Information
-
Patent Grant
-
6422686
-
Patent Number
6,422,686
-
Date Filed
Wednesday, May 24, 200024 years ago
-
Date Issued
Tuesday, July 23, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Barlow; John
- Mouttet; Blaise
Agents
- Fitzpatrick, Cella, Harper & Scinto
-
CPC
-
US Classifications
Field of Search
US
- 347 47
- 347 63
- 347 65
- 029 8901
-
International Classifications
-
Abstract
In a liquid discharge head having an orifice plate in which a plurality of discharge ports for discharging liquid droplets therethrough are arranged, and a head body provided with a plurality of flow paths communicating with the plurality of discharge ports, a liquid chamber for supplying liquid to the plurality of flow paths, and a plurality of energy generation elements disposed correspondingly to the plurality of flow paths and generating energy for discharging the liquid droplets, the orifice plate being joined to the joined surface of the head body in which the communication ports of the flow paths communicating with the discharge ports are disposed, the orifice plate is formed with wall-shaped convex portions protruding from the inner peripheral portions of the discharge ports and having at least a portion thereof entering from the communication ports into the flow paths, and the width of the wall-shaped convex portions is greater in the portions thereof parallel to the row direction in which the plurality of discharge ports are arranged than in the portions thereof orthogonal to the row direction.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a liquid discharge head for discharging liquid and effecting recording by flying liquid droplets. More particularly, the invention relates to a liquid discharge head applicable to an apparatus such as a facsimile apparatus having a printer, a copier and a communication system for effecting recording on a recording medium such as paper, thread, fiber, cloth, leather, metals, plastics, glass, wood or ceramics, and a word processor having a printer portion, and further an industrial recording apparatus compositely combined with various processing apparatuses, and a method of manufacturing the liquid discharging head.
“Recording” in the present invention means not only imparting images such as characters and figures having meanings to a recording medium, but also imparting images such as patterns having no meaning to the recording medium.
2. Related Background Art
An ink jet recording apparatus for discharging recording liquid (ink) from the discharge port (orifice) of a liquid discharge head to thereby effect recording is known as a recording apparatus excellent in such points is low noise and high-speed recording. As such ink jet recording apparatuses, ones of various types have heretofore been proposed and improved, and some of them have already been commercialized or are being developed for practical use.
An example of the ink jet recording apparatus according to the prior art, as shown in
FIGS. 14 and 15
of the accompanying drawings, has a liquid discharge head comprised of an orifice plate
200
for discharging ink, a top plate
210
for forming a flow path
202
communicating with a discharge port
201
, and a substrate
204
having an energy generation element
203
provided in the flow path
202
and generating energy for discharging liquid.
The minute discharge port
201
for liquid discharge provided in the orifice plate
200
is an important element which governs the discharging performance of the liquid discharge head. That is, the orifice plate
200
of the liquid discharge head is required to be formed of a material having good workability for forming the minute discharge port
201
and having a good ink-resisting property for the direct contact with the ink. Heretofore, as a material satisfying such conditions, use has been made of a metal plate of stainless steel, nickel, chromium, aluminum or the like, or resin film easy to obtain a desired thickness and inexpensive, such as polyimide, polysulfone, polyether sulfone, polyphenylene oxide, polyphenylene sulfide or polypropylene.
Japanese Patent Application Laid-Open No. 2-204048 discloses a liquid discharge head of a construction in which a portion of an orifice plate enters into a flow path to improve discharge efficiency. Specifically, this liquid discharge head is of a construction in which a part of the material forming the orifice plate is softened by heat and comes into the flow path, and thereafter forms a discharge port. Further, U.S. Pat. No. 5,604,521 discloses a liquid discharge head which uses an orifice plate having a convex portion formed with an orifice and provided on a joined surface with the main body of the head and in which adhesive resin is applied to the joined surface of the orifice plate, whereafter the convex portion is fitted into a flow path.
However, when the liquid discharge head has the convex portion to be fitted into the orifice, the discharge port assumes a tapered shape and therefore, when the flow path is to be highly densely arranged, the highly dense arrangement of the convex portion has been limited.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a liquid discharge head having:
an orifice plate in which a plurality of discharge ports for discharging liquid droplets therethrough are arranged in a row; and
a head body provided with a plurality of flow paths communicating with the plurality of discharge ports, a liquid chamber for supplying liquid to the plurality of flow paths, and a plurality of energy generation elements disposed correspondingly to the plurality of flow paths and generating energy for discharging the liquid droplets;
the orifice plate being joined to the joined surface of the head body in which the communication ports of the flow paths communicating with the discharge ports are disposed;
characterized in that the orifice plate is formed with wall-shaped convex portions protruding from the inner peripheral portions of the discharge ports and having at least a portion thereof entering from the communication ports into the flow paths, and
the width of the wall-shaped convex portions is greater in the portions thereof parallel to the row direction in which the plurality of discharge ports are arranged than in the portions thereof orthogonal to the row direction.
It is another object of the present invention to provide a liquid discharge head having:
an orifice plate in which a plurality of discharge ports for discharging liquid droplets therethrough are arranged in a row; and
a head body provided with a plurality of flow paths communicating with the plurality of discharge ports, a liquid chamber for supplying liquid to the plurality of flow paths, and a plurality of energy generation elements disposed correspondingly to the plurality of flow paths and generating energy for discharging the liquid droplets;
the orifice plate being joined to the joined surface of the head body in which the communication ports of the flow paths communicating with the discharge ports are disposed;
characterized in that the orifice plate is formed with wall-shaped convex portions protruding from the inner peripheral portions of the discharge ports and having at least a portion thereof entering from the communication ports into the flow paths, and
on the joined surface side of the orifice plate to the head body, as compared with the inner end portions of the discharge ports at positions orthogonal to the row direction in which the plurality of discharge ports are arranged, the wall-shaped convex portions located in parallelism to the row direction are formed high in the direction of thickness of the orifice plate.
