Method of making ink jet recording head with tapered orifice

Information

  • Patent Grant
  • 6211486
  • Patent Number
    6,211,486
  • Date Filed
    Thursday, July 2, 1998
    26 years ago
  • Date Issued
    Tuesday, April 3, 2001
    23 years ago
Abstract
A method for manufacturing an ink jet recording head involves forming discharge ports by irradiating a laser beam onto a member which becomes the discharge port plate through a mask having specific patterns thereon. The mask includes a transmission section which regulates the shape of the discharge ports, and an attenuation section formed on the outer circumference of the transmission section so that the further the attenuation section is from the transmission, the less the laser beam becomes. This method also involves forming the discharge ports by irradiating the laser beam through the mask to the member, and each port has a cross-sectional shape which gradually tapers from a rectangular shape at a side of the port connected with the liquid flow path to a circular shape at a recording liquid discharge side of the port.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to an ink jet recording head that records by discharging recording droplets to a recording medium by use of the ink jet recording method for the adhesion thereof to it. The invention also relates to a method of manufacture therefor. More particularly, it relates to an ink jet recording head for discharging fine recording droplets stably at higher speeds in order to obtain images recorded in higher precision, and a method of manufacture therefor as well.




2. Related Background Art




With the ink jet recording head, recording (printing) is made by discharging the ink that serves as recording liquid from the fine discharge ports (orifices) as flying droplets which adhere to a recording medium (a paper recording sheet or the like). To structure the ink discharge unit of the ink jet recording head, there are laminated a resin member on a substrate provided with a plurality of discharge energy generating elements and lead electrodes on it in order to form a plurality of grooves that serve as ink liquid flow paths and a groove that serves as a common liquid chamber communicated with the plurality of liquid flow paths. To the resin member formed on this substrate, the glass ceiling plate provided with an ink supply opening is bonded to cover all the grooves for the formation of the liquid flow paths and the common liquid chamber.




In recent years, the above-mentioned glass ceiling plate is omitted, while the ink supply opening is added to the grooves that serve as the liquid flow paths and the common liquid chamber. Then, the resin ceiling plate is formed by means of injection molding or the like together with the orifice plate having discharge ports formed therefor. Such resin ceiling plate and the substrate provided with the discharge energy generating elements are bonded through an elastic member so that each of the discharge energy generating elements is fittingly arranged for each of the flow path grooves on the ceiling plate. In this manner, there has been developed an ink jet recording head formed by bonding the resin ceiling plate and the substrate.





FIG. 9

is a perspective view which shows the principal part of the ink jet recording head formed by bonding such resin ceiling plate and substrate. In

FIG. 9

, the second substrate that serves as the resin ceiling plate is partly broken for representation. As shown in

FIG. 9

, a plurality of discharge energy generating elements


701


for discharging ink are arranged in parallel for the first substrate


702


. On the other hand, the resin second substrate


710


is structured by the ceiling plate portion


711


and the orifice plate portion


708


. Here, the ceiling unit


711


is configured in such a manner that it is connected vertically with one surface of the orifice plate portion


708


. On one surface of the ceiling plate portion


711


, the ink supply opening


709


is arranged. Here, a hole extended from the ink supply opening


709


penetrates the ceiling plate portion


711


vertically. On the other surface of the ceiling plate portion


711


, where the hole form the ink supply opening


709


is open, there are arranged a groove extendedly in parallel with the orifice plate portion


708


to serve as the common liquid chamber to retain ink temporarily, and a plurality of grooves communicated with the common liquid chamber


706


to serve as liquid flow paths which are extended on straight lines from the common liquid chamber


706


in the direction toward the orifice plate portion


708


. On the leading edge portion of the orifice plate portion


708


to which the plurality of liquid flow paths


707


are extended, the holes are arranged to penetrate the orifice plate portion


708


. Through these holes, the liquid flow paths


707


are communicated with the outside. These through holes on the orifice plate portion


708


become the ink discharge ports


705


. The surface of the second substrate


710


, where the grooves are provided for the common liquid chamber


706


and the liquid flow paths


707


, and the surface of the first substrate


702


, where the discharge energy generating elements


701


are formed, are arranged to face each other so that the discharge energy generating elements


701


are positioned with the corresponding liquid flow paths


707


. Then, these surfaces are pressed with an elastic material (not shown) between them to bond the first substrate


702


and the second substrate


710


for the formation of the common liquid chamber


706


and the liquid flow paths


707


. The first substrate


702


bonded together with the second substrate


710


, and the wiring substrate


703


, which is provided with driving circuits installed thereon to generate electric signals to be transmitted to the first substrate


702


, are fixed on the base plate


704


, thus forming the principal part


714


of the head.




Now, with the principal part


714


of the ink jet recording head shown in

FIG. 9

, an ink jet recording head is fabricated as represented in FIG.


10


. Here, the head principal part


714


is integrally formed by the injection molding together with the grooves that become liquid flow paths


707


to supply ink (recording liquid) to the head principal part


714


, the ceiling plate portion


711


provided with the ink supply opening


709


, and the orifice plate portion


708


as shown in FIG.


10


. Then, a part of the orifice plate portion


709


, which is the plate portion of the integrally formed resin member, prepared for the formation of the discharge ports


705


, is irradiated by excimer laser from the common liquid chamber side to from them. In this manner, the second substrate


710


is produced.




Now, with reference to

FIGS. 11A

to


11


C, the description will be made of the operation of the ink jet recording head structured as described above. The interior of the common liquid chamber


706


is filled with ink supplied from the ink supply opening


709


. The interior of each of the liquid flow paths


707


is also filled with the ink that has flown into it from the common liquid chamber


706


. When each of the discharge energy generating elements


701


is supplied with electric power, thermal energy is generated as discharge energy. With the thermal energy thus generated, film boiling is created in ink on each of the discharge energy generating elements


701


, hence air bubbles being formed in the liquid flow paths, respectively. By the development of each air bubble, ink that resides between the corresponding discharge energy generating element


701


and discharge port


705


is pressed toward the discharge port


705


. Then ink is discharged from the discharge port


705


.




