Information
-
Patent Grant
-
6378994
-
Patent Number
6,378,994
-
Date Filed
Wednesday, August 30, 200024 years ago
-
Date Issued
Tuesday, April 30, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Barlow; John
- Stephens; Juanita
Agents
- Morgan, Lewis & Bockius LLP
-
CPC
-
US Classifications
Field of Search
US
- 347 65
- 347 92
- 347 47
- 347 63
- 347 64
- 347 20
- 347 56
- 347 54
-
International Classifications
-
Abstract
The present invention provides a liquid jet printing head, a method of manufacturing the same, and a liquid jet printing apparatus, which allow stable, high speed, and continuous printing. A liquid jet printing head provides an inflow of liquid from an inlet to a common chamber, then along with the surface of heating elements of a heating element substrate and with a wall of a housing to separate channels. Liquid drops will be ejected by heating the heating elements. Since liquid may flow linearly from the inlet to the separate channels in accordance with the present invention, smooth flow promotes evacuation of bubbles through a nozzle, while cooling the heating element substrate with liquid flowing along with the substrate. The present invention provides thereby stable printing with high speed, continuous ejection (printing) of liquid drops.
Description
BACKGROUND OP THE INVENTION
1. Field of the Invention
The present invention is directed to a liquid jet type recording head, a method for manufacturing the same, and a liquid jet type recording apparatus, and more specifically to a liquid jet type recording head used in a thermal type liquid ejector apparatus capable of continuously and stably jetting (printing) liquid at high speed, a method of manufacturing the same, and a liquid jet type recording apparatus using the same.
2. Description of the Related Art
Recently, the liquid jet recording apparatus has attracted a great deal of public attention because of its nature as a low-cost and high quality color recording apparatus. Exemplary liquid jet recording heads for use in the liquid jet recording apparatus includes, for example, a piezo-electric liquid jet recording head for jetting liquid through nozzles with the pressure generated by the mechanical distortion of pressure chamber by a piezo-electric element, and a thermal type liquid jet recording head for jetting liquid through nozzles with the pressure generated by evaporation of liquid by applying current to heating elements each of which is individually arranged in a separate channel.
There are some known ink jet printing heads in the Prior Art. Japanese Published Unexamined Patent Application No. Hei 9-226142 discloses the prevention of bubbles by providing an ink supplying channel having smaller cross-sectional area than the cross section of opening of the common ink chamber for an ink supplying channel to the common ink chamber communicating with the head orifice of the printing head. Japanese Published Unexamined Patent Application No. Hei 11-227208 discloses narrowing in the vertical direction the inner walls of head in the proximity of nozzles and liquid inlet within each orifice in the recording head to improve the ink supply. Japanese Published Unexamined Patent Application No. Hei 1-148560 discloses a method of creating an ink jet recording head by compiling a first substrate having ink channels and a common chamber formed by anisotropic etching on a surface side of silicon wafer, and a second substrate having heating elements and addressing electrodes formed on a surface side of silicon wafer. Japanese Published Unexamined Patent Application No. Hei 5-338177 discloses a printing head with a fitting arrangement of an ink manifold used as the common liquid chamber of recording head with an ink reservoir, having the back end wall of ink manifold formed as a sharp edge. Japanese Published Unexamined Patent Application No. Hei 5-338168 discloses a method of removing bubbles in a reservoir by forming an ink supplying lid of parallelogram to an ink reservoir of a printing head made of a silicon substrate. Japanese Published Unexamined Patent Application No. Hei 8-118666 discloses an ink jet recording head by forming an ink jet recording head chip by bonding plural silicon substrates, removing a part of one of silicon substrates of the head chip, and providing a common ink chamber having an ink supplying opening at the removed part. Japanese Published Unexamined Patent Application No. Hei 8-118653 discloses a method of improving the adhesiveness between silicon substrates in an inkjet printing head having two patterned silicon substrates bonded together by an intermediate thick film of a polymer by flattening by chemically or mechanically polishing the intermediate thick film layer of the ink jet printing head.
An example of the thermal type liquid jet recording head of the state of the art is disclosed in the Japanese Published Unexamined Patent Application No. Hei 9-226142. Now referring to
FIG. 20
, there is shown a perspective view of a liquid jet recording head and a liquid supplier incorporated in a liquid jet recorder of the Prior Art.
FIG. 21
depicts a cross-sectional view of the head shown in
FIG. 20
taken along with the line A—A.
A head chip
100
has plural channels
102
formed in parallel at a predetermined distance, and an ink outlet
104
is outwardly opened at an end of each channel
102
. The other end of each of plural channels
102
is communicated with a commonly shared ink chamber
106
. At the top of ink chamber
106
an opening
108
is formed for supplying liquid thereto. In each of channels
102
a heating element
110
is disposed, which generates heat to foam the liquid in the channel
102
, and the pressure generated by the foamed liquid forces the liquid to eject through the ink outlet
104
for recording.
The head chip
100
as has been described above may be formed by bonding a heating element substrate
114
with heating elements
110
mounted thereon and a channel substrate
116
having grooves formed for the channels
102
and the common ink chamber
106
, with the aid of a resin layer (not shown in the figure).
The heating element substrate
114
is affixed to a heat sink
118
for effective radiation of heat. On the heat sink
118
is formed a printed circuitry to transfer power and signals supplied from the liquid jet recorder through the bonding wires
120
to the heating element substrate
114
and to feed back signals generated by a variety of sensors incorporated in the heating element substrate
114
to the recorder.
On the head chip
100
, a liquid supplier member
122
is bonded. The liquid supplier member
122
includes liquid channels
124
for supplying liquid from a liquid reservoir (not shown) to the head chip
100
.
The liquid jet recording head thus formed will be supplied with liquid from the liquid reservoir through the separate channels
102
. In other words, the liquid supplied from the reservoir will flow through the liquid channels
124
of the liquid supplier member
122
, then through the liquid inlet
108
opened on the top of the channel substrate
116
of the head chip
100
to the common chamber
106
, in order to supply ultimately to each of the separate channels
102
.
In a liquid jet recording head as has been described above has a disadvantage that some bubbles will be intermixed with the liquid when introducing the liquid from the liquid reservoir to the liquid chamber
106
. The bubbles mixed therein along with the liquid tend to reside intensively in the area
126
(see
FIG. 21
) in the liquid chamber
106
where the liquid flow is slow. In case where bubbles reside in the chamber
106
for example, the bubbles will grow larger while repeatedly jetting the liquid so as to interfere the supply of liquid by blocking channels
102
, to ultimately cause the defects of recording. In the thermal type of liquid jet recording heads, the temperature of liquid will increase with the heating of heating element
110
. As the result of heating the air dissolved in the liquid, bubbles will be deposited in the common chamber
106
and enlarged to be likely to prevent smooth ejection of liquid drops therefrom. In this manner, heating may develop bubbles in the common chamber
106
as well as in the junction of the common chamber
106
with the liquid supplier member
122
, resulting in a problem of blocking by bubbles.