It is still another object of the present invention to provide a method of manufacturing a liquid discharge head having:
an orifice plate in which a plurality of discharge ports for discharging liquid droplets therethrough are arranged in a row; and
a head body provided with a plurality of flow paths communicating with the plurality of discharge ports, a liquid chamber for supplying liquid to the plurality of flow paths, and a plurality of energy generation elements disposed correspondingly to the plurality of flow paths and generating energy for discharging the liquid droplets;
the orifice plate being joined to the joined surface of the head body in which the communication ports-of the flow paths communicating with the discharge ports are disposed;
characterized in that the orifice plate is formed with wall-shaped convex portions protruding from the inner peripheral portions of the discharge ports and having at least a portion thereof entering from the communication ports into the flow paths, and
the wall-shaped convex portions are formed by laser working after the discharge ports have been formed by laser working.
Other objects and features of the present invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a typical cross-sectional view showing the essential portions of a liquid discharge head according to a first embodiment of the present invention.
FIG. 2
is a perspective view, partly in cross-section, of the liquid discharge head shown in FIG.
1
.
FIG. 3
is an enlarged perspective view of the back of an orifice plate shown in FIG.
1
.
FIG. 4
schematically shows the construction of a laser working apparatus used in a first method of manufacturing the orifice plate shown in FIG.
1
.
FIG. 5
is a fragmentary enlarged view of a mask used in the manufacture of the orifice plate by the laser working apparatus shown in FIG.
4
.
FIG. 6
schematically shows the construction of a manufacturing line used in a second method of manufacturing the orifice plate shown in FIG.
1
.
FIG. 7
is an enlarged perspective view of the back of an orifice plate according to a second embodiment of the present invention.
FIG. 8
is an enlarged perspective view of the back of an orifice plate according to a third embodiment of the present invention.
FIG. 9A
is an enlarged rear view of an orifice plate according to a fourth embodiment of the present invention, and
FIG. 9B
is a cross-sectional view of the essential portions of the liquid discharge head thereof.
FIG. 10
is an enlarged perspective view of the back of an orifice plate according to a fifth embodiment of the present invention.
FIG. 11A
is an enlarged rear view of an orifice plate according to a sixth embodiment of the present invention, and
FIG. 11B
is a cross-sectional view thereof.
FIG. 12
is a cross-sectional view of the essential portions of an orifice plate according to a seventh embodiment of the present invention.
FIG. 13
is a cross-sectional view of the essential portions of a liquid discharge head according to an eighth embodiment of the present invention.
FIG. 14
is a typical cross-sectional view showing an example of the liquid discharge head according to the prior art.
FIG. 15
is an exploded perspective view showing an example of the liquid discharge head according to the prior art.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Some embodiments of the present invention will hereinafter be described with reference to the drawings.
FIGS. 1 and 2
show a liquid discharge head according to a first embodiment of the present invention. A top plate
400
formed with a plurality of flow paths
401
and groove-shaped recesses for constituting a single liquid chamber
402
communicating with the plurality of flow paths
401
, and a base plate (heater board)
100
comprising a Silicon substrate on which energy generation elements (in the present embodiment, heaters which are heat generation elements)
101
for generating discharge energy and wiring of aluminum (not shown) for supplying an electrical signal thereto are formed by the film forming technique are joined together, whereby a head body
20
is constructed. The top plate
400
and the base plate
100
are joined together, thereby the flow paths
401
and the liquid chamber
402
are constructed between the top plate
400
and the base plate
100
.
An orifice plate
40
is stuck on an opening disposition surface (the joined surface of the head body
20
)
44
in which the communication port (the fore end opening portion) of each flow path
401
is located, by an adhesive layer
42
. The orifice plate
40
in the present embodiment comprises polysulfone film having a thickness of 50 μm. The orifice plate
40
is provided with a plurality of discharge ports
41
communicating with the respective flow paths
401
, and a convex portion
45
protruding from the inner wall of each discharge port
41
to the head body
20
side is integrally formed. This convex portion
45
enters into the inside of the communication port of each flow path
401
. The convex portions
45
and the discharge ports
41
are formed into a tapered shape.
FIG. 3
shows an enlarged view of the convex portions in the present embodiment as they are seen from the inner surface (back) side of the orifice plate. In the present embodiment, the wall-shaped convex portion
45
is formed along the entire inner peripheral portion of each discharge port
41
. This convex portion
45
is thinner in a portion
45
b
orthogonal to the row direction R in which the discharge ports are arranged than in a portion
45
a
parallel to the row direction. Thereby, the spacing between the convex portions corresponding to adjacent ones of the discharge ports
41
can be secured and therefore, the highly dense arrangement of the discharge ports
41
becomes possible. For example, the density of 600 to 720 dpi (dots per inch) at a pitch of the order of 35.5 to 42.5 μm can be adopted.
