Inkjet head having plural ink supply channels between ink chambers and each pressure chamber

BACKGROUND OF THE INVENTION

The present invention generally relates to print heads for printers, and more particularly to a head (or an inkjet head) for use with an inkjet printer. The inkjet head of the present invention is applicable not only to a single printer unit but also widely to copiers, facsimile machines, computer systems word processors, and combination machines thereof which have a printing function.

Among inkjet heads, those which employ a piezoelectric element have increasingly come into the limelight in recent years due to their excellence in energy efficiency. This type of inkjet head typically includes a piezoelectric element, one common ink chamber which receives from an external device and stores ink, a plurality of pressure chambers coupled to the piezoelectric element, and a nozzle plate so connected to the pressure chambers that a nozzle may be connected to each pressure chamber. Each pressure chamber is connected to the common ink chamber through an ink supply channel so that it may receive ink from the common ink chamber and increase its internal pressure using deformation of the piezoelectric elements, thereby jetting ink from each nozzle.

In recent years, piezoelectric elements have often been manufactured by printing or sputtering of LSI technology. The LSI technology facilitates miniature piezoelectric elements, while the miniature ink supply channels are needed as well. A higher resolution is also needed by reducing an interval between two nozzles of adjacent pressure chambers (i.e., nozzle pitch) and increasing the number of nozzles. The miniature ink supply channels are also required for this purpose. The miniature ink supply channels are thus sought for both manufacturing and higher-resolution purposes.

According to ink's hydraulic resistance equivalence, a doubled number of ink supply channels would make the length of the ink supply channel twice as long as that of one ink supply channel. A quadrupled number of ink supply channels would make the length of the ink supply channel four times as long as that of one ink supply channel. Thus, in terms of hydrodynamics, ink's hydraulic resistance equivalence is maintained by increasing the length of the ink supply channel by the number of ink supply channels.

On the other hand, an ink supply channel has been demanded which is longer than a distance between adjacent pressure chambers since a long ink supply channel would enhance rigidity and strength of a wall between the common ink chamber and each pressure chamber. Some head configurations are required to be a adhered to a thin film before being adhered to a piezoelectric element in a pressure-chamber plate that includes pressure chambers, ink supply channels and a common ink chamber. Such a head calls for a longer ink supply channel so that the thin film can be firmly adhered to a larger area between each pressure chamber and the common ink chamber.

For these requirements, each pressure chamber has been allocated a plurality of (e.g., four) ink supply channels that align with a direction in which the pressure chambers are arranged in a conventional inkjet head.

However, the instant inventors have discovered those ink supply channels, which align with a direction in which the pressure chambers are arranged as in the conventional inkjet head, would prevent a higher resolution. This is because a nozzle pitch that is designed to be narrow so as to attain a high integration would necessarily lead to the narrow pressure chamber width, and it would be extremely difficult to establish multiple ink supply channels in the narrow width.

BRIEF SUMMARY OF THE INVENTION

Accordingly, it is an exemplified general object of the present invention to provide a novel and useful inkjet head and its manufacturing method in which the above disadvantages are eliminated.

A more specific object of the present invention is to provide an inkjet head and its manufacturing method which may realize a high resolution, maintain at a desired strength a wall that defines an ink supply channel between a common ink chamber and each pressure chamber, and secures a sufficient adhesion area on the wall.

The present invention also has an object to provide an inkjet head and its manufacturing method which allocate a plurality of ink supply channels so as to connect each pressure chamber to the common ink chamber, and use a dry film resist for high-precision and efficient manufacturing.

To achieve the above objects, an inkjet head of the present invention comprises a pressure-chamber plate which includes a plurality of pressure chambers which store ink and a plurality of ink supply channels that supply the pressure chamber with the ink, a piezoelectric element that may pressurize the pressure chamber in the pressure-chamber plate, and a nozzle plate that includes a nozzle which jets the ink in the pressure chamber when the piezoelectric element pressurizes the pressure chamber, wherein some of the ink supply channels are connected by the plural number to each pressure chamber, and arranged in a direction perpendicular to that in which the plurality of pressure chambers are arranged. Alternatively, said ink supply channels may be connected by the plural number to each pressure chamber, and arranged two-dimensionally at random with respect to a plane parallel to a direction in which the plurality of pressure chambers are arranged.