However, the progress of recording technologies, particularly the progress in making the precision of recorded images more precise, is remarkable in recent years. As a result, it has been demanded to make recorded images highly precise not only in the conventional resolutions of from 360×360 dpi (dot per inch) and 600×600 dpi to 720×720 dpi, but also, in the extremely high resolution of 1200×600 dpi or the like.




In order to materialize highly precise images recorded by use of an ink jet recording head, it is necessary to make the recording droplets extremely small when discharged from each of the discharge ports. However, there is a problem encountered that it is very difficult to discharge the extremely fine recording droplets stably at high speeds by use of the ink jet recording head produced by the conventional art. Now, hereunder, such problem will be discussed with reference to

FIGS. 11A

to


11


C which illustrate the conventional techniques.




In other words, there is a need for making the diameter of each discharge port smaller in order to make each recording droplet a small one. Then, when the discharge port is made smaller, the residing region of the fluid resistance component (the step


730


in

FIGS. 11A

to


11


C) becomes larger in the portion that connects the discharge port with the liquid flow path. As a result, due to the presence of this fluid resistance component, the amount of reflection is increased against the discharge pressure waves when bubble is generated by the heater. This increased reflection disturbs the ink flow at the time of refilling. A flow disturbance of the kind tends to result in lowering the refilling frequency. Meanwhile, the enhancement of resolution as described earlier necessitates the increased numbers of recording droplets inevitably. Therefore, in order to secure the same printing speeds as those conventionally available, it is necessary to obtain a sufficient discharge frequency. This in turn requires the enhancement of refilling frequency.




In this respect, if each of the discharge energy generating elements should be driven at higher speeds for discharging smaller droplets just by making the diameter of each discharge port smaller, the refilling capability tends to become insufficient eventually, hence making it hardly attainable to obtain the discharge characteristics in good condition as desired.




Also, as another method for making recording droplets small ones, it is practiced to make the heater power smaller. However, although this method produces a favorable effect on the enhancement of the refilling frequency, it tends to results not only in reducing the discharge amount of recording droplets, but in reducing the discharge speeds. This tendency may invite the twisted flight of recording droplets or the like, and from the practical point of view, a method of the kind can hardly be regarded as a desirable one.




Further, it may be possible to enhance the refilling speeds by making the volume larger in the liquid flow paths and the discharge ports on the discharge port side than the energy generating device side, because this arrangement makes the amount of displacement smaller for each meniscus. However, if such volume is made larger just by shifting the energy generating devices to the liquid chamber side, the discharge efficiency of recording droplets becomes inferior, and in some cases, the disabled discharge of recording droplets may take place particularly when the heater power is made smaller.




As described above, no ink jet recording head has been developed to make a high quality printing possible by discharging small droplets at higher frequency.




SUMMARY OF THE INVENTION




In consideration of the problems discussed above, the present invention is designed. It is an object of the invention to provide an ink jet recording head capable of obtaining the volume of the liquid flow paths and discharge ports on the discharge port side more than the energy generating device side without making the distance from the heaters to the discharge ports greater, at the same time, presenting excellent refilling characteristics in order to secure a sufficient discharge speed of recording droplets.




In order to achieve the objective described above, the ink jet recording head of the present invention is provided with a plurality of discharge ports for discharging recording liquid, a discharge port plate having the discharge ports therefor, a liquid chamber for retaining the recording liquid, a plurality of discharge energy generating elements for discharging the recording liquid, a substrate having the plurality of discharge energy generating elements on one surface thereof, and a plurality of liquid flow paths extended in one direction for communicating the liquid chamber and the discharge ports, each having the rectangular sectional configuration, at the same time, including each of the discharge energy generating elements therein. The sectional shape of each of the discharge ports is circular on the end portion thereof on the recording liquid discharge side, at the same time, the sectional area of the discharge port end portion connected with the liquid flow path being made larger than that of the end portion of discharge port on the recording liquid discharge side, and the sectional shape of the discharge port is rectangular, while the discharge port is tapered to change its sectional shape from being rectangular to circular.




Also, the method for manufacturing an ink jet recording head of the present invention is provided with a plurality of discharge ports for discharging recording liquid, a discharge port plate having the discharge ports therefor, a liquid chamber for retaining the recording liquid, a plurality of discharge energy generating elements for discharging the recording liquid, a substrate having the plurality of discharge energy generating elements on one surface thereof, and a plurality of liquid flow paths extended in one direction for communicating the liquid chamber with the discharge ports, each having the rectangular sectional configuration, at the same time, including each of the discharge energy generating elements therein, and the discharge ports are formed by irradiating the laser beam on the member becoming the discharge port plate though a mask having specific patterns thereon. This mask that transmits the laser beam is provided with the transmission section that regulates the shape of the discharge port, and the attenuation sections formed on the outer circumference of the transmission section to enable the transmissivity of the laser beam to be made gradually smaller as each of the attenuation sections parts farther away from the transmission section, thus forming by use of the mask the discharge port that changes its sectional shape in the form of taper gradually from the end portion of discharge port connected with the liquid flow path having the rectangular sectional shape to the end portion of the discharge port on the recording liquid discharge side having the circular sectional shape.




Further, the discharge port may be provided with a symmetrically tapered part on the portion that is connected with the end portion on the recording liquid discharge side, which is symmetrically formed with respect to the axis of ink discharge direction.




Also, the discharge port may be provided with a portion that changes its taper angle on the way or may be provided a taper angle uniformly on the portion of the discharge port nearest to the liquid flow path.




With the structure thus arranged, it becomes possible to make the resistance component smaller on the portion that connects the discharge port and the liquid flow path. At the same time, it becomes possible to secure the volume of the liquid flow path on the discharge port side more than that of the energy generating device side without making the distance larger between the heat and discharge port. As a result, an ink jet recording head can be obtained with the improved refilling characteristics.




Further, the resistance component is made smaller particularly on the portion that connects the discharge port on the substrate side and the liquid flow path. Therefore, the discharge efficiency is enhanced more than the conventional head. In this way, it becomes possible to secure the sufficiently higher speeds for discharging recording droplets. Consequently, without making the heater area comparatively larger, small droplets can be discharged, while effectuating the enhancement of the refilling characteristics.




