4. Incremental printing of symbolic information
  5. Ink jet
  6. Ejector mechanism

Structure of printhead

Incremental printing of symbolic information – Ink jet – Ejector mechanism

Reexamination Certificate

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Reexamination Certificate

active

06623109

ABSTRACT:

FIELD OF THE INVENTION
BACKGROUND OF THE INVENTION
In the current market of computer printers, ink-jet printers are relatively inexpensive in terms of good quality they offer. Compared with laser printers, each type of printers has its respective strengths and weaknesses. The ink-jet printers are lower priced but cost more in printing. The laser printers are more expensive, but cost less in printing. Therefore, for the ink-jet printers, the goal of lowering printing cost for greater competitiveness becomes a pressing task for further research and development.
Any ink-jet printing technology generally includes controlling devices for releasing ink to a printing surface. Regarding a ink-jet printing technology in the prior art, a printhead is fitted to a ink-jet cartridge, which releases ink jets in response to control signals.
Two methods, thermal-bubble and piezoelectricity methods, are generally employed by the printhead for releasing ink jets. In the thermal-bubble method, the printhead employs a membrane resistor that heats up small portion of ink (ink droplets) to gaseous state rapidly for releasing in jets through the nozzle.
In the piezoelectricity method, the printhead employs a piezoelectric element that compresses the volume of the ink in response to control signals for creating pressure waves and then forcing the ink droplets in jet though the nozzle.
One type of printheads for thermal-bubble ink-jet printers has been disclosed in the prior art, which is a layer structure manufactured via the VLSI manufacturing process, such as the layer structure disclosed in the U.S. Pat. No. 4,513,298. This layer structure is a three-dimensional structure gradually formed via multiple manufacturing steps.
FIG. 1
shows the plane elevated view of the printhead layer structure. The nozzle plate is removed in
FIG. 1
for clear illustration of the layer structure. As shown in
FIG. 1
, the components of the printhead includes at least the followings in proper order from the bottom to the top: a base layer
11
, a pattern layer
12
and a dry film of a channel barrier layer
13
. This structure is manufactured via the VLSI manufacturing process with add-in silicon chips. The topmost layer of the dry film of the channel barrier layer
13
is represented by dotted lines in FIG.
1
.
FIGS. 2 and 3
illustrate the printhead structure and mechanism.
FIG. 2
is a close-up view of the nozzle cavity and
FIG. 3
is a cross-sectional view of the nozzle cavity which shows the layer structure of one nozzle cavity. The dry film of the channel barrier layer
13
shown in
FIG. 1
is situated on the top of the pattern layer
12
and forms an ink channel
131
in the center of the channel barrier layer
13
and a plurality of ink cavities
132
on the two sides of the ink channel
131
.
As shown in
FIG. 2
, an ink first flows, via an ink cartridge (not shown), into an ink channel
131
and then into each ink cavity
132
. Referring to
FIG. 3
, where the nozzle plate
14
and the dry film of a channel barrier layer
13
are thermally compressed together for tight adhesion. The nozzle plate
14
has a plurality of openings corresponding to each ink cavity
132
. With ink flowed into it, the ink of each nozzle cavity
132
is heated up by the heating layer
121
of the pattern layer
12
in response to the control signals from the printer, so that the ink expands in volume and is jetted out through the openings of the nozzle plate
14
.
FIG. 3
further illustrates the layer structure of the printhead in which the base layer
11
includes a silicon base layer
111
and a silicon dioxide layer
112
for forming the base of the printhead, and the pattern layer
12
includes a heating layer
121
, a first passivation layer
122
and a second passivation layer
123
for forming the ink-heating structure for the printhead.
FIG. 4
is a cross-sectional view along the A—A line of the printhead shown in FIG.
1
. It can be seen that when the pattern layer
12
is formed on the two sides of the ink channel
131
, there emerges a height differential (about 0.6 &mgr;m) between the pattern layer
12
and the gap which is formed at the ends of the ink channel
131
because there is none pattern layer
12
arranged on the two opposite ends of the ink channel
131
. Hence as the dry film of channel barrier layer
13
is formed on its top, a step differential d of about 0.6 &mgr;m is created at the ink channel
131
. When adhering nozzle plate
14
(usually made of nickel) onto the dry film of a channel barrier layer
13
(usually high polymer compound of Morton, Vacrel or the likes), high temperature at 120° C. and high pressure are needed for 2 to 5 minutes for the high polymer to combine with the nozzle plate
1
.
Referring to
FIG. 4
again, as the nozzle plate
14
is thermally pressed along the directions pointed by the arrows for adhesion with the dry film of the channel barrier layer
13
, a greater pressure is required to deform the dry film of channel barrier layer
13
, so that it pushes and squeezes the ink channel
131
for closing up gaps created by the step differential d for preventing the ink leakage though such gaps.
However, the great tangential shear force B, generated by the great pressure due to the thermal compression of
FIG. 4
, may cause the dry film of the channel barrier
13
in each ink cavity
132
to be deformed transversely so that it leads to reduce internal volume and raises higher printhead ill rates. Generally, the tolerable error for the size of the ink cavity
132
is within +/−10&mgr;. If the thermal pressure is too high, the ill rate will increase.
As the step differential d of pattern layer
12
is responsible for causing in the compression process of the nozzle plate
14
, the primary object of the present invention is to provide a manufacturing method for the printhead and the structure thereof, which can reduce the differential on the two opposite ends of ink channel
131
, so that the dry film of channel barrier layer
13
is made smoother, and the nozzle plate
14
can adhere tightly with the dry film of channel barrier layer
131
for eliminating the ink leakage problem.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a structure of a printhead for raising its product acceptance rate and improving its quality.
According to the present invention, a structure of a printhead, including a base layer, a pattern layer disposed on the base layer and having a flow pattern disposed on two opposite ends of the base layer and having a space location for forming thereabove a flow channel, and a base pattern disposed on two opposite sides of the base layer and having plural apertures for forming thereabove plural ink cavities, wherein the flow pattern and the base pattern surround a central location for forming thereabove an ink channel, the base pattern includes at least a heating layer and a passivation layer, and the flow pattern is made of the same material and at the same height as those of the base pattern, a channel barrier layer disposed on the pattern layer and having a dry film, the ink channel, the flow channel and the plural ink cavities, and a nozzle plate adhered to the dry film of the channel barrier layer, wherein the nozzle plate has plural ink openings disposed over the ink cavities.
Certainly, the nozzle plate can be adhered to the dry film of the channel barrier layer by thermal compression.
Certainly, the pattern layer can be made by means of a semi-conductor manufacturing process.
Certainly, the heating layer can be made of tantalic aluminum (TaAl).
Certainly, the first passivation can be made of one of silicon nitride (Si3N4) and silicon carbide (SiC).
Certainly, the second passivation can be made of tantalum (Ta).
Certainly, the nozzle plate can be made of nickel (Ni).
Preferably, the base pattern and the flow pattern are in discontinuously alternate arrays.
Preferably, the flow pattern incluses a first flow pattern and a second flow pattern disposed in discontinuously arrays for forming thereabove a flow channel.
Pr

Chang Ying-Lun

Inventor

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Chou Chin-Yi

Inventor

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Mou Tse-Chi

Inventor

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Yu Cheng-Hung

Inventor

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Brooke Michael S

Examiner

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Madson & Metcalf

Law Firm

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Microjet Technology Co., Ltd.

Corporate Assignee

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Nguyen Judy

Examiner

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