By these convex portions
45
, the discharge ports
41
of the orifice plate
40
and the flow paths
401
of the head body
20
can be connected together without gaps, and the flow of ink becomes smooth and improvements in the discharge speed of the ink and the quality of print as well as in the discharge efficiency can be achieved. Also, the discharge ports
41
of the orifice plate
40
and the flow paths
401
of the head body
20
can be easily connected together with good accuracy and moreover, the strength of the joint between the orifice plate
40
and the head body
20
is heightened. The adhesive overflowing the adhesive layer
42
can be prevented from entering into the flow paths
401
to thereby change the characteristic of the flow paths.
According to this liquid discharge head, the liquid (ink) is supplied from the liquid chamber
402
to the flow paths
401
. Driving means, not shown, selects a flow path
401
to discharge the ink in conformity with an image to be formed, and supplies a driving signal to a heater
101
in the selected flow path
401
. The heater
101
which has received the driving signal generates heat, and heats the ink in the flow path
401
. The heated ink bubbles, and ink droplets are discharged outwardly from the discharge port
41
by pressure accompanying the growth of the bubble. The ink droplets discharged outwardly adhere to a recording medium (such as recording paper), not shown, and an image is formed on the recording medium. In the present embodiment, by the convex portions
45
being formed, the flow of the ink from the flow path
401
to the discharge port
41
is smooth and discharge efficiency is good.
The material of the orifice plate
40
may desirably be metal film such as stainless steel or nickel, or plastic film excellent in ink-resisting property, for example, a resin film material such as polyimide, polysulfone, polyether sulfone, polyphenylene oxide, polyphenylene sulfide or polypropylene.
Description will now be made of a method of manufacturing the liquid discharge head of the present invention.
Two methods will first be described as methods of manufacturing the orifice plate
40
.
FIG. 4
schematically shows the construction of a laser working apparatus used in a first method of manufacturing the orifice plate. This laser working apparatus has a laser oscillator
1
which is a laser source emitting a laser beam
2
, an apparatus frame
6
provided with a working system for effecting the working of a workpiece W by the laser beam from the laser oscillator
1
, and an information processing and controlling system
7
for effecting the information processing and control regarding the working of the workpiece W.
As the laser oscillator
1
used in the laser working apparatus, one of a high output such as a YAG laser oscillator, a CO
2
laser oscillator, an excimer laser oscillator or an N
2
laser oscillator would occur to mind, and in the present embodiment, use is made of a Kr—F excimer laser oscillator of excimer laser oscillators.
The apparatus frame
6
has an optical system
8
, an observation and measuring system
9
for observing and measuring the position of the workpiece W, a mask
10
and a work station
11
for moving the workpiece W. The optical system
8
has a beam forming optical system and Koehler illumination system
8
a
disposed on the optical axis a of the laser beam
2
entering the apparatus frame
6
, and a projection optical system
8
b
for forming the image of the mask
10
on the worked surface of the workpiece W, and the mask
10
is disposed between the beam forming optical system and Koehler illumination system
8
a
and the projection optical system
8
b.
FIG. 5
shows the mask
10
on an enlarged scale. The mask
10
in the present embodiment is partly changed in the laser beam transmittance per working unit area in order to work the orifice plate
40
of the liquid discharge head of the aforedescribed construction, and the transmittance of areas (discharge port forming portions)
50
corresponding to the discharge ports
41
shown in
FIG. 1
is 100%, the transmittance of areas (convex portion forming portions)
51
corresponding to the convex portions
45
is 0%, and the transmittance of the other portion
53
is 30%.
The projection optical system
8
b
should preferably be a reduction optical system when the durability of the mask
10
is taken into account. In the present embodiment, a projection optical system
8
b
of a reduction of ¼ times is provided.
Although the detailed construction of the work station
11
is not shown, the work station
11
may preferably be provided with suitable adjusting means to adjust the inclination of the workpiece W with respect to the optical axis a. For example, the work station
11
may be constituted by a combination of three shafts orthogonal to one another and a stage having a degree of freedom with respect to the five axes of rotation about two axes. By adopting a construction in which the center for the adjustment of rotation is made coincident with the center of working of the workpiece W, the control of the adjusting means can be simplified.
A plurality of reference pins to be rammed against the workpiece W disposed on the work station
11
may preferably be provided on a jig
11
a
for mounting the workpiece W on the work station
11
for the positioning of the workpiece W on the work station
11
. Also, besides the above-described ramming mechanism, a clamp mechanism using air suction or the like may preferably be provided on the jig
11
a
and be made integral with an auto-hand to thereby make the automatic supply of the workpiece W to the work station
11
possible. Further, a plurality of workpieces W may be set on the work station
11
at a time to thereby shorten the reserve time. In this case, however, an axis in the direction of rotation of the adjusting means cannot be disposed at the center of the workpieces W and therefore, it is necessary to effect the conversion of a reference value during measurement and during the movement of the workpieces W.
The observation and measuring system
9
is comprised of a pair of observation devices and a two-surface mirror
9
d
disposed on the optical axis a. Each of the observation devices comprises a lens barrel
9
a
provided with an objective lens, an epi illumination light source
9
b
incorporated in the lens barrel
9
a
, and a CCD camera sensor
9
c
connected to the lens barrel
9
a.
Each observation device and the mirror
9
d
are disposed between the projection optical system
8
b
and the work station
11
, and design is made such that the mirror
9
d
is off the optical axis a during the application of the laser, and is moved on the optical axis a only during measurement. In the present embodiment, the movement of the mirror
9
d
is controlled by an air cylinder mechanism, not shown.
