, the manufacturing method of an ink-jet head according to Embodiment 2 of the present invention will be described.
In the manufacturing method of ink-jet head 100 of this example, the method of observing the state of flight of an ink drop 22 when discharged from an ink discharge unit 12 differs from that in the manufacturing method of ink-jet head 100 according to Embodiment 1.
As shown in
Then, in the manufacturing method of ink-jet head 100 of this example, the state of flight of an ink drop 22 is observed by observing the shadow of ink drop 22 by means of camera 25.
By confirming the state of flight of an ink drop 22 as described above in the manufacturing method of ink-jet head 100 of this example, it is possible to obtain not only the result after the impact of ink drop 22 on receiving body 23, but also information such as the ink drop 22 satellite occurrence situation, discharge speed, flight direction, and so forth.
In the ink-jet head 100 manufacturing method shown in
When ink drop 22 is aligned with head plate 13, 3-directional (3-dimensional) alignment is normally essential, but with ink-jet head 100 of this example, since nozzle plate 1 is in intimate contact with head plate 13, with regard to the discharge direction of ink drop 22, it is sufficient to perform alignment in the remaining two directions parallel to head plate 13.
Thus, in the manufacturing method of ink-jet head 100 of this example, the first ink drop 22 discharge direction is observed by the camera 25a/LED 29a pair, and the second ink drop 22 discharge direction is observed by the camera 25b/LED 29b pair.
A method whereby the ink drop 22 discharge direction is observed from two directions—parallel to and perpendicular to the direction of the row of ink discharge units 12—using two pairs of cameras 25a and 25b and LEDs 29a and 29b in this way has traditionally been generally employed.
However, since cameras have a focal length, as is commonly known, if the length of head plate 13 in the direction of the row of ink discharge units 12 is greater than the focal length of the cameras, it is not possible to position camera 25b and LED 29b in a direction parallel to the direction of the row of ink discharge units 12.
Thus, as shown in
Thus, in the manufacturing method of ink-jet head 100 of this example, the discharge direction of an ink drop 22 is observed from two directions by means of camera 25a positioned Perpendicular to the direction of the row of ink discharge units 12, and camera 25b positioned at an angle to the direction of the row of ink discharge units 12.
Therefore, in the manufacturing method of ink-jet head 100 of this example, the focal length of camera 25b does not exceed the length of head plate 13 in the direction of the row of ink discharge units 12, and good alignment between an ink discharge unit 12 and head plate 13 is possible.
As described above, in the manufacturing method of ink-jet head 100 of this example, alignment of an ink discharge unit 12 with head plate 13 is performed while discharging ink drops 22 from ink discharge unit 12.
Therefore, with the manufacturing method of ink-jet head 100 of this example, the final impact position of an ink drop 22 can be confirmed, and it is also possible to perform alignment of ink discharge unit 12 with respect to head plate 13 while confirming the state of flight, including the satellite occurrence situation, discharge speed, and so forth.
Thus, with the manufacturing method of ink-jet head 100 of this example, it is possible to prevent the installation on head plate 13 of an ink discharge unit 12 whose ink drop 22 discharge status is defective or unstable, and to obtain an ink-jet head 100 with more stable ink drop 22 impact positioning capability.
In the manufacturing method of ink-jet head 100 of this example, camera 25a and LED 29a may also be positioned at an angle to the direction of the row of ink discharge units 12.
Next, the configuration of an ink-jet head according to Embodiment 3 of the present invention will be described.
As shown in
For the sake of clarity, ink-jet head 200 of this example is shown in
The method of fixing ink discharge units 12 to head plate 13 in ink-jet head 200 of this example is similar to that in ink-jet head 100 according to Embodiment 1, and therefore a description thereof will be omitted here.
The method of aligning an ink discharge unit 12 with head plate 13 in ink-jet head 200 of this example is also similar to that in ink-jet head 100 according to Embodiment 1, and therefore a description thereof will be omitted here.
Next, the general configuration of an ink jet recording apparatus that uses ink-jet head 200 of this example will be described.
Inink-jet recording apparatus 300 shown in
In
Heater 30 generates heat through the passage of electric current, and a plane heater that is in contact with the surface of head plate 13 is used to facilitate the transfer of heat to head plate 13. Heater 30 may also be embedded in head plate 13 to further improve heat transfer.
Heater 30 heats and maintains the temperature of head plate 13 in accordance with the temperature detected by thermistor 31 fitted to head plate 13, and by this means ink discharge units 12 are heated to and maintained at a desired temperature.
Next, the operation of ink-jet recording apparatus 300 of this example will be described.