In order to purge bubbles residing in the common liquid chamber, it is common to aspirate through the nozzles
104
. When sucking bubbles through the nozzles
104
, an amount of liquid equivalent to the volume sucked will be supplied from the reservoir. Thus supplied liquid will spread along with the shape of the common liquid chamber
106
to be directed to the separate channels
102
. The liquid flow may force bubbles to advance toward the channels
102
to purge from the nozzles
104
. However, the bubbles residing at both ends of the chamber
106
, at the ends shown by the arrow in the direction of X, which are the primary cause of defects in the printing quality, are difficult to be completely removed because these bubbles are in the area of very slow flow of liquid.
In order to remove bubbles residing at both ends of the chamber
106
as has been described above, in the liquid jet recording heads of the Prior Art, dummy nozzles
126
have to be provided at both ends of the chamber
106
, which nozzles are not for use in printing.
Although it is conceivable to increase the number of times of aspiration through nozzles, there will arise problems that a higher frequency of aspiration cleaning decreases the effective efficiency of liquid for use in recording, and requires a larger volume of a waste liquid container for containing aspired waste liquid, resulting In a larger apparatus in size.
In a thermal type liquid jet recording head, there is another problem that high speed and continuous printing cannot be performed. This is because when ejection (recording) is continuously performed, the temperature of head assembly increases to ultimately disable the stable ejection of liquid.
SUMMARY OF THE INVENTION
In order to avoid this phenomenon, finer control of printing such as stopping printing at or beyond a predetermined temperature threshold or slowing the speed of printing by monitoring the temperature of the head will be required.
The present invention has been made in view of the above circumstances and provides a liquid jet printing head, a method of manufacturing the same, and a liquid jet recording apparatus using the same.
In order to solve the above mentioned problems, the present invention provides a liquid jet printing head for jetting liquid by heating with a heater member, includes: a common liquid chamber having an inlet opening for supplying liquid from outside; and plural separated channels for heating liquid supplied through the chamber with the heating elements to eject the liquid through outlets; a heating element substrate incorporating plural heating elements; wherein the liquid supplied from the inlet flows through linearly to the outlet, and wherein the heating element substrate is arranged along with the flow of the liquid.
Now the function of an aspect of the present invention will be described in greater details below.
The liquid that has reached to the common chamber through the inlet will flow through each of separate channels, be heated by heating elements each provided for a channel, and ejected as liquid drops due to the pressure of bubbles generated by heating. The liquid that has flowed through the common chamber from the inlet will be introduced linearly to the channels along with the surface of heating elements formed on the heating element substrate so as to be ejected through the outlet. Because a smooth flow of liquid from the inlet through the channel is achieved, bubbles created in the separate channels or in the chamber will be evacuated smoothly to the atmosphere together with the liquid drops. By arranging the ejection of liquid in the direction of gravity, the bubbles generated will move to the top of common chamber, then through the inlet to the liquid reservoir. This arrangement will prevent the ejection of liquid from being blocked by residing and growing in the proximity of separate channels and by finally occluding separate channels.
Since the liquid flows through along with the surface of heating elements formed on the heating element substrate, the substrate will be effectively cooled down by the liquid so as to be able to suppress the increase of temperature in the heating element substrate.
Therefore a stable, high speed, continuous liquid jet (printing) will be performed.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes a guiding surface for driving the liquid that flows through the common chamber to the separate channels.
Now the function of the present invention will be described in greater details below.
A guiding surface is formed from the common chamber to the channels, so that the liquid will flow there through smoothly. This ensures that the bubbles generated in the common chamber will not remain in the chamber and will be securely ejaculated through the channels.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes a guide plate provided for narrowing the cross section of path toward the channels.
The function of the invention will be described in greater details below.
A guide plate is provided for narrowing the cross section of flow path from the common chamber toward the separate channels, thereby the flow of liquid entering from the common chamber to the separate channels will be accelerated. This allows the liquid flow entering to separate channels to be smoother, resulting in easier evacuation of bubbles generated in the common chamber or separate channels, in other words secure prevention of residual bubbles in the proximity of separate channels. In addition this promotes cooling of the heating element substrate so as to enable more effective control of temperature increase.
Still another aspect of the present invention is characterized in that, in a liquid jet printing head, the cross section of path formed by the guide plate and the substrate is gradually diminished in the direction toward the separate channels.
The function of the invention will be description in greater details below.
The decrease in cross section of the path formed by the guide plate and the substrate toward the separate channels causes the liquid to flow faster toward the channels, thereby the bubbles generated in the proximity of channels will be easily removed and the blocking of liquid jet will be prevented.
Another aspect of the present invention is characterized in that in a liquid jet printing head in accordance with the present invention, a liquid element substrate is arranged so as to contact liquid in the surfaces other than that of forming the heating elements in the heating element substrate.
The function of the invention will be described in greater details below.
In the present invention, a heating element substrate arranged so as to contact liquid in other surfaces in addition to the surface having heating elements may increase radiation of the heating element substrate, allowing more effective control of temperature increase caused by the heating of the heating elements. Thus more stable liquid jet may be achieved even when continuous, high-speed liquid jet is required.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes a structure incorporating the separate channels together with the common chamber.
The function of the aspect of the present invention will be described in greater details below.
Separate channels incorporated with the common chamber enables the decrease in the number of parts as well as miniaturization of printing head.
If the respective separate channels are directly communicate with the common liquid chamber, bubbles remaining in the common chamber will effectively diminished because so-called dead circulate portion of the liquid in the chamber and thus, to ensure the ejection of the liquid droplet from the outlets. Also, the common chamber has relatively high volume compare to the conventional one, contacting area of the heating element substrate with the liquid will be drastically increased, and thus the heat energy generated by the heating element will be effectively released through the liquid. The heat energy released into the liquid also generate the circulate of the liquid for diminishing the temperature of the substrate.
Another aspect of the present invention is characterized in that a liquid jet printing head including input/output terminals of electric signal mounted on the surface of the heating element substrate is positioned at an end of the heating element substrate in the direction orthogonal to the direction of liquid jet.
Now the function of the invention will be described below.
In the present invention, input/output terminals of electric signals are arranged at an end of the heating element substrate in the direction orthogonal to the direction of liquid jet. The inlet of the common liquid chamber, which may be referred as a sub ink tank, may be thereby designed inline toward the separate channels. As a result, more smooth flow may be achieved with input/output terminals of electric signals arranged on the heating element substrate.
Another aspect of the present invention is characterized in that a liquid jet printing head having the surface of the heating element substrate forming the separate channels and coated by a liquid resistant resin layer, includes a liquid resistant and high thermal conductive material deposited at least on a portion of the surface of the heating elements in the heating element substrate, and a resin layer deposited on the surface of the heating elements or on the top of the high thermal conductive material such that a part of the high thermal conductive material is exposed, wherein the liquid comes in contact with the high thermal conductive material.
The function of the invention will be described below.