The position data of the workpiece W from the observation and measuring system
9
and the data of beam power from a power detector
4
are fed back to the information processing and controlling system
7
. Specifically, the information processing and controlling system
7
has an image processing system
7
a
connected to each observation device, a control system
7
b
connected to the image processing system
7
a
, moving means
7
c
connected to the control system
7
b
for effecting the movement of the workpiece W on the work station
11
, and an interface
7
d
connected to the control system
7
b
and the laser oscillator
1
.
Polysulfone film which provides the orifice plate
40
is set as the workpiece W shown in
FIG. 4
in the work station
11
. The laser beam
2
is applied from the laser oscillator
1
. A part of the laser beam
2
emitted from the laser oscillator
1
is reflected by a beam splitter
3
, and the reflected light is monitored by the power detector
4
. On the other hand, a part of the laser beam
2
transmitted through the beam splitter
3
is reflected by two 45° total reflection mirrors
5
and enters the apparatus frame
6
. The beam splitter
3
is a plane parallel plate of synthetic quartz and separates a part of the laser beam
2
by only surface reflection.
The laser beam
2
which has entered the apparatus frame
6
is transmitted through the beam forming optical system and Koehler illumination optical system
8
a
, and causes the image of the mask
10
to be formed on the worked surface of the workpiece W by the projection optical system
8
b.
In the present embodiment, the application of the laser was effected under the condition of about 1 (J/cm
2
·puls) and 200 to 400 puls, and the cutting of the polysulfone film by laser ablation was effected. As previously described, the mask
10
has its laser beam transmittance divided into 100%, 30% and 0% and therefore is worked in conformity with these transmittances. A cross-sectional view of the orifice plate
40
is shown in FIG.
1
. That is, the portion of the transmittance 100% provides the discharge port extending completely through the polysulfone film, and the portion of the transmittance 30% is made thin to a certain degree (in the present embodiment, film having a thickness of about 50 μm is cut by the order of 10 to 20 μm into a thickness of 30 to 40 μm). The portion of the transmittance 0% is not cut, but provides a relative convex portion
45
.
On the other hand, when a part of the laser beam
2
applied from the laser oscillator
1
is reflected by the beam splitter
3
and enters the power detector
4
, the data of beam power is delivered from the power detector
4
to the image processing system
7
a
of the information processing and controlling system
7
. The result of the processing by the image processing system
7
a
is then sent to the control system
7
b
. Also, the position data of the workpiece W is fed back from the CCD camera sensor
9
c
of the observation and measuring system
9
to the control system
7
b
of the information processing and controlling system
7
.
The control system
7
b
calculates the movement distance of the workpiece W on the basis of the supplied data or the like, operates the moving means
7
c
and effects the movement of the stage on which the workpiece W is placed in the work station
11
. When the position data measured by the observation and measuring system
9
assumes a predetermined value, the position adjustment by the moving means
7
c
is terminated, and the mirror
9
d
is deviated from the optical axis a, and a signal for effecting the emission of the laser beam
2
is supplied to the laser oscillator
1
for a predetermined time or by a predetermined pulse number. Also, the beam power information from the power detector
4
is fed back to the control system
7
b
, where the adjustment of the magnitude of the output given to the laser oscillator
1
through the interface
7
d
is effected. The cutting of the polysulfone film by the laser ablation is effected as described above while such control is effected, to thereby form the discharge ports
41
, the convex portions
45
and the other portion. Thus, the manufacture of the orifice plate
40
is completed.
While in the above-described embodiment, there is shown a construction in which the discharge ports and the convex portions are worked at a time by laser working, it is also possible to work the discharge ports and the convex portions by discrete steps. In this case, after the discharge ports are laser-worked, the shape of the convex portions is laser-worked, whereby the working of the discharge ports can be accomplished irrespective of the shape of the convex portions and therefore, it desirably becomes possible to secure a large diameter for the discharge ports.
FIG. 6
typically shows a portion of a manufacturing line used in a second method of manufacturing the orifice plate. In this manufacturing line, the steps of extruding molten resin into the form of film by extrusion molding, and pressing a roll provided with a relief mold of a predetermined shape against the surface of the extruded film-like resin to thereby form a pattern of a desired shape on the surface of the film-like resin are carried out.
As shown in
FIG. 6
, molten resin is extruded into the form of film from the die
302
of an extrusion molding machine
301
, whereby film-like resin
303
is formed, and the film-like resin
303
is nipped between a cooling roll
305
and a nip roll
306
and is pressed by those rolls. A relief mold
304
of a shape conforming to the discharge ports
41
and the convex portions
45
shown in
FIGS. 1
to
3
is attached to the surface of the cooling roll
305
. A desired shape is continuously formed on the surface of the film-like resin
303
by this relief mold
304
.
The film-like resin
303
on the surface of which the desired shape has been formed by the relief mold
304
and which has been cooled by the cooling roll
305
passes several rolls and two take-over rolls
307
, and thereafter is taken up into the form of a roll by a take-up roll
308
.
In this example of the method of manufacturing the orifice plate, polysulfone resin (Udel P3900 produced by Amoco Inc.) was used as the resin material extruded from the extrusion molding machine
301
. It is preferable that a thermoplastic polymer be used as the resin material extruded from the extrusion molding machine
301
, i.e., the material of the film-like resin
303
. Also, specifically, it is preferable that one of polysulfone, polyether sulfone, polyphenylene sulfide and polyether ether ketone be used as the material of the film-like resin
303
.
A method of making the orifice plate
40
will now be described.