In ink-jet recording apparatus 300 of this example, first, current is passed through heater 30 in accordance with the temperature detected by thermistor 31, and head plate 13 is heated to and maintained at the desired temperature.
That is to say, as shown in
With ink-jet recording apparatus 300 of this example, aluminum is used for head plate 13, and its coefficient of linear thermal expansion is 23.9×10E−6/° C.
Therefore, when the temperature of head plate 13 rises by 20° C. from a reference temperature, for example, the nozzle pitch increases by 0.0478%. That is to say, since the distance between both ends of the row of nozzles 2 is 25.4 mm, that distance increases by 12 μm, and the impact position error is considerable.
Thus, with ink-jet recording apparatus 300 of this example, if the temperature of head plate 13 during use is designated T1, and the desired nozzle pitch at that temperature is designated P1, ink-jet head 200 is made so that at a temperature lower than T1—for example, T2—the nozzle pitch is P2.
Also, with ink-jet recording apparatus 300 of this example, temperature T1 during use is made higher than the temperature inside the apparatus and the operating environment temperature. That is to say, it is sufficient to provide a heating section for making the head plate 13 temperature T1, and a cooling section is not necessary.
Therefore, in ink-jet recording apparatus 300 of this example, in specific terms, an ink-jet head 200 with a desired nozzle pitch of 2.54 mm is obtained by making the head plate 13 temperature 50° C.
With this ink-jet head 200, ink drops 22 can be discharged with the desired pitch by passing current through piezoelectric element 10 (see
Here, in ink-jet head 200, the temperature of head plate 13 is assumed to be 50° C., and at this time the ink inside an ink discharge unit 12 also rises in temperature, and the viscosity of the ink decreases. Therefore, with this ink-jet head 200, the desired pressure is applied by passing an energizing waveform appropriate to the viscosity of the ink through piezoelectric element 10.
In this state, nozzle pitch measurement was carried out while varying the environmental temperature in which ink-jet recording apparatus 300 is used from 10° C. to 40° C. The result was that a fixed pitch of 25.4 mm could be obtained at all times by maintaining the temperature of head plate 13 at 50° C. even though the operating environment of ink-jet recording apparatus 300 was varied from 10° C. to 40° C. As the actual pitch measurement, the distance between nozzles 2 at each end was measured.
Ink-jet head 200 used in ink-jet recording apparatus 300 of this example has a configuration whereby a plurality of ink discharge units 12 are fixed to head plate 13 after being positioned, and therefore has good ink drop 22 impact positioning capability.
With ink-jet recording apparatus 300 of this example, when nozzle pitch P of ink-jet head 200 has not attained a desired value, if the environmental temperature and apparatus temperature vary from the initially set temperature and nozzle pitch P differs from the desired value, it is possible to change the temperature of head plate 13 of ink-jet head 200 by means of a temperature changing section and correct nozzle pitch P to the desired value, the desired nozzle pitch P can always be obtained, and good ink drop 22 impact positioning capability can be maintained.
As the temperature changing section in ink-jet recording apparatus 300 of this example, heater 30 that generates heat through the passage of electric current and is attached to head plate 13 is used, and through the extremely simple means of heater 30, and the ability to directly heat head plate 13 which is to be heated, temperature changes are effected speedily, and the desired nozzle pitch P is obtained, at low cost.
Ink discharge units 12 in ink-jet recording apparatus 300 are fixed to head plate 13 in an attachable and removable fashion, and readjustment of an ink discharge unit 12 can be carried out after initial alignment if required since ink discharge units 12 are attachable and removable,
Also, it is possible to replace an ink discharge unit 12 if an ink drop 22 discharge defect or ink drop 22 non-discharge occurs. Thus, an ink-jet head 200 can be provided that offers a high degree of flexibility and maintainability.
In ink-jet recording apparatus 300 of this example, through the provision of sealing member 14, it is possible to perform suction from nozzle 2, and apply negative pressure to ink in ink discharge unit 12, in a state in which suction cap 16 is in contact with head plate 13 but is not in direct contact with nozzle plate 1. Consequently, ink filling and recovery from a non-discharge state can easily be carried out while maintaining good ink drop 22 impact positioning capability.
Sealing member 14 is elastic, ink discharge unit 12 is supported so as to be able to move with respect to head plate 13 through deformation of sealing member 14, and slight movement of ink discharge unit 12 relative to head plate 13 is possible while maintaining a sealed state even after sealing member 14 is formed, enabling slight adjustment of the mounting position of ink discharge unit 12 with respect to head plate 13 to be carried out easily.