As described above, in accordance with the present invention, it is possible to repeatedly discharge smaller droplets at higher speeds, hence obtaining an ink jet recording head capable of printing images in high quality at higher speeds.











BRIEF DESCRIPTION OF THE DRAWINGS





FIGS. 1A

,


1


B and


1


C are a cross-sectional view, a plan view, and a perspective view, respectively, which illustrate an ink jet recording head most suitably in accordance with a first embodiment of the present invention.





FIG. 2

is a perspective view which shows the principal part of the ink jet recording head provided with the discharge ports and liquid flow paths represented in

FIGS. 1A

,


1


B and


1


C.





FIG. 3

is a perspective view which shows an ink jet recording head provided with the principal part of the ink jet recording head represented in FIG.


2


.





FIG. 4

is a structural view which schematically shows the laser processing apparatus used for the formation of the discharge ports and liquid flow paths represented in

FIGS. 1A

,


1


B and


1


C.





FIG. 5

is an enlarged view which shows the mask used for the laser processing apparatus represented in FIG.


4


.





FIG. 6

is a cross-sectional view which shows the ink jet recording head most suitably in accordance with a second embodiment of the present invention.





FIG. 7

is a cross-sectional view which shows the variation of the ink jet recording head in accordance with the second embodiment of the present invention.





FIG. 8

is a cross-sectional view which shows the ink jet recording head most suitably in accordance with a third embodiment of the present invention.





FIG. 9

is a perspective view which shows the principal part of the ink jet recording head in accordance with the conventional art.





FIG. 10

is a perspective view which shows the ink jet recording head provided with the principal part of the ink jet recording head represented in FIG.


9


.





FIGS. 11A

,


11


B and


11


C are a cross-sectional view, a plan view, and a perspective view, respectively, which illustrate the discharge ports and liquid flow paths represented in FIG.


9


.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




Hereinafter, with reference to the accompanying drawings, the description will be made of the embodiments in accordance with the present invention.




(First Embodiment)





FIGS. 1A

to


1


C are a cross-sectional view, a plan view, and a perspective view, respectively, which illustrate an ink jet recording head most suitably in accordance with a first embodiment of the present invention.

FIG. 1A

is the cross-sectional view which shows a liquid flow path and a discharge port of the ink jet recording head.

FIG. 1B

is the plan view which shows the configuration of the liquid flow path and the discharge port represented in FIG.


1


A.

FIG. 1C

is a perspective view which shows the structure of the circumference of the discharge port for the easier understanding of the relationship between the liquid flow path and the discharge port represented in FIG.


1


A and

FIG. 1B

, respectively.




In accordance with the present embodiment, the ink jet recording head is provided, as shown in

FIG. 1A

, with the ink supply opening


109


, the liquid common chamber


106


to retain ink serving as a recording liquid; the discharge port


105


to discharge ink in the common liquid chamber


106


; and the liquid flow path


107


extended in one direction in order to conductively connect the common liquid chamber


106


and the discharge port


105


. The ink jet recording head is also provided with each of the discharge energy generating elements


101


arranged therefor. The discharge port


105


connected with the leading end of the liquid flow path


107


is tapered so that it becomes gradually smaller toward the recording liquid discharge side. Also, as shown in

FIGS. 1B and 1C

, the sectional configuration of the end portion of the discharge port


105


on the recording liquid discharge side is circular, and the sectional configuration of the liquid flow path


107


is equally-footed trapezoidal in the direction perpendicular to the progressing direction of ink.




Also, the configuration of the portion that connects the discharge port


105


with the liquid flow path


107


is equally-footed trapezoidal to match the discharge port with that of the liquid flow path


107


. Here, in accordance with the present invention, the end portion of the discharge port


105


is made circular on the recording liquid discharge side in order to reduce the creation of mist significantly when the discharge energy generating element


101


is driven at high speeds. Also, with the sectional configuration of the discharge port


105


which is tapered gradually from the equally-footed trapezoid to the circle, it becomes possible to make the fluid resistance component smaller, while securing a sufficient volume between the liquid flow path


107


and discharge port


105


on the discharge port side more than the discharge energy device


101


side, thus improving the refilling performance. Here, in accordance with the present embodiment, the sectional configuration of the liquid flow path and that of the portion connecting the discharge port


105


with the liquid flow path


107


are arranged to be equally-footed trapezoidal. However, it should be good enough if only the sectional configuration of the liquid flow path


107


is made rectangular with the flat substrate


102


, which is provided with the discharge energy generating elements thereon, as the bottom of such rectangle to be formed. Also, it should be good enough if only the sectional configuration of the portion that connects the liquid flow path


107


with the discharge port


105


is made rectangular to match the discharge port with the liquid flow path.




The common liquid chamber


106


and liquid flow path


107


thus configured are formed by bonding the first substrate


102


, which provided with discharge energy generating elements


101


thereon, and the second substrate


110


to be configured as described later. One surface of the second substrate where the respective grooves are formed for the provision of the common liquid chamber


106


and the liquid flow path


107


is bonded to the surface of the first substrate


102


on the discharge energy generating element side so that the each of the discharge energy generating elements


101


can be arranged correspondingly for each of the grooves that becomes each liquid flow path


107


. Further, the first substrate


102


integrally arranged with the second substrate


110


as one body is mounted and fixed on the base plate


104


.




The second substrate


110


is provided with the ceiling plate portion


111


having on it each of the grooves that becomes the common liquid chamber


106


and the liquid flow path


107


, respectively, and also, provided with the orifice plate portion


108


. The ceiling plate portion


111


is arranged to be perpendicular to it. Each of the liquid flow paths


107


extends from the common liquid chamber


106


toward the orifice plate


108


. The orifice plate portion


108


is a plate member where discharge ports


105


are formed. On the orifice plate, through holes are provided each on the position to which each of the liquid flow paths


107


is extended, hence forming the discharge ports


105


, respectively.