Polysulfone resin is first extruded from the die
302
under the following working conditions so as to assume a thickness of 50 μm to thereby form film-like resin
303
. The film-like resin
303
is pressed by the cooling roll
305
of a temperature of 15° C. having the relief mold
304
provided on the surface thereof and the nip roll
306
to thereby cool the film-like resin
303
.
Extrusion Working Conditions
Die opening: 0.5 mm
Set temperature of the extruder: rear portion 315° C., intermediate portion 360° C., head and die portion 370° C.
Temperature of the cooling roll: 15° C.
Extrusion thickness: 50 μm
Nip pressure (air gauge pressure): 2 kgf/cm
2
The relief mold
304
of the cooling roll
305
is pressed against the surface of the film-like resin
303
, and by this relief mold
304
, a plurality of discharge ports
41
and convex portions
45
as shown in
FIG. 3
are continuously formed at a time in and on the film-like resin
303
in the extrusion direction of the film-like resin
303
.
After the discharge ports
41
and the convex portions
45
have been formed in and on the film-like resin
303
by the relief mold
304
, a water repellent layer is formed on that surface (face surface) of the film-like resin
303
which is opposite to the convex portions
45
. As a water repellent treating agent, use was made of CTx-CZ5A produced by Asahi Glass Co., Ltd. When a water repellent layer is to be formed on the face surface of the film-like resin
303
, the face surface is first made hydrophilic by corona treatment, whereafter a water repellent agent is applied to the face surface of the film-like resin
303
by the use of a microgravure coater produced by Yasui Seiki Co., Ltd. as an applying apparatus. Here, the step of applying the water repellent agent and the step of prebaking the applied water repellent agent at 80° C. so that the final thickness of the water repellent layer might be 0.1 μm were continuously carried out. The film-like resin
303
taken up into the form of a roll after such applying and prebaking steps have been completed is heated at a temperature of 150° C. for 5 hours in a heating furnace, whereby a water repellent layer is formed on the face surface of the film-like resin
303
.
While in the method of manufacturing the liquid discharge head according to the present embodiment, the step of pressing the relief mold
304
against the film-like resin
303
and the step of forming the water repellent layer on the film-like resin
303
have been discretely carried out, those two steps may be carried out at a single step. For example, at the step of pressing the relief mold
304
against the film-like resin
303
, the pressing work against the film-like resin
303
may be done while the water repellent agent is supplied to that surface of the film-like resin
303
which is adjacent to the nip roll
306
to thereby form a water repellent layer on that surface. Alternatively, a coating roll for applying the water repellent agent may be set at a location before the film-like resin
303
is taken up by the take-up roll
308
, and the water repellent agent may be applied to the film-like resin
303
by the use of the coating roll.
The film-like resin
303
in and on which the discharge ports
41
and the convex portions
45
have been formed in this manner and which has been wound into the form of a roll is cut into a necessary size for each liquid discharge head, whereby the orifice plate
40
shown in
FIG. 3
is made.
Description will now be made of a method of manufacturing the liquid discharge head after the orifice plate
40
has been made.
The orifice plate
40
is made by one of the aforedescribed methods, while on the other hand, the top plate
400
and the base plate
100
are formed separately, and these are adhesively secured to each other in their layered state to thereby constitute the head body
20
. In order to uniformize the opening forming surface (joined surface)
44
of the head body
20
, it is preferable to cut the top plate
400
and the base plate
100
perpendicularly to the surfaces of the plates after they have been layered and secured to each other, and form the communication ports of the flow paths
401
in this cut surface to thereby provide the opening forming surface
44
.
The orifice plate
40
is secured to this opening forming surface (joined surface)
44
of the head body
20
by an epoxy adhesive layer
42
. At this time, each discharge port
41
communicates with each flow path
401
, and the convex portions
45
are aligned so as to come into the respective flow paths
401
.
As the adhesive used here, use is made of an epoxy adhesive which can be made into 13 stage (medium hardened state) while keeping tackiness (viscosity) by UV (ultraviolet rays) being applied to the adhesive, and can adhesively secure members to each other by heating and pressing or further application of UV to the adhesive after the adhesive has been hardened and constricted. Such an adhesive can also secure members to each other by only heating and pressing without being made into B stage.
Specifically, the epoxy adhesive as described above is transferred to the joined surface of the head body
20
by the transferring method. Next, ultraviolet rays of 1 mW/cm
2
are applied to the transferred adhesive for 60 seconds to make the adhesive into B stage, and the hardening and constriction of the adhesive are terminated while the tackiness of the adhesive is kept.
Next, the convex portions
45
of the orifice plate
40
are brought into the corresponding flow paths
401
, and the convex portions
45
are fitted into the fore end opening portions (communication ports) of the flow paths
401
. The fitting between the convex portions
45
and the flow paths
401
is clearance fit. Thus, a load of 1 kg/cm
2
is applied to the orifice plate
40
from that surface of the orifice plate
40
positioned relative to the head body
20
which is opposite to the convex portions
45
to thereby bring the orifice plate
40
and the head body
20
into close contact with each other, and while keeping that state, the orifice plate
40
is heated at a temperature of 60° C. and pressed against the head body
20
, and the hardening of the adhesive is terminated.
The liquid discharge head shown in
FIGS. 1 and 2
is manufactured by way of the above-described steps.