In ink-jet recording apparatus 300 of this example, one nozzle 2 is formed in one ink discharge unit 12, and if a plurality of nozzles 2 are provided, as long as alignment can be performed dependably for each ink discharge unit 12 without the occurrence of error with respect to the impact position among that plurality of nozzles, impact position error can be made extremely small.
The pressure application section of ink-jet recording apparatus 300 of this example is composed of diaphragm S that moves relative to nozzle plate 1, and piezoelectric element 10 that drives diaphragm 5, with the direction of relative movement of diaphragm 5 being virtually parallel to the discharge direction of an ink drop 22 discharged from nozzle 2, and flexibility with regard to ink selection is improved by using piezoelectric element 10 in the pressure application section.
In ink-jet head 300 of this example, by making the direction of oscillation of diaphragm 5 virtually parallel to the ink drop 22 discharge direction, variation of the rectilinearity of an ink drop 22 can be kept small even if the intensity of the pressure applied to the ink is changed, for instance.
According to a manufacturing method of ink-jet recording apparatus 300 of this example, alignment of an ink discharge unit 12 and head plate 13 is performed while recording an ink drop 22 from ink discharge unit 12 on receiving body 23 and observing the impact position of that ink drop 22, and with this method ink discharge unit 12 alignment is performed while confirming the final impact position, enabling impact position error to be made extremely small.
According to a manufacturing method of ink-jet recording apparatus 300 of this example, the temperature of head plate 13 during use is T1, the desired nozzle pitch of nozzles 2 of head plate 13 at that temperature T1 is P1, and when the temperature of head plate 13 is changed to T2, the head plate 13 nozzle pitch at that temperature changes to P2. That is to say, for head plate 13, when the temperature is T2, the nozzle 2 nozzle pitch is P2.
Therefore, in a manufacturing method of ink-jet recording apparatus 300 of this examples nozzle pitch P is determined taking the thermal expansion and contraction of head plate 13 into consideration, and by manufacturing ink-jet head 200 so that this determined nozzle pitch P is achieved, an ink-jet head 200 can he provided in which the desired nozzle pitch P is achieved at the temperature at which ink-jet head 200 is actually used.
In ink-jet recording apparatus 300 of this example, a single-layer piezoelectric element 10 has been used, but a laminated configuration may also be used for the piezoelectric element.
A so-called electrostatic actuator using electrostatic force, or a magnetostrictor using magnetic force, may also be used as a pressure application section in ink-jet recording apparatus 300 of this example.
In ink-jet recording apparatus 300 of this example, each ink discharge unit 12 is equipped with one nozzle 2, but the number of nozzles 2 need not necessarily be one. However, when particular importance is placed on variance of ink drop 22 impact positions, the fewer nozzles 2 there are, the better.
In ink-jet recording apparatus 300 of this example, heater 30 is attached to head plate 13 as a temperature changing section, but a heating element may also be formed directly on head plate 13.
In ink-jet recording apparatus 300 of this example, heater 30 is attached to a supporting plate 3, but heater 30 need not necessarily be attached to supporting plate 3, and it is also possible for heater 30 to be attached to ink discharge unit 12.
In ink-jet recording apparatus 300 of this example, heater 30 that generates heat through the passage of electric current is used as a temperature changing section, but it is also possible to use a cooling section that absorbs heat by means of a Peltier element or the like, for example, and furthermore a configuration is also possible in which both heater 30 and a cooling section are used.
In ink-jet recording apparatus 300 of this example, the liquid sucked from ink-jet head 100 has been assumed to be ink, but this liquid need not be a liquid containing a black or colored coloring material for creating text or a photograph on recording paper, and, for example, a liquid containing electrically conductive particles for electrode formation, a luminescent material used for EL (electroluminescence), a resinous material for creating microlenses, and so forth, can also be used satisfactorily.
Next, the configuration of an ink-jet recording apparatus according to Embodiment 4 of the present invention will be described.
As shown in
Camera 32 is supported by a camera moving section 33 so as to be able to move in the direction of the row of nozzles 2.
In
Then, according to this method, camera 32 is moved to the position of the adjacent nozzle 2, and nozzle pitch P is detected by measuring the amount of this movement.
Depending on the case, a method may also be satisfactorily used whereby nozzle pitch P is found by measuring the spacing of both ends of the row of nozzles 2 formed in ink discharge units 12.
Then, according to this method, the value of nozzle pitch P obtained by means of the above-described method, the value of nozzle pitch P desired when using ink-jet head 200, and the coefficient of linear thermal expansion of head plate 13 are considered, the temperature to be maintained for ink-jet head 200 is determined, current is passed through heater 30, and head plate 13 is heated to and maintained at the desired temperature in accordance with the temperature detected by thermistor 31.