By depositing a film of liquid resistant resin on the heating element substrate, the corrosion of heating element substrate by the liquid will be prevented. However, coating by a resin layer will decrease the heat radiation from the heating element substrate to the liquid hence promotes the increase of temperature in the heating element substrate. Therefore, by depositing a liquid resistant and high thermal conductive material to at least on a portion of the heating element substrate and exposing a portion of the high thermal conductive material to the liquid to come in contact therewith, the heat generated in the heating element substrate will be effectively conducted to the liquid through the high thermal conductive material. In other words, in accordance with the present invention, the increase of temperature in the heating element substrate will be sufficiently controlled so as to enable stable, high speed, and continuous liquid jet.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes plural openings in the resin layer for exposing the high thermal conductive material.
The function of the invention will be described below.
In order to promote heat radiation from the heating element substrate to the liquid, it may be needed to increase the exposed surface area of the high thermal conductive material. This means that larger area of opening in the resin layer is better. However, when polishing for flattening the surface of the resin layer, there may arise a problem that some abrasive may penetrate into the opening, and the area in proximity of the opening may be locally polished. In accordance with the present invention, there are plural openings provided; the polishing of resin layer may be entirely leveled to increase the radiation.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes the openings of the same shape as the holes provided in the resin layer for exposing the heating elements.
The function of the invention will be described below.
The openings, which have the same shape as the holes formed in the resin layer in order to expose the heating elements, may further level the polishing of the resin layer.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes the openings arranged in a staggered pattern.
The function of the invention will be described below.
The staggered pattern of the openings allows the polished state of resin layer to be further leveled.
Another aspect of the present invention is characterized in that a liquid jet printing head, further includes a liquid resistant and high thermal conductive material disposed on the surface of heating elements on the heating element substrate to provide a wavy ramp surface.
The function of the invention will be described below.
Disposing a liquid resistant and high thermal conductive material on the surface of heating elements on the heating element substrate so as to provide a wavy ramp surface causes the surface area of the high thermal conductive material to be increased and causes the heat radiation of the heating element substrate to be improved.
Another aspect of the present invention is characterized in that a liquid jet printing head further includes the ramp of the high thermal conductive material exceeding a reference value being coated by the resin layer.
The function of the invention will be described below.
The portion with the ramp exceeding a reference value in the high thermal conductive material having a wavy ramp surface is not suitable for the deposition of the high thermal conductive material at a predetermined thickness. Therefore such a portion may have a potential risk of corrosion of the heating element substrate when contacting with the liquid. Therefore, by depositing a resin layer on the high thermal conductive material on the area where the thickness exceeds a reference value, the corrosion of the high thermal conductive material by the liquid in the defective deposition points of high thermal conductive material occurred in such area can be effectively prevented.
Another aspect of the present invention is characterized in that a liquid jet printing apparatus includes a liquid jet printing head in accordance with the present invention.
The function of the invention will be described below.
When using the liquid jet printing head in accordance with an aspect of the present invention, a liquid jet printing apparatus may perform stable liquid jet without the fear of bubbles generated. Also the heat radiation from the heating element substrate to the liquid will be prompted so that the increase of temperature in the heating element substrate may be well controlled so as to be able to continuously eject.
Another aspect of the present invention is characterized in that a liquid jet printing apparatus further includes the liquid jet printing head arranged so as to eject liquid in the angular range between the gravity direction and up to 45 degrees with respect to the gravity direction.
The function of the invention will be described below.
When a liquid jet printing head is arranged to eject liquid in the angular range between the gravity direction and 45 degrees from the gravity direction, the path from the inlet of a common chamber to the ink outlet should be accordingly disposed in the range between the gravity direction and 45 degrees from the gravity direction. Thus the bubbles generated in separate channels or the common chamber may displace toward the inlet of the common chamber. This may prevent the liquid jet through the separate channels from being affected.
Another aspect of the present invention is characterized in that a method of manufacturing a liquid jet printing head having a liquid channel substrate forming separate channels for jetting liquid and a portion of a common chamber for supplying liquid to the separate channels, in accordance with any one aspect of the present invention, wherein the liquid path substrate is made of a silicon substrate, on which grooves are formed for providing the separate channels and the common chamber by using either a crystalline anisotropic etching method or anisotropic etching method.
The function of the invention will be described below.
By forming grooves by either crystalline anisotropic etching or anisotropic etching of a silicon substrate, a portion of separate channels and a common chamber may be formed on a liquid path substrate at high precision.
Another aspect of the invention is characterized in that a method of manufacturing a liquid jet printing head includes a first step of etching a first surface of the liquid path substrate to provide grooves forming a portion of the separate channels and the common chamber, and a second step of processing the substrate from a second surface opposing to the first surface to decrease the thickness of the substrate to pierce there through the groove for a portion of the common chamber.
The function of the invention will be described below.
In general, a portion (pierced throughhole) of the common chamber of the path substrate is formed before forming the separate channels. Care should be taken for handling a path substrate on which the throughhole is formed at the time of forming separate channels; otherwise the substrate will be damaged. In the present invention, the process of forming separate channels is performed at the same time of process of grooves for a portion of the common chamber, and thereafter a portion of the common chamber may be pierced by for example grinding, as the final process of path substrate. This prevents the substrate from being damaged.
When forming throughhole on the path substrate prior to forming of separate channels, cooling gas for the channel process may be leaked from the second surface to the first surface, causing some degradation of process quality and precision of the separate channels. In accordance with the present invention, the quality and precision of process of separate channels may be improved by piercing a portion of common chamber by decreasing the thickness of substrate from the second surface side after the process of separate channels.
Another aspect of the present invention is characterized in that in a method of manufacturing a liquid jet printing head in accordance with the present invention, the second process step is performed after bonding the liquid path substrate and heating element substrate.
The function of the invention will be described below.
The liquid path substrate and heating element substrate will be bonded together after forming grooves for the separate channels and the like in the first surface side. Thereafter, a portion forming a common chamber will be pierced through the substrate by piercing therethrough from the second surface side of the liquid path substrate. In this manner, since the throughhole portion will be formed by processing from the second surface side after increasing the rigidity of the liquid path substrate by bonding the liquid path substrate with the heating element substrate, defects of substrates can be securely prevented.
Another aspect of the present invention is characterized in that a method of manufacturing a liquid jet printing head in accordance with any one of aspects provided by the present invention includes a heating element substrate incorporating heating elements, the heating element substrate being integrated with heating elements and driver circuits on the surface thereof by means of semiconductor manufacturing technique.
The function of the invention will be described below.
Forming heating elements and driver circuits integrated on a substrate may facilitate the forming process as well as improve the reliability of signal processing.