FIG. 2

is a perspective view which shows the principal part of the ink jet recording head provided with a plurality of discharge ports


105


, liquid flow paths


107


and common liquid chambers


106


each of which is as represented in

FIGS. 1A

to


1


C. In

FIG. 2

, the second substrate


110


is partially broken for representation. As shown in

FIG. 2

, the second substrate


110


is structured by the ceiling plate portion


111


and the orifice plate portion


108


, and configured to allow the ceiling plate portion


111


to be connected with the orifice plate portion


108


vertically. On one surface of the ceiling plate portion


111


, the ink supply opening


109


is arranged. The hole extended from the ink supply opening


109


penetrates the ceiling plate portion


111


vertically. On the other surface of the ceiling plate portion


111


where the hole from the ink supply opening


109


is open, the groove that becomes the common liquid chamber


106


extends in parallel with the orifice plate portion


108


. Being communicated with this groove that becomes the common liquid chamber


106


, a plurality of grooves that become the liquid flow paths


107


are extended on straight lines toward the orifice plate portion


108


. On the orifice plate portion


108


at the leading end of each of the liquid flow paths thus extended, each of the holes (ink discharge ports


105


) is formed. Through these ink discharge ports


105


, each of the liquid flow paths


107


is communicated externally. As described above, the surface of the second substrate


110


where each of the grooves are provided for the formation of the common liquid chamber


106


and the liquid flow paths


107


are positioned to face the surface of the first substrate


102


where the discharge energy generating elements


101


are formed so that each of the liquid flow paths


107


is arranged correspondingly for each of the discharge energy generating elements


101


. Then, with an elastic member (not shown) being placed between these surfaces, the first substrate


102


and the second substrate


110


are pressed and bonded. With the first substrate


102


and second substrate


110


thus bonded together, the common liquid chamber


106


and the plural liquid flow paths


107


are formed. The first substrate


102


to which the second substrate


110


is bonded, and the wiring substrate


121


having on it the driving circuit for generating electric signals to the first substrate


102


are fixed on the base plate


104


to structure the head principal part


114


.





FIG. 3

is a perspective view which shows an ink jet recording head provided with the head principal part


114


represented in FIG.


2


. As shown in

FIG. 3

, the head principal part


114


is assembled on a cartridge


123


by means of an outer frame member


122


which contains a recording liquid supply member (not shown) or the like that supplies ink to the head principal part


114


. In the interior of the cartridge


123


, sponges or the like are housed to absorb ink for storage.




Now, with reference to FIG.


4


and

FIG. 5

, the description will be made of a method for forming the above-mentioned discharge ports


105


.

FIG. 4

is a structural view which schematically shows the laser processing apparatus used for the formation of the discharge ports


105


. Here, the laser processing apparatus adopted for the present embodiment is different from the one used for the conventional art only in the mask to be used, and no other structural elements are the same as the conventional laser apparatus.




As shown in

FIG. 4

, the laser processing apparatus of the present embodiment comprises, on the laser optical axis


202


of the laser beam emitted from the laser light source


201


, the beam shaping optical system


203


, the illumination optical systems


206




a


and


206




b


, the mask


205


, the projection optical system


207


, and the work


204


in that order from the laser light source


201


side. The work


204


is the member whereby to produce the second substrate


110


shown in FIG.


1


A and

FIG. 2

before the discharge ports


105


are formed.




The beam shaping optical system


203


is to shape the laser beam from the laser light source


201


. The illumination optical systems


206




a


and


206




b


are to uniform the intensity of laser beam. For the mask


205


, the patterns are formed as shown in

FIG. 5

, which will be described later, in accordance with the processing form of the work


204


. The projection optical system


207


is arranged to focus the laser beam, which is transmitted through the mask, on the processing surface in a specific magnification. In accordance with the present embodiment, the projection optical system


207


is used in a specific magnification of ¼ and resolution of 0.002 mm. The resolution of the projection optical system


207


means the minimum size obtainable on the processing surface, in which the patterns of the mask


205


can be focused on the surface of the work


204


. Thus, if the pattern that should be formed on the mask is 0.008 mm or less, which is the quotient of the resolution (0.002 mm) of the projection optical system


207


divided by the specific magnification (¼), it is impossible to focus such pattern on the work


204


.




Also, on the laser optical axis


202


between the illumination optical system


206




b


and the mask


205


, there is arranged a device (not shown) which is provided with a power monitor unit


209


for measuring the intensity of the laser beam from the illumination optical system


206




b


. The work


204


is mounted on the work mount


208


, and on both sides of the work


204


with respect to the optical axis, the observation systems


210




a


and


210




b


are arranged and used for positioning the work


204


. The observation system


210




a


and


210




b


, the laser light source


201


, and the work mount


208


are controlled by means of the control system


211


.





FIG. 5

is an enlarged view which shows one pattern of the mask


205


used for the laser processing apparatus represented in FIG.


4


. On the mask


205


,


128


of the same patterns as shown in

FIG. 5

are arranged at pitches of 0.282 mm. With such patterns on the mask


205


, it allows 90% of the laser beam from the laser light source


201


to be transmitted as shown in FIG.


5


. Each pattern on the mask


205


comprises a circular transmission section


302


that allows the laser beam from the laser light source to be transmitted to regulate the configuration of the discharge port


105


; attenuation sections formed on the outer circumference of the transmission section, each of which enables the transmissivity of the laser beam to be reduced gradually by 10% as it is located farther away from the transmission section


302


; and a light shielding section


305


formed on the outer circumference of the attenuation sections


303


, the transmissivity of the laser beam of which is 20%.




The attenuation sections


303


are formed by three extinction portions


303




a


,


303




b


, and


303




c


each with the different laser beam transmissivity, respectively. On the outer circumference of the transmission section


302


, the attenuation section


303




a


whose transmissivity is 50% is formed. On the outer circumference of the attenuation section


303




a


, the attenuation section


303




b


whose transmissivity is 40% is formed, and on the outer circumference of the attenuation section


303




b


, the attenuation section


303




c


whose transmissivity is 30% is formed. In this manner, the transmissivity of the laser beam changes by 10% in the direction from the attenuation sections


303


to the light shielding section


305


one after another.




The external shape of the attenuation sections


303


is equally-footed trapezoidal of 0.224 mm on the upper side, and 0.156 mm on the lower side, in a height of 0.176 mm. With this trapezoidal shape, the configuration and size of the surface of the tapered liquid flow path


107




b


which is in contact with the liquid flow path


107




a


are regulated. The transmission section


302


is circular of 0.164 mm diameter.