According to the aforedescribed method of manufacturing the liquid discharge head, an orifice plate
40
is not made by being divided, but is made as an integral one and therefore, even when an orifice
40
having a number of discharge ports
41
is to be made, there is no seam and the dimensional accuracy of the discharge ports
41
, the convex portions
45
, etc. become good. Thereby, the disadvantage that the convex portions
45
of the orifice plate
40
cannot be fitted into the flow paths
401
of the head body
20
is eliminated. Also, in the evaluation when recording was effected by the use of the manufactured liquid discharge head, there were not disadvantages such as the twist of flying liquid droplets and the irregularity of recorded images caused by the badness of the seam portions of the orifice plate
40
when the orifice plate
40
was made by being divided, and good recording dignity was obtained.
Also, the working time for manufacturing a liquid discharge head of good liquid discharge efficiency can be shortened and improved productivity can be achieved. Very highly accurate alignment becomes unnecessary during working and therefore, manufacture becomes easy and moreover, the simplification of the manufacturing apparatus becomes possible.
Further, in the aforedescribed second method of manufacturing the orifice plate, a laser is not used to form the discharge ports
41
and the convex portions
45
and therefore, there is no production of a byproduct such as carbon and thus, the labor of post-treatment is not required and a large-scale laser working machine is unnecessary, and the cost of an apparatus for manufacturing the liquid discharge head can be made low.
A second embodiment of the present invention will now be described with reference to FIG.
7
. This embodiment is of a construction in which the height of the wall-shaped convex portions of the orifice plate is changed, and in the other points, the construction of the present embodiment is substantially the same as that of the first embodiment. Portions similar in construction to those of the first embodiment are given the same reference characters and need not be described.
FIG. 7
shows an enlarged view of convex portions
145
in the present embodiment as they are seen from the inner surface (back) side of an orifice plate
140
. In the present embodiment, the wall-shaped convex portions
145
are formed along the entire inner peripheral portions of discharge ports
141
. These convex portions
145
are lower in portions
145
b
orthogonal to the row direction R in which the discharge ports
141
are arranged than in portions
145
a
parallel to the row direction R and therefore, the thickness of the walls is small and highly dense arrangement can be coped with. The adhesive applied to the narrow portion between adjacent ones of the discharge ports
141
is small in quantity and therefore, even the relatively low wall-shaped convex portions
145
b
can interrupt any overflowing adhesive. In contrast, a large quantity of adhesive is applied to the portion of wide area outside the row formed by the plurality of discharge ports
141
and therefore, a large quantity of adhesive may overflow. In the present embodiment, relatively tall wall-shaped convex portions
145
a
are formed to interrupt the overflowing adhesive and therefore, excellent manufacturing stability and reliability are obtained for the quantity of overflowing adhesive. In the present embodiment, the height of the portions
145
b
of the wall-shaped convex portions
145
for interrupting the adhesive overflowing from the narrow portion between adjacent ones of the discharge ports
141
which are orthogonal to the row direction is small, and the height of the portions
145
a
of the wall-shaped convex portions
145
for interrupting the adhesive overflowing from the portion of wide area outside the row formed by the discharge ports
141
which are parallel to the row direction is great. The heights of the portions
145
b
of the wall-shaped convex portions
145
which are orthogonal to the row direction and the portions
145
a
of the wall-shaped convex portions
145
which are parallel to the row direction are thus suitably set in conformity with the quantity and kind (characteristic) of the applied adhesive, whereby the convex portions
145
of necessary minimum height can be formed and this is good in efficiency.
A third embodiment of the present invention will now be described with reference to FIG.
8
. Portions similar in construction to those of the first and second embodiments are given the same reference characters and need not be described.
FIG. 8
shows an enlarged view of convex portions
245
in the present embodiment as they are seen from the inner surface (back) side of an orifice plate
240
. In the present embodiment, the wall-shaped convex portions
245
are provided not along the entire inner peripheral portions of discharge ports
241
, but only in portions parallel to the row direction R in which the discharge ports
241
are arranged, and are not provided in portions orthogonal to the row direction R. This is a construction in which the adhesive applied to the narrow portion between adjacent ones of the discharge ports
241
is regarded as hardly coming into the flow paths and only the adhesive overflowing from the portion of wide area outside the row formed by the discharge ports
241
is interrupted. According to this, the discharge ports
241
can be made more highly dense. For example, the density can be of the order of 1200 dpi at a pitch of 21.25 μm.
In a fourth embodiment shown in
FIGS. 9A and 9B
, in addition to the construction of the third embodiment, interruption wall portions
346
parallel to the row direction in which discharge ports
341
are arranged are formed outside the portions of wall-shaped convex portions
345
which are also parallel to the row direction. The interruption wall portions
346
, unlike the wall-shaped convex portions
345
, are provided not at locations entering into the communication ports of flow paths
401
, but at locations whereat they abut against the opening forming surface (joined surface)
44
of the head body
20
during joint. Further outside these interruption wall portions
346
, there are provided groove portions
347
also parallel to the row direction.
According to the present embodiment, design is made such that at a location separate from the flow paths, the inflow of an adhesive
348
is interrupted by the interruption wall portions
346
and further, the overflowing adhesive
348
is contained in the groove portions
347
and therefore, the inflow of the adhesive
348
into the flow paths
401
can be prevented more reliably. Also, the area of application of the adhesive in the orifice plate
340
is large due to the unevenness of the groove portion
347
and the interruption wall portions
346
and therefore, the strength of the joint between the orifice plate
340
and the head body
20
by the adhesive is improved.