By this means, the desired nozzle pitch P can be obtained when ink-jet head 200 is used.
In ink-jet recording apparatus 300 of this example, nozzle pitch P of ink-jet head 200 is detected, the temperature to be maintained for head plate 13 is set based on that value, and thermal expansion of head plate 13 is caused, and the desired nozzle pitch P obtained, by having head plate 13 heated to and maintained at the set temperature by heater 30.
Therefore, with ink-jet recording apparatus 300 of this example, the desired nozzle pitch P can be dependably obtained even if nozzle pitch P varies for each ink-jet head 200.
with ink-jet recording apparatus 300 of this example, a method can also be used satisfactorily whereby current is passed through heater 30 while measuring nozzle pitch P, and when the desired nozzle pitch P is obtained, that temperature is maintained.
With ink-jet recording apparatus 300 of this example, camera 32 is moved by means of camera moving section 33, but it is also possible to keep camera 32 fixed and move ink-jet head 200.
Next, another method of detecting nozzle pitch P of ink-jet recording apparatus 300 of this example will be described.
The difference between this nozzle pitch P detection method and the nozzle pitch P detection method shown in
In
Then receiving body 23 on which ink drop 22 images have been formed is passed directly beneath a camera 34 in the direction indicated by the arrow in
With this detection method, the nozzle pitch of ink-et head 200 is detected, the temperature to be maintained for head plate 13 is set based on that value, and thermal expansion of head plate 13 is caused, and the desired nozzle pitch obtained, by having head plate 13 heated to and maintained at the set temperature by heater 30.
Thus, with this detection method, an ink-jet recording apparatus 300 can be provided that enables the desired nozzle pitch P to be dependably obtained even if nozzle pitch P varies for each ink-jet head 200.
Next, an ink-jet recording apparatus according to Embodiment 6 of the present invention will be described.
As shown in
In
There are various demands with regard to nozzle pitch P of ink-jet head 200, and when ink-jet head 200 is actually manufactured, various problems arise concerning nozzle pitch P of ink-jet head 200.
One such problem is the desire to provide an ink-jet head 200 nozzle pitch P distribution within ink-jet head 200. This is a requirement of receiving body 23 onto which ink drops 22 are discharged, with, for example, nozzle pitch P at each end being made slightly longer than nozzle pitch P in the center.
This problem can be solved by making the calorific value of heaters 30 at both ends of ink-jet head 200 greater than the calorific value of heater 30 in the center, thereby raising the temperature at both ends of ink-jet head 200 above the temperature in the center, and increasing thermal expansion accordingly.
By this means, it is possible to make nozzle pitch P at each end of ink-jet head 200 longer than nozzle pitch P in the center.
Another problem is that, when ink-jet head 200 is manufactured, distribution may occur with respect to the desired value of nozzle pitch P within ink-jet head 200.
To solve this problem, it is desirable for heaters 30 to be given a heat generation distribution, and for ink-jet head 200 to be given a temperature distribution so as to correct the distribution with respect to the desired value.
A further problem is that, when there is an ink-jet head 200 calorific value distribution or a difference in heat dissipation according to ink-jet head 200 locations, if uniform heat generation is performed by heaters 30, a temperature distribution occurs in the ink-jet head, and as a result, a nozzle pitch distribution occurs.
To solve this problem, it is desirable for heaters 30 to be given a suitable heat generation distribution even if there is a calorific value distribution in ink-jet head 200, for instance, and thereby make the temperature of ink-jet head 200 uniform, and obtain a uniform nozzle pitch.
In ink-jet recording apparatus 400 of this example, it is possible to provide a temperature distribution in the direction of the row of ink-jet head 200 nozzles 2 by using a plurality of heaters 30 and creating a heat generation distribution.
By this means, with ink-jet recording apparatus 400 of this example, when there is an ink-jet head 200 nozzle pitch P distribution within that ink-jet head 200 and it is wished to eliminate that distribution, or conversely, when it is wished to provide a distribution for nozzle pitch P within ink-jet head 200, the desired nozzle pitch P can be obtained by providing a temperature distribution corresponding thereto.
Also, with ink-jet recording apparatus 400 of this example, by using a plurality of heaters 30 and providing a heat generation distribution for ink-jet head 200, if there is a calorific value distribution in ink-jet head 200 when ink-jet head 200 is heated and its temperature maintained, or if there are differences in ink-jet head 200 heat dissipation, by providing heaters 30 with a heat generation distribution corresponding thereto it is possible to perform heating and temperature maintenance so that the temperature of ink-jet head 200 becomes constant, and the desired nozzle pitch P can be obtained throughout ink-jet head 200.