Also, the attenuation sections


303


function like negative portion of the mask


205


, and formed by inlaying a plurality of square extinction elements


304


each in a size of 0.002 mm per side. The extinction element


304


shown on the lower left side in

FIG. 5

is the enlargement of the actual extinction element


304


for representation. The size of this extinction element


304


(0.002 mm) is smaller than the quotient, 0.008 mm, obtainable by dividing the resolution (0.002 mm) of the projection optical system


207


described earlier by the specific magnification (¼). As a result, one piece of the extinction element


304


is not focused on the work


204


by means of the projection optical system


207


. However, by the extinction element


304


, the laser beam is partly reflected or absorbed, and the laser beam which is incident upon the attenuation sections


303


is attenuated. Therefore, with many more numbers of extinction elements


304


being inlaid, the corresponding attenuation sections can be formed in a lower transmissivity accordingly. In this case, it is necessary to make an arrangement so that a plurality of extinction elements


304


are not aggregated together to make the size of aggregated elements more than 0.008 mm which is the quotient obtainable by dividing the resolution (0.002 mm) of the projection optical system


207


by the specific magnification (¼). When the size of the aggregated extinction elements


304


becomes more than 0.008 mm, the image of such aggregated elements is focused on the work


204


eventually. As a result, the laser beam cannot be attenuated uniformly.




With the transmissivity of the laser beam being 20% on the light shielding section


305


, the energy density of the laser beam, which is converged by the projection optical system


207


after being transmitted through the light shielding section


305


, becomes less than the processing threshold value of the work


204


. Hence, the work


204


is not processed.




With the laser processing apparatus thus structured, the laser beam that transmits the interior of the transmission section


302


of the mask


205


is adjusted to make its energy density at 1 J/cm·puls on the processing surface of the work


204


when the laser beam has transmitted 90% of this section. Then, the laser beam is irradiated on the processing surface of the work


204


with 300 puls at 100 Hz for processing. The work


204


is prepared to be in the shape of the second substrate


110


as shown in

FIG. 2

, and the grooves that become the liquid flow paths


107


and the common liquid chamber


106


are also formed as shown in

FIGS. 1A

to


1


C and

FIG. 2

, but the discharge ports


105


yet to be formed. Therefore, the leading end of each liquid flow path is blocked by the orifice plate portion


108


. The laser beam is irradiated on the orifice plate portion


108


from the liquid flow path


107


side for processing. Thus, the surface of the orifice plate portion


108


on the leading end of the liquid flow paths


107


is the processing surface. Now, the description will be made of the operation of the laser processing apparatus shown in FIG.


4


.




The laser beam emitted from the laser light source is shaped by means of the beam shaping optical system


203


, and the intensity of the laser beam is uniformed by means of the illumination optical systems


206




a


and


206




b


to be incident upon the mask


205


. Of the laser beam that enters the mask


205


, the one that transmits the mask


205


is converged on the processing surface of the work


204


in a magnification of ¼ by means of the projection optical system


207


. At this juncture, the pattern formed on the mask


205


is focused on the processing surface of the work


204


in the magnification of ¼ by means of the projection optical system


207


. The processing surface of the work


204


is then processed by abrasion or the like in accordance with the pattern on the mask


205


.




The image formed on the processing surface of the work


204


is such that since the pattern on the mask


205


is reduced to a ¼, the image that projects the circle of 0.164 mm diameter at the transmission section


302


becomes a circle of 0.041 mm on the processing surface of the work


204


. The hole that penetrates the orifice plate portion


108


is formed by the application of the laser beam that has transmitted this transmission section


302


for the formation of each discharge port


105


. The diameter of the discharge port


105


thus formed on the end portion of the recording liquid discharge port side is smaller than the circle of 0.041 mm diameter which is the projected image on the processing surface because of the characteristics of the laser processing. In accordance with the present embodiment, it is possible to obtain the discharge port whose diameter is 0.033 mm on the end portion of the recording liquid discharge port side.




Also, the laser beam that transmits each attenuation section


303


is being changed to the laser beam having lower energy densities as it is away externally from the transmission section


302


. Therefore, the orifice plate portion


108


on the outer circumference of the discharge port


105


is processed in a depth corresponding to the energy density of the laser beam. Then, the processing depth thereof becomes gradually shallower as it is farther away from the end portion of the liquid discharge port


105


on the recording liquid discharge side. As a result, it becomes possible to obtain the tapered discharge port


105


without any steps on the way.




As in the transmission section


302


, the projected equally-footed trapezoidal image of 0.224 mm on the upper bottom and 0.156 mm on the lower bottom in a height of 0.176 mm, which is the outer shape of the attenuation section


303


, becomes the equally-footed trapezoidal shape of 0.056 mm on the upper bottom and 0.039 mm on the lower bottom in the height of 0.044 mm on the processing surface. However, this trapezoidal projection image is almost the same as the sectional configuration of the liquid flow path


107


. The energy density of the laser beam that has transmitted the light shielding section


305


of 20% transmissivity becomes equal to or less than the processing threshold value of the work


204


. Therefore, the equally-footed trapezoidal outer shape of the attenuation sections


303


serves to regulate the configuration of the discharge port


105


on the liquid flow path


107


side. As a result, the step (resistance component) is significantly reduced on the boundary between the discharge port


105


and the liquid flow path


107


. In this way, it becomes possible to produce the second substrate


110


provided with each discharge port


105


as shown in

FIGS. 1A

to


1


C. In accordance with the present embodiment, since the


128


patterns of the one shown in

FIG. 5

are formed on the mask


205


, it is possible to obtain the second substrate


110


having


128


discharge ports of 0.033 mm diameter each for it.




The second substrate


110


thus processed is bonded to the first substrate


102


as shown in

FIG. 2

to produce an ink jet recording head. With such ink jet recording head, printing is performed actually with the result that the speed of ink droplet discharges is stabilized: it is more stabilized than the conventional one particularly when printing is performed at higher speeds. Moreover, when smaller droplets are discharged, the discharge speeds are stabilized, and at the same time, the discharge speeds are enhanced. Also, the generation of ink mist is reduced when smaller droplets are discharged. As a result, it becomes possible to record images in higher precision.