In a fifth embodiment of the present invention shown in
FIG. 10
, the shape of wall-shaped convex portions
445
differs from that in the fourth embodiment. That is, the wall-shaped convex portions
445
are provided only in portions parallel to the row direction in which discharge ports
441
are arranged, and the inner sides of these convex portions
445
(the surfaces facing the discharge port
441
side) are curved surfaces
445
a
similar to the discharge ports
441
. Thereby, the directional stability of ink discharge is heightened. Further, in the present embodiment, the wall-shaped convex portions
445
have their opposite end portions
445
b
formed into a tapered shape so as to be lengthwisely tapered. Thereby, the work of bringing the convex portions
445
into the communication ports of flow paths
401
can be done easily.
As in the fourth embodiment, there are provided interruption wall portions
446
and groove portions
447
parallel to the row direction in which the discharge ports
441
are arranged. Thereby, the entry into the adhesive into the flow paths
401
can be prevented and also, the strength of the joint between the orifice plate
440
and the head body
20
can be improved. However, one or both of the interruption wall portion
446
and the groove portion
447
can be omitted.
Description will now be made of a sixth embodiment shown in
FIGS. 11A and 11B
. In this embodiment, there are provided wall-shaped convex portions
445
similar to those in the fifth embodiment and further, interruption wall portions
546
, instead of wall-shaped convex portions, are provided between adjacent ones of discharge ports
441
. The interruption wall portions
546
, unlike the wall-shaped convex portions, are provided not at locations entering into the communication ports of flow paths
401
, but at locations whereat they abut-against the joined surface
44
of the head body
20
during joint, and these interruption wall portions
546
are collapsed by the joint between the orifice plate
440
and the head body
20
. By this construction, the flow path separability between nozzles is heightened, the fluid interference between the nozzles is decreased and the stability of discharge becomes high. According to the present embodiment, the inflow of the adhesive is interrupted by the interruption wall portions
546
at locations separate from the flow paths
401
and therefore, the entry of the adhesive into the flow paths
401
can be prevented more reliably than in the construction wherein the wall-shaped convex portions entering into the flow paths
401
are provided.
In a seventh embodiment shown in
FIG. 12
, instead of the interruption wall portions in the sixth embodiment, a groove portion
547
orthogonal to the row direction of the discharge ports
441
is formed between adjacent ones of the discharge ports
441
. In the present embodiment, the overflowing adhesive is contained in the groove portions
547
to thereby prevent the inflow of the adhesive into the flow paths
401
.
In the fifth embodiment, the wall-shaped convex portions have their opposite end portions formed into a tapered shape so as to be lengthwisely tapered, but in an eighth embodiment shown in
FIG. 13
, wall-shaped convex portions
645
have their outer sides
645
a
formed into a tapered shape so as to be widthwisely tapered. Again in this case, the work of bringing the convex portions
645
into the communication ports of the flow paths
401
can be done easily. Of course, it will be more effective if the wall-shaped convex portions
645
are formed into a tapered shape so as to be tapered both lengthwisely and widthwisely.
It is also possible to adopt constructions in which the constructions of the first to eighth embodiments described above are variously combined.
Claims
- 1. A liquid discharge head having:an orifice plate in which a plurality of discharge ports for discharging liquid droplets there through are arranged in a row; and a head body provided with a plurality of flow paths communicating with said plurality of discharge ports, a liquid chamber for supplying liquid to said plurality of flow paths, and a plurality of energy generation elements disposed correspondingly to said plurality of flow paths and generating energy for discharging the liquid droplets, wherein said orifice plate is joined to the surface of said head body in which the communication ports of said flow paths communicating with said discharge ports are disposed; wherein said orifice plate is formed with wall-shaped convex portions protruding from the inner peripheral portions of said discharge ports and having at least a portion entering from said communication ports into said flow paths, and the width of said wall-shaped convex portions is greater in the portions parallel to the row direction in which said plurality of discharge ports are arranged than in the portions orthogonal to said row direction.
- 2. A liquid discharge head according to claim 1, wherein said wall-shaped convex portions are provided along the entire inner peripheral portions of said discharge ports.
- 3. A liquid discharge head according to claim 1, wherein said orifice plate is formed of resin, silicon, ceramics or a metal material.
- 4. A liquid discharge head according to claim 1, wherein said discharge ports are of a tapered shape.
- 5. A liquid discharge head according to claim 1, wherein said orifice plate is joined to said head body by an adhesive layer, and said adhesive layer comprises an adhesive made into B stage by carrying out processing including the application of ultraviolet rays, infrared rays or heat.
- 6. A liquid discharge head according to claim 5, wherein said adhesive layer comprises an epoxy adhesive, said epoxy adhesive having a thermosetting property and/or a light energy hardening property.
- 7. A liquid discharge head having:an orifice plate in which a plurality of discharge ports for discharging liquid droplets there through are arranged in a row; and a head body provided with a plurality of flow paths communicating with said plurality of discharge ports, a liquid chamber for supplying liquid to said plurality of flow paths, and a plurality of energy generation elements disposed correspondingly to said plurality of flow paths and generating energy for discharging the liquid droplets, wherein said orifice plate is joined to the surface of said head body in which the communication ports of said flow paths communicating with said discharge ports are disposed; wherein said orifice plate is formed with wall-shaped convex portions protruding from the inner peripheral portions of said discharge ports and having at least a portion entering from said communication ports into said flow paths, and on the surface side of said orifice plate to said head body, as compared with the inner end portions of said discharge ports at positions orthogonal to the row direction in which said plurality of discharge ports are arranged, said wall-shaped convex portions located in parallel to said row direction are formed high in the direction of thickness of said orifice plate.