Additional features and advantages of the invention will be according to part in the description which follows and in part will be obvious from the description, or may be learned by practice of the invention. The above mentioned and other features and advantages of the invention may be implemented and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part of this specification illustrate some embodiments of the invention and, together with the description, serve to explain the objects, advantages and principles of the invention. In the drawings,
FIGS. 1A
to
1
C are cross-sectional views of a liquid jet printing head in accordance with a first preferred embodiment of the present invention;
FIG. 2
Is a perspective view of a head chip in accordance with the first preferred embodiment of the present invention;
FIG. 3
is an partial enlarged view of
FIG. 1
;
FIG. 4
is a perspective view of a head chip in accordance with a second preferred embodiment of the present invention;
FIG. 5
is a partial cross-sectional view in the proximity of nozzles of the liquid jet printing head in accordance with the second preferred embodiment of the present invention;
FIG. 6
is a partial cross-sectional view around the nozzles of the liquid jet printing head in accordance with another example of the second preferred embodiment of the present invention;
FIG. 7
is a graph depicting the temperature of a head of the Prior Art and a head in accordance with the present invention;
FIG. 8
is a partial cross-sectional view around the nozzles of liquid jet printing head in accordance with a third preferred embodiment of the present invention;
FIG. 9
is a partial cross-sectional view around the nozzles of the liquid jet printing head in accordance with another example of the third preferred embodiment of the present invention;
FIG. 10
is a perspective view of the head chip in accordance with a fourth preferred embodiment of the present invention;
FIG. 11
is a perspective view of the heating element substrate in accordance with a fifth preferred embodiment of the present invention;
FIG. 12
is a perspective view of the heating element substrate in accordance with a sixth preferred embodiment of the present invention;
FIG. 13
is a perspective view of a heating element substrate in accordance with another example of the sixth preferred embodiment of the present invention;
FIG. 14
is a cross-sectional view illustrating a resin layer defined in a heating element substrate in accordance with a seventh preferred embodiment of the present invention when the coating with tantalum is weak;
FIG. 15
is a schematic diagram of tantalum layer defined on a heating element substrate in accordance with an eighth preferred embodiment of the present invention;
FIGS. 16A
to
16
C arc schematic diagrams illustrating the method of manufacturing a head chip in accordance with a ninth preferred embodiment of the present invention;
FIG. 17
is a cross-sectional view of a head chip illustrating the method of manufacturing a head chip in accordance with the ninth preferred embodiment of the present invention;
FIG. 18
is a cross-sectional view of a head structure combined with a liquid reservoir in accordance with an embodiment of the present invention;
FIG. 19
is a perspective view of a liquid jet printing apparatus incorporating a liquid jet printing head in accordance with one of preferred embodiments of the present invention;
FIG. 20
is a perspective view of a liquid jet printing head in accordance with the Prior Art; and
FIG. 21
is a cross-sectional view of
FIG. 20
taken along with the line A—A.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A detailed description of some preferred embodiments embodying the present invention will now be given referring to the accompanying drawings.
(First Embodiment)
A liquid jet printing head in accordance with the first preferred embodiment of the present invention will be described hereinbelow in greater details with reference to
FIG. 1A
to FIG.
3
.
FIG. 1A
is a cross-sectional drawing of a liquid jet printing head in accordance with this preferred embodiment,
FIG. 2
is a perspective view of a head chip constituting part of the liquid jet printing head, and
FIG. 3
is an enlarged view of part of FIG.
1
A.
A liquid jet printing head
10
including a head chip
14
fixed at the tip of a housing
12
, as shown in FIG.
1
A.
The head chip
14
includes a heating element substrate
18
having heating elements
16
formed thereon, bonded to a liquid path substrate
26
having a groove
24
constituting part of a common chamber
22
by integratedly joining grooves for separate channels
20
and the housing
12
, as shown in
FIGS. 2 and 3
.
The heating element substrate
18
may be made by means of an apparatus and a method of manufacturing LSIs and the like. For example, a heat storage layer such as silicon oxide is formed on the surface of single crystalline silicone to form thereon the heating elements
16
. Plural heating elements
16
may be formed and connected to signal lines for supplying power and signals thereto, The heating elements
16
may be heated by receiving signals supplied from a driver circuit arranged in the same chip or elsewhere. On top of the heating elements
16
a protective layer includes a single layer or plural layers of silicon oxide, silicon nitride, tantalum, etc. for protection the heating elements
16
.
A resin layer will be coated thereon, which may be served as a protector film for protecting from liquids. The resin layer may be formed by applying a photosensitive resin and patterning in a photolithographic process. Any of photosensitive resins including for example photosensitive polyimide may be used. Any other polymer materials in addition to photosensitive polyimide may also be used, including for example non-photosensitive polyimide and dry-films. Before patterning the resin layer, the resin on the heating elements and signal electrodes should be removed.
The resin layer will be shrunk in the process of thermosetting so that edges of resin layer being patterned will become a convex shape. The circumference of the substrate will also have a convex shape due to a thick resin layer formed thereon. Such a convex shape may cause defective bonding when bonding to the liquid path substrate
26
. In order to remove such convex shape, the resin layer should be flattened by means of such a method as CMP (chemical mechanical polishing).
The liquid path substrate
26
may be formed by means of an apparatus and a method of manufacturing LSIs and the like. For example, a single crystalline silicone may be crystalline anisotropically etched to form grooves for the common chamber
22
and separate channels
20
. The crystalline anisotropic etching may be performed such that an etching mask is patterned on a silicon wafer having the crystal face (
100
) on the surface and the wafer is etched by using warmed aqueous solution of potassium hydroxide (KOH) and the like. Suitable etching solutions include solution of tetra-methyl ammonium hydroxide (TMAH). As an alternative, a method disclosed in Japanese Published Unexamined Patent Application No. H11-227208 may be used instead.
The heating element substrate
18
and liquid path substrate
26
thus formed may be registered and bonded, then cut and separated as a head chip
14
. In this manner the liquid path extending from the common chamber
22
through separate channels
20
to the nozzle
28
may be formed.
Then the heating element substrate
18
will be mounted on a heat sink
34
for radiating heat generated by the heating elements
16
. A wiring substrate not shown in the figure may be formed on the heat sink
34
to connect to the signal terminals on the head chip
14
through bonding wires.
Then, the head chip
14
will be mounted in the housing
12
so as to form a common chamber
22
. The common chamber
22
is formed in a shape of rectangle, provides an inlet
32
for introducing liquid therein from a liquid reservoir, which may be referred as main ink tank, on a side opposing to the head chip
14
, and communicates with the other end of each of separate channels
20
through a concaved recess
24
of the head chip
14
(liquid path substrate
26
).
By arranging the surface of wall
12
B of the housing
12
in succession to the surface
18
A of heating element substrate
18
, the liquid introduced to the common chamber
22
from the inlet
32
will flow through the wall
12
B and the surface
18
A of the heating element substrate to the separate channels
20
(see the solid line with an arrow shown in FIG.
3
).
At the side of separate channels
20
in the common chamber
22
a guide surface
26
A may be formed, which is at an acute angle (θ) in the direction opposed to the liquid jet, so as to smoothly introduce the liquid in the common chamber
22
into the separate channels
20
(see the broken line with an arrow shown in FIG.
3
).
The function of thus formed drop ejection recording head
10
will be described below.
Liquid will be supplied from a reservoir not shown in the figure, introduced into the common chamber
22
through the inlet
32
, and then distributed to each of separate channels
20
. The pressure of bubbles developed in the separate channels
20
by heating the heating elements
16
in the separate channels
20
forces liquid drops
36
to eject from the channels to print on a recordable medium
38
.