In accordance with the present embodiment, as each of the attenuation sections


303


of the mask


205


becomes farther away from the circumference of the transmission section


302


, the transmissivity of the laser beam is reduced by 10%. However, it may be possible to arrange the structure of the attenuation sections


303


so that the transmissivity is made changeable by a smaller percentage, hence reliably forming the tapered liquid flow path


107




b


with its surface being processed more smoothly. More ideally, it is desirable to arrange the structure so that the transmissivity becomes 20% on the boundary between the attenuation section


303


and the light shielding section


305


after the transmissivity has continuously been reduced from 50% as each of the attenuation sections


303


parts farther away from the transmission section


302


.




Also, in accordance with the present embodiment, the transmissivity of the attenuation section


303




c


which is arranged on the most external side of the attenuation sections


303


is set at 30%, but this transmissivity may be increased to 40%. Thus, for example, the transmissivity of the attenuation section


303




b


is set at 45%. In this way, the attenuation sections


303


may be structured so that the transmissivity thereof is made changeable by 5%, respectively. With the mask having such pattern, the laser processing may be performed to produce an ink jet recording head which is able to demonstrate the same effect as described above.




Also, in accordance with the present embodiment, the outer shape of the attenuation sections


303


of the mask


205


is arranged to be an equally-footed trapezoid of 0.224 mm on the upper bottom and 0.156 mm on the lower bottom in a height of 0.176 mm. Then, the shape of the equally-footed trapezoidal image projected on the processing surface is made agreeable with the sectional configuration of the liquid flow path


107


. However, if the projected image on the processing surface and the section of the liquid flow path


107


are in one identical shape, there is a fear that a great resistance component may be created locally on the boundary between the processed discharge port


105


and liquid flow path


107


when the laser processing is performed with the positions of the mask


205


and the work


204


as they are, which are slightly deviated between them on the laser processing apparatus shown in FIG.


4


. Therefore, in order to improve the production yield for the intended laser processing, the size of the outer shape of the attenuation sections


303


of the mask


205


should be made larger by approximately 10% to enable the liquid flow path


107


portion to be processed simultaneously.




In this case, the laser beam, which is irradiated on the common liquid chamber


106


side which may constitute the partition wall or the like of the adjacent liquid flow paths


107


themselves, tends to weaken its intensity, because such laser beam has transmitted the attenuation section


303




c


whose transmissivity is 30%. As a result, the processing depth becomes shallower. However, the portion thus processed shallower, such as the partition walls of the liquid flow path


107


on the common liquid chamber side, does not produce any unfavorable effect on ink discharges even if irregularities are formed slightly on such portion. Here, there is no particular problem to be encountered. There is no influence exerted, either, on the formation of the discharge port


105


as shown in

FIGS. 1A

to


1


C even if the mask


205


and work


204


are slightly deviated when positioned.




In consideration of the aspects described above, the outer shape of the attenuation sections


303


is arranged to be the equally-footed trapezoid of 0.246 mm on the upper bottom and 0.172 mm on the lower bottom in a height of 0.194 mm. Then, the laser processing is performed by use of the mask with the arrangement of


128


patterns at pitches of 0.282 mm, each having the wider region for the attenuation sections


303




a


,


303




b


, and


303




c


, respectively, along the wider external shape of the attenuation sections


303


thus formed. In this way, the second substrate


110


provided with the discharge ports


105


becomes obtainable.




Here, in order to improve the production yield of the second substrate


110


when ink jet recording heads are manufactured in a large scale, the outer shape of the attenuation sections


303


of the mask


205


should be made slightly larger, and it is desirable to perform the laser processing, with the projected image of the outer shape of the attenuation sections


303


being made larger than the sectional configuration of the liquid flow path


107


on the work


204


.




Also, it is possible to manufacture an ink jet recording head having the same effect as described above by the performance of laser processing with the mask having the pattern whose transmissivity is made changeable by 5% provided that the transmissivity of the attenuation section


303




a


is set at 50%,


303




b


at 45%, and


303




c


at 40% as each of the attenuation sections parts farther away from the transmission section


302


as described earlier, while the outer shape of the attenuation sections


303


is made larger approximately by 10%. However, if the transmissivity of the attenuation section


303




c


is made larger than 35%, the wall surface of the liquid flow path


107


is partly processed. It is therefore preferable to set the transmissivity of the attenuation section


303




c


at 35% or less.




Further, in accordance with the present embodiment, the extinction element


304


of the mask


205


is made a square of 0.002 mm per side. Then, it is made smaller than the quotient of 0.008 mm obtainable by dividing the resolution (0.002 mm) of the projection optical system


207


by the specific magnification (¼). In this way, the laser beam is attenuated by means of the attenuation sections


303


to process the wall surface of the tapered liquid flow path


107




b


smoothly as described earlier. However, depending on the condition of the work


204


and that of the laser processing, it is not necessarily to make the size of the extinction element


304


smaller than 0.008 mm. Now, hereunder, the reasons therefor will be described.




Here, for example, it is assumed that a pattern whose size is 0.004 mm is projected on the work


204


in the performance of the laser processing by use of the projection optical system


207


whose resolution is 0.002 mm and specific magnification is ¼ as described for the present embodiment. In this case, the projected image has a larger resolution. Then, on the processing surface of the work


204


, the pattern whose size is 0.004 mm is formed. However, when this 0.004 mm pattern is engraved to a depth of 0.01 mm from the processing surface, the 0.004 mm pattern is collapsed eventually due to the thermal influence exerted at the time of laser processing. Then, there is a fear that the processed surface does not present the anticipated form of the pattern in some cases. The size that allows the work


204


to be processed exactly as the form of pattern may vary depending upon the energy density of the laser beam to be irradiate, the period of time during which the laser beam is irradiated, the material of work


204


, or some others. Depending on these factors, the minimum dimension should be determined to allow the work


204


to be processed exactly as the pattern to be adopted.




