Incremental printing of symbolic information – Ink jet – Ejector mechanism
Reexamination Certificate
2002-11-25
2004-07-27
Meler, Stephen D. (Department: 2853)
Incremental printing of symbolic information
Ink jet
Ejector mechanism
Reexamination Certificate
active
06767081
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a thermal head for use with a thermal printer, and more particularly to a power-thrifty thermal head having high-speed thermal responsivity.
2. Description of the Related Art
In recent years, the thermal head has been heavily used for a recording device for various information apparatuses. Thus, in order to speed up, reduce the prices of, reduce power requirements of, and miniaturize these information apparatuses, a power-thrifty thermal head having high-speed thermal responsivity has also been requested.
In order to realize such a thermal head having high-speed thermal responsivity, for heat insulating layer material, material with thermal conductivity decreased can be used, and the thickness of the heat insulating layer can be made thinner to reduce the thermal capacity. However, it is technically difficult to decrease the thermal conductivity of a glaze heat insulating layer material which has conventionally been used, and when the glaze heat insulating layer is used, the thermal capacity of the glaze heat insulating layer has been decreased by simply forming to make the thickness thereof thinner, and the reserve heat has been reduced.
For this reason, high-speed printing has generally been performed with desired thermal responsivity while sacrificing savings in electric power.
With reference to
FIG. 5
, the description will be made of such a conventional thermal head. On the top surface of a substrate
1
with heat dissipating property, made of alumina or the like, there is formed a glaze heat insulating layer
2
made of glass, having thermal conductivity of nearly 1.1 W/m.k.
This glaze heat insulating layer
2
is formed so as to be as thick as, for example, 200 &mgr;m in thickness, and is formed with a projecting section
2
a
in which a portion formed with a heating element
3
a
to be described later protrudes at a predetermined height.
Also, on the top surface of the glaze heat insulating layer
2
, there is formed a heating resistor
3
made of Ta—SiO
2
, TiO
2
and the like, and on the top surface of this heating resistor
3
, there are formed a common power feeding member
4
and an individual power feeding member
5
. In a portion sandwiched between this common power feeding member
4
and the individual power feeding member
5
, there is formed a heating element
3
a.
On top of these components, a protective layer
6
made of ceramic such as Thialone is covered so as to prevent the heating element
3
a
or the common power feeding member
4
, the individual power feeding member
5
and the like from being oxidized or worn.
In the conventional thermal head having such a structure, the individual power feeding member
5
is pulse-energized on the basis of printing information, whereby the heating element
3
a
is adapted to be able to selectively generate heat.
However, since such a conventional thermal head as described above has been only the glaze heat insulating layer
2
as extremely thick as, for example, 200 &mgr;m in thickness formed on top of the substrate
1
with heat dissipating property, it has the same thermal conductivity.
For the reason, the exothermic temperature due to single pulse energization while the glaze heat insulating layer
2
has been cool becomes a low exothermic temperature without regard to the thickness of the glaze heat insulating layer
2
. Accordingly, since great applied energy is requested during energization, there has been the problem that at the head of line at the commencement of printing, no power saving effect has been obtained, and a peak current of the battery cannot be reduced.
Also, when pulse energization is continuously performed, reserve heat in a portion in which the heating element
3
a
with great printing duty has been formed in the glaze heat insulating layer
2
remarkably increases because of inferior heat dissipating property of the glaze heat insulating layer
2
.
For the reason, the exothermic temperature of the heating element
3
becomes excessively high, and exceeds a control range of control of energized heat, which might possibly cause deteriorated printing quality due to blotting, tailing or the like on an image printed on a recording sheet.
However, in recent years, there has been disclosed a heat insulating layer material, of which power saving does not have to be sacrificed, and which is excellent in thermal responsivity. Such heat insulating layer material is obtained by forming low oxide ceramic with low thermal conductivity by means of oxygen reactive sputtering deposition.
With reference to
FIG. 6
, the description will be made of a conventional thermal head using such a heat insulating layer material as described above. On the surface of a substrate
11
excellent in heat dissipating property, made of silicon or the like, there is formed a projecting section
11
a
having a predetermined height by means of the photolithography technique, and on top of this projecting section
11
a
, a heat insulating layer
12
is stacked and formed.
The heat insulating layer
12
is made up of Si, plural transition metals and oxygen, has low thermal conductivity and electrical conductivity, having thermal conductivity of nearly 0.8 W/m.k and electrical resistivity of nearly 100 &OHgr;-cm, and is formed to have a thickness of 10 to 30 &mgr;m on the substrate
11
by means of the oxygen reactive sputtering deposition.
Also, on the top surface of the heat insulating layer
12
, in order to impart insulation characteristics and resistance to etching to the surface, an insulating layer
13
made of ceramic with insulation characteristics such as SiO
2
and Al
2
O
3
is stacked and formed in a single layer at a thickness of nearly 2 &mgr;m by means of the sputtering deposition or the like.
Also, on the top surface of the insulating layer
13
as a single layer, a heating resistor
14
made of Ta—SiO
2
, Ti—SiO
2
and the like is stacked by means of the sputtering deposition or the like, and a pattern of the heating resistor
14
is formed by means of the photolithography technique.
On the top surface of the heating resistor
14
, a common power feeding member
15
and an individual power feeding member
16
which is made of Al, Cu and the like are formed, and a portion sandwiched between this common power feeding member
15
and the individual power feeding member
16
is formed with a heating element
14
a.
On top of these components, a protective layer
17
made of ceramic such as Thialone is covered so as to prevent the heating element
14
a
, the common power feeding member
15
, the individual power feeding member
16
and the like from being oxidized or worn.
Since there is formed a heat insulating layer
12
of low thermal conductivity on top of a silicon substrate
11
of high thermal conductivity, the conventional thermal head having such a structure is capable of obtaining high exothermic temperature at a heating element
14
a
due to single pulse energization to be singly driven, and decreasing printing blurring at the head of lines where the temperature of the substrate
11
is low at the commencement of printing.
Also, peak current of the power supply is decreased and it is possible to reduce power requirements and to miniaturize the power supply. Also, on account of a combination of the substrate
11
excellent in heat dissipating property with the heat insulating layer
12
with low thermal capacity excellent in heat insulating properties due to continuous pulse energization to be continuously driven, even in continuous energization, it is possible to gently raise the temperature at the substrate
11
due to reserve heat and to provide a thermal head excellent in high-speed printing with power requirements reduced.
However, such a conventional thermal head using the heat insulating layer material as described above has had the problem that even if, on top of the heat insulating layer
12
of electrical conductivity, the heating resistor
14
and the power feeding members
15
and
16
are stacked through the
Jumonji Masahisa
Kubo Satoshi
Shirakawa Takashi
Alps Electric Co. ,Ltd.
Brinks Hofer Gilson & Lione
Do An H.
Meler Stephen D.
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