In the preferred embodiment, liquid introduced from the inlet
32
to common chamber
22
will smoothly enter the separate channels
20
along with the wall
12
B of the housing
12
and with the surface of heating elements
18
A of the heating element substrate
18
. The liquid will flow smoothly there into, guided by the guide surface
26
A of the liquid path substrate
26
disposed at an angle θ (approximately <90 degrees) in the direction opposing to the ejection direction of liquid drops
36
. As there is no region, where liquid flows extremely slow, observed in a conventional structure of printing head (dead water region), either in the common chamber
22
or in the separate channels
20
, there is no space for retaining bubbles if some bubbles accidentally introduced along with the supplied liquid, or for example if bubbles residual in the liquid are developed due to increased temperature of liquid in the common chamber
22
by heating the heating elements
16
, and the smooth flow of liquid as mentioned above will evacuate through the nozzle
28
to the outside. Accordingly, interference to the liquid supply to the nozzle
28
(separate channels
20
) caused by the development of bubbles will be prevented to ensure a stable printing capability (drop ejection performance).
If the direction of drop ejection from the liquid jet printing head
10
is arranged to be vertically downward, the bubbles developed in the common chamber
22
will be surfaced upwardly toward the common chamber
22
by the buoyancy, without affecting the liquid supply to the separate channels
20
, ensuring a stable printing capability.
There can be cases where a step like ramp may exist between the heating element substrate
18
and the housing
12
due to manufacturing error of the housing
12
or assembly error for example. However, the dead water area caused by the structural nature found in the Prior Art will not be developed so that the ramp may be regarded to be tolerable.
Another object of the present invention is to radiate excessive heat stored in the beating element substrate
18
caused by the heating of heating elements
16
not only to the heat sink
34
but also to the liquid contacting to the heating element substrate
18
by enlarging the volume of the common chamber
22
. If the liquid temperature increases beyond a predetermined threshold temperature, printing failure such as sucking of bubbles from the nozzles
28
may occur. In accordance with the present invention, by sufficiently enlarging the volume of the common chamber
22
, the heated liquid will move upwardly in the common chamber while cooled liquid will move downwardly. In other words a kind of convection of liquid may be created in the common chamber. The convective liquid in the common chamber may also exchange heat with the ink in the reservoir through the intermediary of a filter not shown in the figure. The saturation temperature of the head chip
14
may be accordingly significantly decreased with respect to the conventional structure. Also, since the common chamber
22
has a larger (liquid) volume therein, the increasing rate of temperature in the head chip
14
may be somewhat decelerated with respect to the conventional structure.
FIG. 7
is a graph illustrating the increase of temperature in the head in accordance with the present invention as well as in the head of a conventional structure. As can be seen from the graph, the present invention may decelerate the increasing rate of temperature with the same heat sink when compared to the conventional structure, while the saturation temperature in the head may also be lowered by the heat radiation to the liquid. Thus, when using a larger heat sink in the conventional structure, the increasing rate of temperature may be equivalently slowed down, however the saturation temperature may not be decreased. In this way the present invention may avoid the printing failure by decreasing the saturation temperature, so that continuous, high-speed printing will be allowed to improve the printing productivity. In accordance with the preferred embodiment, the volume of the common chamber
22
will be approximately 2000 mm
3
, as compared with the volume of common chamber in the chip in the conventional structure of approximately 2 mm
3
, resulting in a volume of approximately 1000-fold. As can be clearly appreciated from the significant difference, the common chamber
22
in accordance with the present invention is drastically different from the conventional ink chamber.
Still another aspect of the present invention is to eliminate any dummy nozzles as used in the conventional structure. In the conventional structure in accordance with the Prior Art, a certain number of nozzles (for example, six to ten nozzles) are formed at the ends of the head chip, dedicated as dummy nozzles, which are not to use in printing. These nozzles were served for suppressing any printing failure caused by bubbles residing in either of both ends of common chamber and for purging bubbles by sucking. In accordance with the present invention, liquid may smoothly flow through the inlet
32
to the separate channels
20
, allowing prevention of residual bubbles even in the both ends of the common chamber
22
. Accordingly, dummy nozzles are basically unnecessary. As a result the head chip achievable in accordance with the present invention may become smaller while the manufacturing cost thereof may be lowered at the same time.
As alternative examples of the preferred embodiment, head structure as shown in
FIGS. 1B and 1C
may be equivalently used.
(Second Embodiment)
Now a liquid drop ejection type recording head in accordance with the second preferred embodiment of the present invention will be described in greater details hereinbelow with reference to
FIGS. 4 and 6
. The identical reference numerals refer to the member similar or identical to the first preferred embodiment above, so a detailed description thereof will be omitted for the sake of simplicity.
Now referring to the figures,
FIG. 4
is a perspective view of a head chip in accordance with the preferred embodiment of the invention,
FIG. 5
is a cross-sectional view of a liquid drop ejection type recording head in accordance with the preferred embodiment of the present invention, and
FIG. 6
is a cross-sectional view of another embodiment in accordance with the present invention.
The liquid path substrate
26
constituting a head chip
14
as shown in
FIG. 4
is different from the above mentioned first preferred embodiment in that there is no concaved recess
24
. Resultingly, a guide
26
B of the liquid path substrate
26
will be projected in the common chamber
22
, when the head chip
14
is affixed to the housing
12
. The guide
26
B may be arranged to be opposed to the heating element substrate
18
to form a guided path
40
there between.
The function of thus formed drop ejection type recording head
42
will be described below.
In this drop ejection type recording head
42
having a projected guide
26
B of the liquid path substrate
26
into the common chamber
22
, the liquid flow introduced form the common chamber
22
through the separate channels
20
will be narrowed the inflow area (cross section) by the guided path
40
and then introduced to the separate channels
20
, as well as the function similar to the above mentioned first preferred embodiment may be attained. Consequently, the guided path
40
may accelerate the flow rate of liquid as to introduce the liquid into the separate channels
20
in a more smooth way. In this manner, if bubbles are generated along with the increased temperature of liquid in the common chamber
22
, the smooth flow of liquid will catch up the generated bubbles and introduced into the nozzles
28
to eject simultaneously together with the liquid drops
36
, prior to growing to a size considered as printing defect. Increasing further the flow rate of liquid at the surface of the heating element substrate may also improve the radiation of heat from the substrate.
It should be noted that, as shown in
FIG. 6
, the surface of guide
26
B opposing to the heating element substrate
18
in the drop ejection type recording head
42
may be inclined to be a slanted plane
26
C the cross section of which is decreased toward the separate channels
20
, for the purpose of further smooth flow.
(Third Embodiment)
Next, a drop ejection type recording head in accordance with third preferred embodiment of the present invention will be described in greater details hereinbelow with reference to FIG.
8
. The identical reference numerals refer to the member similar or identical to the first preferred embodiment above, so a detailed description thereof will be omitted for the sake of simplicity.
FIG. 8
is a cross-sectional view of a liquid jet printing head in accordance with the third preferred embodiment of the present invention.
FIG. 9
is a cross-sectional view of another example of liquid jet printing head.
The liquid drop ejection type printing head
44
in accordance with the preferred embodiment has the structure as shown in
FIG. 8
with a heating element substrate
18
of the head chip
14
being housed in the housing
12
connected to the heat sink
34
.