Now, therefore, if the minimum value is adopted as the processing resolution, it becomes impossible to form on the work


204


any pattern that may be smaller than the processing resolution determined by the processing condition and the material of the work


204


. However, in this case, too, the wall surface of the tapered discharge port


105


can be processed smoothly by making the size of each extinction element


304


of the mask


205


smaller than the quotient obtainable by dividing the processing resolution of the projection optical system


207


by the specific magnification so that the laser beam is attenuated by the attenuation sections


303


formed by inlaying such extinction elements


304


.




When the work


204


is processed deeper, it is generally observed that the processing resolution at that time becomes larger than the resolution of the projection optical system. As a result, by determining the size of the extinction element in accordance with the processing resolution as described above, the attenuation sections


303


can be formed by the extinction element which is made larger than the one determined on the basis of the resolution of the projection optical system


207


. Consequently, it becomes easier to produce the mask


205


, thus minimizing the costs of manufacture.




Now, for the mask


205


, the size of the extinction element


304


is made smaller than the quotient obtainable by dividing the processing resolution by the resolution of the projection optical system


207


. Then, the laser beam can be attenuated uniformly by means of the attenuation sections


303


formed by the extinction elements


304


, hence making it possible to manufacture the same ink jet recording heads.




Here, in accordance with the present embodiment, polysulfone resin is used as material for the second substrate, and the laser beam emitted from the laser light source


201


is the Kr—F excimer laser whose wavelength is 248 nm.




Also, as the martial for the mask


205


, synthesized quarts or the like having a good laser transmissivity is used for its transmission section of the laser beam. Then, for the light shielding section


305


, the chromium layer is used. Also, one piece of the chromium layer of 0.002×0.002 is used for each of the extinction elements


304


of the attenuation sections


303


.




(Second Embodiment)





FIG. 6

is a cross-view which shows an ink jet recording head most suitably in accordance with a second embodiment of the present invention.




In accordance with the present embodiment, the taper configuration of the discharge port


105


changes on the way as shown in FIG.


6


. Also, there is provided a symmetrically tapered portion


105




a


on the portion connected with the discharge port


105


on the end portion of the recording liquid discharge side, which is symmetrically tapered with respect to the axis of the ink discharge direction.




Then, with such symmetrically tapered portion


105




a


provided for the discharge port


105


, it is made possible to stabilize the discharge direction of recording droplets, thus reducing the twisted discharge thereof.




Therefore, even if the difference between the sectional area of the liquid flow path and that of the discharge port is large, it is possible to position the discharge port


105


as desired with respect to the liquid flow path


107


by changing its taper configuration on the way with the provision of this symmetrically tapered portion


105




a


. With the arrangement thus made, there is an advantage that the volume of the liquid flow path


107


can be secured in the height direction when each of the liquid flow paths


107


should be arranged in higher density.




Also, in consideration of the enhancement of the discharge efficiency, it is preferable to position each discharge port


105


nearer to the position of the substrate


102


. As shown in

FIG. 6

, the sectional configuration of the discharge port


105


is tapered uniformly on the portion nearest to the substrate


102


, while the taper configuration of the ceiling plate


111


side changes on the way. With the discharge port


105


thus structured, the fluid resistance component is made smaller on the portion of the discharge port


105


nearer to the substrate


102


. As a result, particularly when small liquid droplets should be discharged for recording by means of comparatively small bubbling, it becomes more effective to secure a sufficient discharge speed.




Here, the symmetrically tapered portion


105




a


should be good enough if only the taper angles are made symmetrical at least in two directions, one of which is in parallel with the substrate


102


on the axis of the ink discharge direction, and the other is perpendicular to the substrate


102


(the sectional direction shown in FIG.


6


).




Also, there is no problem even if the portion where the taper configuration changes has fine steps in its shape as shown in FIG.


7


.




(Third Embodiment)




Any one of the structures described above is such as to be provided with one discharge energy generating element


101


in one liquid flow path


107


. However, in accordance with the present embodiment, the structure is arranged so that a plurality of discharge energy generating elements


101


is arranged in one liquid flow path


107


.




As shown in

FIG. 8

, two electrothermal converting elements, namely, two discharge energy generating elements, are arranged in the liquid flow path


107


. These two electrothermal converting elements


101


are arranged with the different distances from the discharge port


105


, respectively. Then, the size of the electrothermal converting element


101


on the discharge port


105


side is made smaller than that of the one on the liquid chamber side. Each of the electrothermal converting elements


101


is selectively driven to change the amount of recording droplet discharges. For example, if smaller liquid droplets should be discharged, only the electrothermal converting element on the discharge port


105


side is driven. If larger liquid droplets should be discharged, both of the electrothermal converting elements


101


are driven simultaneously. In this way, recording is possible in binarized gradation. Here, of course, the gradation recording method is not necessarily limited to the method described above.




With the arrangement that enables the discharges of the smaller and larger liquid droplets as described above, printing is made executable at still higher speeds.




In this respect, when the gradation recording is executed, it is desirable to make the difference in the discharge speeds smaller, while the difference is made larger in the amount of liquid droplets between the larger and smaller droplets.




In accordance with the present invention, it is possible to secure a comparatively large amount of larger droplet discharges even with a comparatively small diameter of the discharge port. At the same time, the speed of the smaller droplet discharges is not made lower as compared with the conventional head. Therefore, it becomes possible to make the difference in speeds smaller, while the difference made larger in the amount of larger and smaller droplet discharges.




In accordance with the present embodiment, the structure is arranged so that a plurality of electrothermal converting elements are arranged along the liquid flow path. However, if only the distances from the electrothermal converting elements to the discharge ports should differ from each other, it may be possible to arrange the structure so as to enable them to intersect in the liquid flow path direction. Also, the sizes of the electrothermal converting elements are not necessarily different from each other.




In this respect, the distance from the electrothermal converting element to the discharge port means the distance from the center of area of the electrothermal converting element to the end of the discharge port on the ink discharge side.