- 8. A liquid discharge head according to claim 7, wherein said wall-shaped convex portions include portions parallel to said row direction and portions orthogonal to said row direction, and the inner end portions of said discharge ports at the positions orthogonal to said row direction are the fore end portions of those portions of said wall-shaped convex portions which are orthogonal to said row direction.
- 9. A liquid discharge head according to claim 7, wherein said wall-shaped convex portions are provided in only the portions parallel to said row direction.
- 10. A liquid discharge head according to claim 7, wherein at least a portion of the inner sides of said wall-shaped convex portions is a curved surface.
- 11. A liquid discharge head according to claim 10, wherein said curved surface is of a shape substantially similar to the shape of said discharge ports.
- 12. A liquid discharge head according to claim 7, wherein interruption wall portions substantially parallel to said row direction are provided outside the portions of said wall-shaped convex portions which are parallel to said row direction.
- 13. A liquid discharge head according to claim 7, wherein groove portions substantially parallel to said row direction are provided outside the portions of said wall-shaped convex portions which are parallel to said row direction.
- 14. A liquid discharge head according to claim 7, wherein interruption wall portions substantially parallel to said row direction and groove portions substantially parallel to said row direction are provided outside the portions of said wall-shaped convex portions which are parallel to said row direction.
- 15. A liquid discharge head according to claim 3, wherein an interruption wall portion substantially orthogonal to said row direction, which is collapsed and deformed during the joining of said orifice plate and said head body, is provided between adjacent ones of said discharge ports.
- 16. A liquid discharge head according to claim 7, wherein a groove portion substantially orthogonal to said row direction is provided between adjacent ones of said discharge ports.
- 17. A liquid discharge head according to claim 7, wherein said orifice plate is formed of resin, silicon, ceramics or a metal material.
- 18. A liquid discharge head according to claim 7, wherein said discharge ports are of a tapered shape.
- 19. A liquid discharge head according to claim 7, wherein said orifice plate is joined to said head body by an adhesive layer, and said adhesive layer comprises an adhesive made into B stage by carrying out processing including the application of ultraviolet rays, infrared rays or heat.
- 20. A liquid discharge head according to claim 19, wherein said adhesive layer comprises an epoxy adhesive, said epoxy adhesive having a thermosetting property and/or a light energy hardening property.
- 21. A method of manufacturing a liquid discharge head, comprising the following steps:discharging liquid droplets through a plurality of discharge ports, the plurality of discharge ports being arranged in a row on an orifice plate, communicating the plurality of flow paths with the plurality of discharge ports, supplying liquid to the plurality of flow paths, and generating energy for discharging the liquid droplets, the energy being generated by a plurality of energy generation elements disposed correspondingly to the plurality of flow paths and generating energy for discharging the liquid droplets, joining the orifice plate to the surface of the head body, the head body being disposed with the communication ports of the flow paths for communicating with the discharge ports, forming the orifice plate with wall-shaped convex portions protruding from the inner peripheral portions of the discharge ports, the discharge ports having at least a portion entering from the communication ports into the flow paths, and after the discharge ports have been formed by laser working, forming wall-shaped convex portions by laser working, wherein the wall-shaped convex portions are formed high in the direction of thickness of the plate, as compared with the inner end portions of the discharge ports at positions orthogonal to the row direction in which the plurality of discharge ports are arranged.
- 22. A method of manufacturing a liquid discharge head according to claim 21, wherein the laser working is laser ablation working by an excimer laser.
- 23. A method of manufacturing a liquid discharge head according to claim 21, wherein the orifice plate is formed of one of polysulfone, polyether sulfone, polyphenylene sulfide and polyether ether ketone.
- 24. A method of manufacturing a liquid discharge head according to claim 21, wherein the discharge ports are of a tapered shape.
- 25. A method of manufacturing a liquid discharge head, comprising the following steps:discharging liquid droplets through a plurality of discharge ports, the plurality of discharge ports being arranged in a row on an orifice plate, communicating the plurality of flow paths with the plurality of discharge ports, supplying liquid to the plurality of flow paths, and generating energy for discharging the liquid droplets, the energy being generated by a plurality of energy generation elements disposed correspondingly to the plurality of flow paths and generating energy for discharging the liquid droplets, joining the orifice plate to the surface of the head body, the head body being disposed with the communication ports of the flow paths for communicating with the discharge ports, forming the orifice plate with wall-shaped convex portions protruding from the inner peripheral portions of the discharge ports, the discharge ports having at least a portion entering from the communication ports into the flow paths, and after the discharge ports have been formed by laser working, forming wall-shaped convex portions by laser working, wherein the wall-shaped convex portions are provided in only the portions parallel to the row direction.
- 26. A method of manufacturing a liquid discharge head according to claim 25, wherein the laser working is laser ablation working by an excimer laser.
- 27. A method of manufacturing a liquid discharge head according to claim 25, wherein the orifice plate is formed of one of polysulfone, polyether sulfone, polyphenylene sulfide and polyether ether ketone.
- 28. A method of manufacturing a liquid discharge head according to claim 25, wherein the discharge ports are of a tapered shape.
Priority Claims (1)
Number |
Date |
Country |
Kind |
11-148540 |
May 1999 |
JP |
|
US Referenced Citations (3)
Number |
Name |
Date |
Kind |
5059973 |
Watanabe |
Oct 1991 |
A |
5604521 |
Merkel et al. |
Feb 1997 |
A |
6079810 |
Davis |
Jun 2000 |
A |
Foreign Referenced Citations (2)
Number |
Date |
Country |
836906 |
Apr 1998 |
EP |
2-204048 |
Aug 1990 |
JP |