With this configuration of liquid drop ejection type printing head
44
, the heating element substrate
18
may allow the liquid to come into contact not only with the surface of heating elements
18
A but also with the end
18
B. As a result, the heat radiation from the heating element substrate
18
to the liquid will be promoted so that the increased temperature of the heating element substrate
18
will be well controlled, allowing to improve the stability of high speed continuous printing.
The liquid drop ejection type printing head
44
may be arranged to cool the head chip
14
(heating element substrate
18
) more effectively with the liquid flow by contacting the backside
18
C of the heating element substrate
18
with the liquid, as shown in FIG.
9
.
(Fourth Embodiment)
Next, a drop ejection type recording head in accordance with fourth preferred embodiment of the present invention will be described in greater details hereinbelow with reference to FIG.
10
. The identical reference numerals refer to the member similar or identical to the first preferred embodiment above, so a detailed description thereof will be omitted for the sake of simplicity.
FIG. 10
is a perspective view of a head chip of liquid jet printing head in accordance with the fourth preferred embodiment of the present invention. Since the only difference from the first preferred embodiment is the head chip, this member only will be described in greater details.
The head chip
14
has terminals for electrical connection
46
for supplying power and signals to the heating elements concentrated at an end of the heating element substrate
18
in the direction of arrayed nozzles (the direction normal to the liquid drops
36
ejection, X direction of the arrow) as shown in FIG.
10
.
With this configuration of head chip
14
, the liquid flow from the inlet
32
to the separate channels
20
may become linear to improve the smoothness.
In the conventional liquid jet printing head, the signal terminals were disposed at the back end of the heating element substrate (see Y direction of the arrow in FIG.
20
and FIG.
21
). Since the flow path had to be designed so as to detour the terminals, the common chamber was a meandering path, which caused the residual bubbles. On the other had, in the liquid jet printing head
10
in accordance with the present invention, the terminals
46
are concentrated to a location at an edge of the heating element substrate
18
, perpendicular to the flow (direction of drop ejection). This configuration allows to supply the liquid to the separate channels
20
in the shortest and linear path without blocking the flow and to minimize the potentially residual bubbles.
(Fifth Embodiment)
Next, a drop ejection type recording head in accordance with fifth preferred embodiment of the present invention will be described in greater details hereinbelow with reference to FIG.
1
A and FIG.
11
. The identical reference numerals refer to the member similar or identical to the first preferred embodiment above, so a detailed description thereof will be omitted for the sake of simplicity.
FIG. 11
is a perspective view of a head chip of liquid jet printing head in accordance with the fifth preferred embodiment of the present invention.
As shown in
FIG. 11
, at the topmost layer of the heating element substrate
18
, a resin layer
48
is deposited as a protector film against the liquid. Immediately beneath the resin layer
48
is deposited a tantalum layer
50
, which is a high thermal conductive material for promoting the heat radiation from the heating element substrate
18
. The resin layer
48
provides holes
52
and
53
each for respective part of heating elements
16
and terminals
46
on the heating element substrate
18
, and an opening
54
formed in the part facing to the common chamber
22
. In this configuration, when the head chip
14
is affixed to the housing
12
, the liquid contained in the common chamber
22
will directly contact the tantalum layer
50
.
The function of thus configured liquid drop ejection type printing head (heating element substrate
18
) will be described below.
The temperature of the heating element substrate
18
will be gradually augmented by supplying continuous power to the heating elements
16
for ejection of liquid drops
36
. Furthermore, the increasing rate of temperature in the heating element substrate
18
will be larger for example in case wherein the heating element substrate
18
integrates the heating elements
16
with a peripheral circuitry, the circuitry itself generates heat by driving, in addition to the heating elements.
This preferred embodiment is intended to achieve supplemental heat radiation to the liquid in addition to the heat radiation of the heating element substrate
18
to the atmosphere by means of a heat sink
34
made of such material as aluminium. By enlarging the area of heating element substrate
18
in contact with the liquid and disposing the tantalum layer
50
, which is a high thermal conductive material, on the contacting portion, the efficiency of heat radiation to the liquid is improved.
Consequently, the heat sink
34
, which limited the size of head chip
14
, may be smaller, resulting in both the liquid jet printing head and the apparatus of a smaller size and lightweight.
(Sixth Embodiment)
Next, a drop ejection type recording head in accordance with sixth preferred embodiment of the present invention will be described in greater details hereinbelow with reference to FIG.
1
A and FIG.
12
. The identical reference numerals refer to the member similar or identical to the first and sixth preferred embodiments above, so a detailed description thereof will be omitted for the sake of simplicity.
FIG. 12
is a perspective view of a head chip of liquid jet printing head in accordance with the sixth preferred embodiment of the present invention.
In the fifth embodiment, a single large opening
54
was formed in the resin layer
48
at the position exposing the heating element substrate
18
to the common chamber
22
. In the sixth embodiment, plural smaller openings
54
will be formed.
When forming the opening
54
as one single opening as is the case of the fifth embodiment, the efficiency of heat radiation may be maximized. However, there may arise a problem of the precision of opening or flatness in the process step of piercing the polyimide or flattening the resin layer
48
, caused by the large size of opening
54
, if the resin layer
48
is flattened by chemical mechanical polishing (CMP) or the like. When configuring a number of openings
54
, as shown in
FIG. 12
, made by an individually separated etching pattern of the resin layer
48
, the heat radiation from the heating clement substrate to the liquid may be ensured, without a problem in manufacturing.
More specifically, the manufacturing problem will be described by way of example when forming a single large opening in the resin layer. In the process of CMP, abrasive particles called slurry are used. When a large opening is formed in the resin layer, some slurry may be accumulated in the opening. The polishing rate (the speed of polishing) in the proximity of the large opening will be faster than any other part. It may be difficult to flatten the entire surface due to the difference in polishing rate. Splitting the opening to plural openings will be effective for solving the problem as have been described above.
Preferably, as shown in
FIG. 13
, the split openings
54
B may be the approximately same size as the hole
52
at the location of heating elements, distributed vertically and horizontally at a predetermined interval space, and arranged to be staggered by displacing an array by a half span of the hole pitch. This configuration will further improve the flatness of the liquid jet printing head
10
in the course of manufacturing.
(Seventh Embodiment)
Next, a drop ejection type recording head in accordance with the seventh preferred embodiment of the present invention will be described in greater details hereinbelow with reference to FIG.
1
A and FIG.
14
. The identical reference numerals refer to the member similar or identical to the first, fifth and sixth preferred embodiments above, so a detailed description thereof will be omitted for the sake of simplicity.
FIG. 14
is a schematic diagram illustrating the deposition of resin layer on the top of heating element substrate. The only difference from the fifth and sixth embodiments is the deposition of resin layer, this member only will be described.
On the heating element substrate, as shown in
FIG. 14
, aluminium wirings
56
will be formed. A protection layer
58
of silicon nitride deposited by means of for example plasma CVD method may be formed for providing a step
60
. A tantalum layer
50
will be uniformly deposited on top of the protection layer
58
. Thereafter, on the step
60
exceeding a reference value, a resin layer liquid jet printing head
10
will be deposited as shown in FIG.