Now, in the embodiments described above, the sectional configuration of each liquid flow path that extends from the common liquid chamber is arranged to be equally-footed trapezoidal. However, such configuration is not necessarily limited to it. For example, for the ink jet recording head of the first embodiment, the shape of the opening of the tapered discharge port


105


on the liquid flow path


107


side may be circular, elliptical, or the like that is arranged to be in contact with the inner side of the equally-footed trapezoidal liquid flow path


107


. It should be good enough if only the leading end portion of the liquid flow path is made gradually smaller while it is extended toward the discharge port, and also, the stagnation of ink is smaller in the leading end portion of the liquid flow path when ink is discharged. Also, for the first to third embodiments described above, Kr—F excimer laser is adopted as the laser light source, but it may be possible to use other pulse ultraviolet laser, such as Xe—Cl excimer laser. It may also be possible to use the fourth higher harmonic waves of YAG laser; the fundamental waves of the YAG laser; the second higher harmonic waves of YAG laser; the mixing waves of the fundamental and second higher harmonic waves of the YAG laser; the nitrogen gas laser beam, or the like.




Also, for the light shielding section of the mask and the extinction element of the attenuation sections, chromium layer is used. However, aluminum, phosphor bronze, nickel, or the like may be used.




Also, for the discharge energy generating element, an electrothermal converting element is used, but piezoelectric element (piezo element) or the like may be used.




As described above, the present invention makes it possible to produce effect on stabilizing the discharge speeds of recording droplets, particularly when printing is made at higher speeds by arranging to make the shape of the leading end portion gradually smaller for each of the liquid flow paths on the discharge port side, which is extended in one direction to be communicated with the common liquid chamber to the discharge port, so as to make the fluid resistance of recording liquid smaller for the stabilization of discharge speeds of recording droplets. Further, when smaller droplets should be discharged, the discharge speeds are enhanced, while maintaining the stability of the discharge speeds, thus suppressing the generation of mist of recording liquid that may be caused when smaller liquid droplets are discharged. As a result, the present invention is remarkably effective on recording images in high precision.




Also, in accordance with the present invention, when each of the liquid flow paths which is configured to be extended toward the discharge port, while its leading end portion being made gradually smaller, and the discharge port that is communicated with the liquid flow path are formed, the laser beam is irradiated for processing from the common liquid chamber side to the plate portion where each of the discharge ports is formed through the mask which is provided with the transmission section that transmits the laser beam to regulate the configuration of each discharge port as well as with the attenuation sections formed on the outer circumference of the transmission section, which make the transmissivity of the laser beam smaller gradually as each of them parts farther away from the transmission section. With such arrangement, it is made possible to produce effect on the formation of each of the discharge ports, the leading end portion of liquid flow path on the plate portion stably in good processing precision. Also, there is no need for the preparation of plural masks when processing the leading end portion in such shape as described above. Therefore, there is an effect that the discharge ports can be formed with ease at lower costs. As a result, it is made possible to provide an ink jet recording head capable of recording images in higher precision, while minimizing the costs of its manufacture.



Claims
  • 1. A method for manufacturing an ink jet recording head provided with a plurality of discharge ports for discharging recording liquid, a discharge port plate having said discharge ports therein, a liquid chamber for retaining said recording liquid, a plurality of discharge energy generating elements for discharging said recording liquid, a substrate having said plurality of discharge energy generating elements on one surface thereof, and a plurality of liquid flow paths extended in one direction for communicating said liquid chamber with said discharge ports, said liquid flow paths each having a rectangular cross-section, and said discharge ports being formed by irradiating a laser beam on a member which thereby becomes said discharge port plate through a mask having specific patterns thereon,said mask including a transmission section which regulates a shape of said discharge ports, and an attenuation section formed on an outer circumference of said transmission section so that the further the attenuation section is from the transmission, the less the laser beam becomes, and forming the discharge ports by irradiating the laser beam through the mask to said member, each said port having a cross-sectional shape which gradually tapers from a rectangular shape at a side of the port connected with said liquid flow path to a circular shape at a recording liquid discharge side of the port.
  • 2. A method for manufacturing an ink jet recording head according to claim 1, wherein the patterns on said mask are provided with a light shielding section formed on an outer circumference of said attenuation section to suppress an energy density of the laser beam to be equal to or less than a processing threshold value of the member becoming said discharge plate.
  • 3. A method for manufacturing an ink jet recording head according to claim 1, wherein said attenuation section of said mask is arranged to reduce the transmission of the laser beam by 10% with increasing distance from said transmission section.
  • 4. A method for manufacturing an ink jet recording head according to claim 1, wherein said attenuation sections are formed by scattering a plurality of extinction elements reflecting or absorbing the laser beam from the laser light source.
  • 5. A method for manufacturing an ink jet recording head according to claim 4, wherein the size of said extinction elements is smaller than the quotient obtained by dividing a resolution of a projection optical system by a predetermined magnification of the projection optical system.
  • 6. A method for manufacturing an ink jet recording head according to claim 4, wherein the size of said extinction elements is smaller than the quotient obtained by dividing a processing resolution determined by the processing condition of a laser processing apparatus used for the processing by a specific magnification of a projection optical system.
  • 7. A method for manufacturing an ink jet recording head according to claim 4, wherein said extinction elements make an energy density of the laser beam transmitting said extinction elements equal to or lower than a processing threshold value of the member becoming said discharge plate.
  • 8. A method for manufacturing an ink jet recording head according to claim 4, wherein said extinction elements shield the laser beam incident upon said extinction elements by 10%.
  • 9. A method for manufacturing an ink jet recording head according to claim 1, wherein said laser beam is an excimer laser beam.
Priority Claims (2)
Number Date Country Kind
9-179760 Jul 1997 JP
10-180943 Jun 1998 JP
US Referenced Citations (5)
Number Name Date Kind
5237148 Aoki et al. Aug 1993
5538817 Smith et al. Jul 1996
5539175 Smith et al. Jul 1996
5748213 Karita et al. May 1998
5948289 Noda et al. Sep 1999
Foreign Referenced Citations (8)
Number Date Country
0 309 146 Mar 1989 EP
0 419 190 Mar 1991 EP
0 419 181 Mar 1991 EP
0 495 663 Jul 1992 EP
0 624 471 Nov 1994 EP
0 739 739 Oct 1996 EP
0625095 Dec 1997 EP
5-338157 Dec 1993 JP