Ink-jet recording apparatus 400 of this example is equipped with a plurality of heaters 30 in order to provide a heat generation distribution, but as long as a heat generation distribution can be provided, it is also possible, for example, to use a single heater 30 that has a heat generation distribution in order to obtain the desired heat generation distribution. In this case, of course, the heat generation distribution cannot be freely changed.
Also, with ink-jet recording apparatus 400 of this example, when ink-jet head 200 is provided with a temperature distribution, it is also possible to change the waveform applied to the respective piezoelectric elements 10 according to that temperature distribution, and also provide a distribution for the voltage applied to the ink in the respective ink discharge units 12.
Next, a manufacturing method of an ink-jet head according to Embodiment 7 of the present invention will be described.
As shown in
In
Thereafter, the same kind of operations are performed as in the manufacturing method shown in
According to the manufacturing method of ink-jet head 200 of this example, head plate 13 is kept at the temperature at which ink-jet head 200 will finally be used, and alignment of ink discharge unit 12 with head plate 13 is carried out in this state.
Therefore, according to the manufacturing method of ink-jet head 200 of this example, an ink-jet head 200 can be obtained in which thermal expansion and contraction of head plate 13 is not considered at all, and the desired nozzle pitch P can be obtained as long as the temperature of head plate 13 is kept constant during use.
Also, according to the manufacturing method of ink-jet head 200 of this example, the same heater 30 is used when an ink discharge unit 12 is aligned and when ink-jet recording apparatus 300 is actually used, and head plate 13 temperature irregularities and variations are approximately the same in both cases.
Therefore, with the manufacturing method of ink-jet head 200 of this example, even if there are temperature irregularities or variations in head plate 13 when an ink discharge unit 12 is aligned, as long as ink discharge unit 12 is aligned satisfactorily in that state, the desired nozzle pitch P can be obtained, and an ink-jet head 200 with good ink drop 22 impact positioning capability can be provided.
In this embodiment, it has been assumed that the same kind of alignment and fixing method as in Embodiment 5 is used after performing heating and temperature maintenance of head plate 13, but the same kind of alignment and fixing method as in Embodiment 1 may also be used.
With the manufacturing method of ink-jet head 200 of this example, heater 30 utilized in ink-jet recording apparatus 300 is ultimately used to change the temperature of head plate 13, but there may be cases where, although this is desirable from the standpoint of impact positioning capability, temperature changing by a different means is desirable from the standpoint of efficiency of the manufacturing process.
In such cases, it is possible, for example, to use a separate high-output heater, or to change not only the temperature of head plate 13 but also the surrounding environmental temperature.
An above-described ink discharge unit 12 is provided with one nozzle plate 1 in which a single nozzle 2 is formed,
If, on the other hand, one nozzle plate 1 of one ink discharge unit 12 is provided with a plurality of nozzles 2, as shown in
Thus, in the manufacturing method of ink-jet head 200 of this example, the temperature of head plate 13 is controlled at the desired temperature, and the length of head plate 13 is changed to the desired length by causing thermal expansion or contraction of head plate 13.
By this means, with the manufacturing method of ink-jet head 200 of this example, nozzle pitch P of each nozzle 2 of each ink discharge unit 12 fixed to head plate 13 can be controlled to the desired nozzle pitch P.
Ink-jet head 200 of this example maybe configured so that a plurality of nozzles 2 are provided for one pressure chamber 6, and may be configured so that ink drops 22 are always discharged simultaneously from a plurality of nozzles 2 for forming one pixel.
The present application is based on Japanese Patent Application No. 2005-032555 filed on Feb. 9, 2005, and Japanese Patent Application No. 2005-137032 filed on May 10, 2005, entire content of which is expressly incorporated herein by reference.
An ink-jet head of the present invention enables ink suction from a nozzle to be performed dependably when an ink-jet head is filled with ink, and when a recovery operation is performed in the event of a discharge defect, and not only records text or images by discharging ink onto recording paper, but can be applied to industrial uses such as formation of a wiring pattern by discharging various kinds of metallic ink, color filter formation by discharging a color filter material, discharge of various kinds of material for performing EL (electroluminescence), and discharge of various kinds of material for organic TFT creation, for example.
Number | Date | Country | Kind |
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2005-032555 | Feb 2005 | JP | national |
2005-137032 | May 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP06/32189 | 2/8/2006 | WO | 10/6/2006 |