14
.
In case where the distance of the step
60
exceeds the reference value, there may probably be a portion
62
on which the tantalum layer
50
is not uniformly deposited at a predetermined thickness (referred to as defect of deposition hereinafter). If liquid is in contact with such defect of deposition
62
for longtime, the liquid may penetrate into inside of substrate through the defect of deposition
62
to corrode aluminium wirings
56
and the like to, ultimately, cause a failure of the head chip, in the worst case. Therefore, the heating element substrate
18
may be securely protected against the liquid by providing a resin layer liquid jet printing head
10
in advance at the step
60
exceeding a threshold value at which the defect of deposition
62
is likely to develop.
(Eighth Embodiment)
A liquid jet printing head in accordance with the eighth embodiment of the present invention will be described below in greater details. This embodiment is characterized in particular by the deposition of tantalum, which will be described among portions in question.
In this preferred embodiment, a rough surface of the protection layer
58
deposited on the heating element substrate
18
may be formed before depositing the tantalum layer
50
, a high thermal conductive material, on the rough surface. For example, as shown in
FIG. 15
, this embodiment may make use of ramps made by the aluminium wirings
56
to form thereon a smooth and wavy passivation layer
64
of silicon nitride (deposited for example by means of an atmospheric pressure CVD method) to deposit further thereon a tantalum layer
50
.
In this configuration, the deposited area (surface area) of the tantalum layer
50
may be increased to further efficiently promote the heat radiation of the heating element substrate
18
through the tantalum layer
50
to the liquid.
It may be preferable on the other hand to integrate, in the heating element substrate
18
shown in
FIGS. 1
to
15
, the heating elements
16
and the driver circuits (not shown in the figure) driving these heating elements
16
. For example, if there are 160 heating elements
16
, signal wirings and connection terminals for each of these 160 heating elements
16
will be required. If the driver circuits for these 160 heating elements
16
are integrated in the heating elements
16
at the time when the heating elements
16
are formed on the substrate
18
, the number of connection terminals may be decreased to approximately 30 or less, resulting in the shrinkage of the head chip
14
, decrease of bonding wires for communicating signals with external devices, as well as electrically high reliability of the head at the same time.
(Ninth Embodiment)
A preferred example of the method of manufacturing the path substrate used in the liquid jet printing head in accordance with the first embodiment above will be described below in greater details. The manufacturing method in accordance with this preferred embodiment, nozzles
28
and unpierced grooves
66
may be formed (see
FIG. 16B
) on the nozzle forming surface
26
D (see
FIG. 16A
) of the liquid path substrate
26
by means of the method disclosed in Japanese Published Unexamined Patent Application No. H11-227208. Although in Japanese Published Unexamined Patent Application No. H11-227208 grooves are to be pierced, grooves may be formed unpierced by the control of duration of etching. Thereafter, as shown in
FIG. 16C
, the backside
26
E of the path substrate (i.e., the side opposed to the nozzle forming side) will be processed (grinding, polishing, etching and the like) to expose (form) a groove
24
which may be part of the common chamber
22
(the groove may sometime be referred to as chamber groove).
The chamber groove
24
may be in general formed prior to the process of nozzles
28
(separate channels
20
), so that care should be taken when handling the liquid path substrate
26
which has the chamber groove
24
previously formed, otherwise the substrate may be damaged. In accordance with this preferred embodiment, the potential risks of defect of substrate may be avoided by piercing the common chamber as the final process of the path substrate by for example grinding, after shaping the nozzles
28
(separate channels
20
) and the like.
In the manufacturing method as have been described above, when piercing the chamber groove
24
on the liquid path substrate
26
with no support the substrate may have insufficient strength. The liquid path substrate
26
may be broken while processing in the worst case.
When using the processing method of the substrate as disclosed in Japanese Published Unexamined Patent Application No. H11-227208, if a (large) throughhole is pierced prior to process nozzles, the cooling gas for nozzle shaping (RIE) may be leaked from the back side
26
E of the path substrate through the pierced throughhole to the nozzle forming side
26
D to degrade the quality and precision of nozzles. Therefore, the throughhole will be opened by thinning (for example, grinding, polishing, etching and the like) the thickness of substrate from the back side
26
E thereof after the formation of nozzle, with no throughhole pierced at the time of forming nozzles. In this manner, the quality and precision of nozzle shaping may be ensured.
In order to improve the ease of handling of liquid path substrate
26
, as shown in
FIG. 17
, the process step of recession of the back side
26
E of the path substrate (for example by grinding) may be provided after the bonding with the heating element substrate
18
. When bonding the path substrate with the heating element substrate, the failure of liquid path substrate
26
may be avoided since the heating element substrate
18
may be served as a support when forming the chamber groove (throughhole)
24
on the liquid path substrate
26
.
If a process such as grinding or polishing is performed after bonding the liquid path substrate
26
with the heating element substrate
18
, there may arise another risk of clogging of separate channels
20
with swarf causing a failure of ejection of liquid drops
36
. Although it is possible to rinse several times after polishing the liquid path substrate
26
, the number and time of steps increases as well as the clogging may not be removed.
Then, the failure may be avoided by for example filling the separate channels
20
with some resin, preferably negative resist, through a predefined filler opening to prevent the penetration of swarf into the separate channels
20
. The filled resin can be removed with a remover solution after polishing, or with a developing fluid if negative type resist is used.
(Tenth Embodiment)
A representative example of liquid jet printing head in accordance with any one of the preferred embodiments described above combined with a liquid supplying apparatus will be described below.
A liquid supplying apparatus
70
may include, as shown in
FIG. 18
, a first reservoir
72
, which holds liquid with a free surface, and a second reservoir
74
, which supplies liquid to the first reservoir
72
while controlling the negative pressure applied to the first reservoir
72
. The second reservoir
74
incorporates a porous member
76
impregnated with the liquid and opened to the atmosphere, communicating to the first reservoir
72
through a meniscus member
78
.
At the bottom, the first reservoir
72
is connected to the common chamber
22
through a filter
80
. Warmed liquid by the heating element substrate
18
may be thereby circulated by convection from the common chamber
22
to the first reservoir
72
and vice versa through the filter
80
to promote the heat radiation of heating element substrate
18
more effectively.
(Eleventh Embodiment)
Now referring to
FIG. 19
, there is shown a perspective view of an exemplary liquid jet printing apparatus incorporating a liquid jet printing head in accordance with any one of the preferred embodiments as have been described above.
The liquid jet printing apparatus
82
incorporates a liquid dispenser
70
and a liquid jet printing head
10
(which head is not limited to the head described above in the first embodiment), both mounted on a carriage
86
slidably mounted on a guide shaft
84
.
The liquid jet printing head
10
may be arranged in the liquid jet printing apparatus
82
so as to direct the ejection of liquid drops from the liquid jet printing head
10
to the gravity direction or within the range of approximately 45 degrees from the gravity direction to displace bubbles remaining in the separate channels
20
and the common chamber
22
upwardly to separate from the proximity of separate channels
20
to prevent positively the printing failure due to bubble clogging.
The recordable medium
38
may be of any recordable medium including for example paper sheets, post cards, fabrics, and the like. The recordable medium
38
will be transported to the position facing to the liquid jet printing head
10
by a carrier mechanism.
Although in the above description there has been depicted and described the liquid jet printing head
10
with only one single common chamber
22
, the present invention is not limited thereto. For example, a configuration for color by integrating one head for one color may be devised within the scope of the present invention. If there are some common chambers each dedicated for a color, each chamber may incorporate respectively a sub-reservoir.
In conclusion, the liquid jet printing head and liquid jet printing apparatus in accordance with the present invention may prevent bubbles from residing in the common chamber or in the separate channels, and decrease the temperature of heating element substrate to enable stable, high speed, and continuous ink drop ejection (printing). Also a method of manufacturing a liquid jet printing head in accordance with the present invention may produce a printing head at higher precision.
Claims
- 1. A liquid jet printing head for jetting liquid by heating with a heating member, the liquid jet printing head comprising:a common liquid chamber having an inlet opening for supplying liquid from outside; a heating element substrate having plural heating elements thereon; plural separated channels for introducing liquid supplied through the common liquid chamber to the heating elements to eject the liquid through outlets; and a guide plate for narrowing a cross section of a path toward the channels, wherein the liquid supplied from the inlet flows through linearly to the outlet, and the heating element substrate is arranged along with the flow direction of the liquid.
- 2. The liquid jet printing head according to claim 1, wherein a guiding surface is provided for driving the liquid that flows through the common liquid chamber to the separate channels.
- 3. The liquid jet printing head according to claim 1, wherein the cross section of the path formed by the guide plate and the substrate is gradually diminished in the direction toward the separate channels.
- 4. The liquid jet printing head according to claim 1, wherein the heating element substrate is arranged so as to contact with the liquid on a surface other than that of the surface having the heating elements.
- 5. The liquid jet printing head according to claim 1, wherein the respective separate channels directly communicate with the common liquid chamber.
- 6. The liquid jet printing head according to claim 1, further comprising input/output terminals of electric signal on the surface of the heating element substrate, wherein the terminals are positioned near an end of the heating element substrate in a direction perpendicular to the liquid jet direction.
- 7. The liquid jet printing head according to claim 1, the heating elements comprising:a liquid-resistant thermal conductive material deposited on the surface of the heating element substrate; and a resin layer deposited on the surface of the heating elements such that a part of the thermal conductive material is exposed to the liquid.
- 8. The liquid jet printing head according to claim 7, wherein the resin layer defines a plurality of openings so that the thermal conductive material is partially exposed to the liquid.
- 9. The liquid jet printing head according to claim 8, wherein the openings are of the same shape.
- 10. The liquid jet printing head according to claim 9, wherein the openings are arranged in a staggered pattern.
- 11. The liquid jet printing head according to claim 7, wherein the liquid-resistant high thermal conductive material is disposed on the surface of the heating element substrate to provide a wavy ramp surface.
- 12. The liquid jet printing head according to claim 11, wherein the ramp of the high thermal conductive material exceeding a reference value is coated with the resin layer.
- 13. A liquid jet printing apparatus comprising a liquid jet printing head according to claim 1.
- 14. The liquid jet printing apparatus according to claim 13, wherein the liquid jet printing head is arranged so as to jet liquid in the angular range between the gravity direction and up to 45 degrees with respect to the gravity direction.
- 15. A method of manufacturing the liquid jet printing head according to claim 1, wherein the plural separate channels are defined by a silicon substrate, both the separate channels and the common liquid chamber are formed either by a crystalline anisotropic etching method or an anisotropic etching method of the silicon substrate.
- 16. The method of manufacturing the liquid jet printing head according to claim 15, comprising:a first step of etching a first surface of the silicon substrate to provide grooves forming a portion of the separate channels and the common liquid chamber; and a second step of processing the substrate from a second surface opposing the first surface to decrease the thickness of the substrate to pierce therethrough the groove for a portion of the common liquid chamber.
- 17. The method of manufacturing the liquid jet printing head according to claim 16, wherein the second process step is performed after bonding the silicon substrate and the heating element substrate.
- 18. The method of manufacturing the liquid jet printing head according to claim 15, the method further comprising the step of:forming a driver circuit of the heating element with the heating element on the surface of the heating element substrate by a semiconductor manufacturing technique.
- 19. A liquid jet printing head for jetting liquid by heating with a heating member, the liquid jet printing head comprising:a common liquid chamber having a wall portion on which a liquid flows; an inlet opening for supplying liquid from outside; an outlet opening; and a print head chip having a heating element substrate and a channel substrate, the print head being mounted in the common liquid chamber near the outlet opening, wherein the wall portion and the heating element substrate are coupled such that liquid supplied from the inlet flows through linearly to at least one heating element.
- 20. The liquid jet printing head according to claim 19, wherein a cross section of a path formed by the heating element substrate and the channel substrate is gradually diminished in a direction toward the outlet opening.
- 21. The liquid jet printing head according to claim 19, wherein a channel formed by the heating element substrate and the channel substrate directly communicates with the common liquid chamber.
- 22. The liquid jet printing head according to claim 19, further comprising input/output terminals of electric signal on the surface of the heating element substrate, wherein the terminals are positioned near an end of the heating element substrate in a direction perpendicular to the liquid jet direction.
- 23. The liquid jet printing head according to claim 19, the at least one heating element comprising:a liquid-resistant thermal conductive material deposited on the surface of the heating element substrate; and a resin layer deposited on the surface of the at least one heating element such that a part of the thermal conductive material is exposed to the liquid.
- 24. The liquid jet printing head according to claim 23, wherein the resin layer defines a plurality of openings so that the thermal conductive material is partially exposed to the liquid.
- 25. The liquid jet printing head according to claim 24, wherein the openings are of the same shape.
- 26. The liquid jet printing head according to claim 25, wherein the openings are arranged in a staggered pattern.
- 27. The liquid jet printing head according to claim 23, wherein the liquid-resistant high thermal conductive material is disposed on the surface of the heating element substrate to provide a wavy ramp surface.
- 28. The liquid jet printing head according to claim 27, wherein the ramp of the high thermal conductive material exceeding a reference value is coated with the resin layer.
Priority Claims (1)
Number |
Date |
Country |
Kind |
2000-064089 |
Mar 2000 |
JP |
|
US Referenced Citations (3)
Number |
Name |
Date |
Kind |
4723129 |
Endo et al. |
Feb 1988 |
A |
4774530 |
Hawkins |
Sep 1988 |
A |
5665249 |
Burke et al. |
Sep 1997 |
A |
Foreign Referenced Citations (8)
Number |
Date |
Country |
1-148560 |
Jun 1989 |
JP |
5-84917 |
Apr 1993 |
JP |
5-338168 |
Dec 1993 |
JP |
5-338177 |
Dec 1993 |
JP |
8-11866 |
May 1996 |
JP |
8-118653 |
May 1996 |
JP |
9-226142 |
Sep 1997 |
JP |
11-227208 |
Aug 1999 |
JP |