A manufacturing method for an inkjet head which is manufactured by joining a plurality of layered members that is made of independent multiple layers, including the step of forming one of the plurality of layered members which comprises the steps of forming a layered member by laminating a dry film resist onto a substrate having a predetermined shape, exposing part of the layered member which corresponds to pressure chambers, an ink supply channel, and a common ink chamber, and developing the layered member, wherein a plurality of ink supply channels are formed and connecting each of a plurality of pressure chambers to the common ink chamber, a direction in which the plurality of pressure chambers are arranged being perpendicular to that in which the ink supply channels allocated to each of the plurality of pressure chambers are arranged.

A manufacturing method of an inkjet head of the present invention comprises the steps of forming first and second layers defining at least one of an introduction path, a pressure chamber, an ink supply channel and a common ink chamber by using a dry film resist, forming a rigid layer on either one of the first and second layers, and joining the first and second layers to each other via the rigid layer.

A printer of the present invention comprises an inkjet head, and a drive unit which drives the inkjet head, wherein the inkjet head comprises a pressure-chamber plate that includes a plurality of pressure chambers which store ink and a plurality of ink supply channels which supply the pressure chambers with the ink, a piezoelectric element that may pressurize the pressure chamber in the pressure-chamber plate, and a nozzle plate that includes a nozzle which jets the ink in the pressure chambers when the piezoelectric element pressurizes the pressure chamber, wherein part of the ink supply channels are connected to each pressure chamber, and arranged in a direction perpendicular to that in which the plural pressure chambers are arranged.

A printer and an inkjet head of the present invention include a plurality of ink supply channels that are connected to each pressure chamber and arranged in a direction perpendicular to a direction in which the pressure chambers are arranged. Therefore, where the predetermined number of ink supply channels is needed, all of them need not align with a direction in which the pressure chambers are arranged. This however intends to exclude a structure in which all of the ink supply channels align with a direction with which the pressure chambers align, and not to prohibit some of the ink supply channels from aligning with the direction with which the pressure chambers align. For example, given three ink supply channels, two of them may align with a direction with which the pressure chambers align. Alternatively, the ink supply channels may be arranged two-dimensionally at random, independently of the direction in which the pressure chambers are arranged. Hereupon, the clause “arranged two-dimensionally at random” intends to exclude a structure in which all of the ink supply channels align only with a direction with which the pressure chambers align, as described in more detail in the following embodiments.

The number of ink supply channels that are allocated to each pressure chamber of the present invention is determined as follows. Firstly, a size of one ink supply channel that may maintain a proper balance with ink's hydraulic resistance as described in the following embodiment with reference to

FIG. 6

is determined in terms of the depth, length and width of the ink supply channel. Where a dry film resist is used to create an ink supply channel, the thickness of the dry film resist becomes the depth of the ink supply channel. Thus, from among some dry film resist candidates having different thickness, those dry film resists having the depth with little fluctuation in terms of the depth, length and width of the ink supply channel are selected. This determines the thickness of a dry film and consequently the size of the ink supply channel. The ink supply channel determined here, however, becomes shorter than an interval (i.e., wall thickness) between the adjacent pressure chambers, and would deteriorate the strength and adhesion with another component of the wall that defines the ink supply channels. The present invention accordingly intends to keep ink's hydraulic resistance equivalent by setting the ink supply channel to be at least equal to, or preferably longer than, the wall between the pressure chambers, while setting the number of ink supply channels to be a quotient produced by dividing the wall thickness between the pressure chambers by the original length of the ink supply channel.

A member with a high Young's modulus, if provided between two adjacent ink supply channels connected to each pressure chamber, would prevent these ink supply channels from negatively influencing each other, keeping them stable.

The manufacturing method of an inkjet head of the present invention allows the ink supply channels made of a dry film resist to align with a direction different than that with which the pressure chambers align. A metal or ceramic layer, if provided between two dry film resists that form an ink supply channel, would keep adjacent ink supply channels stable even after they are joined. A resin or composite resin member, if used in place of metal or ceramic, has a thermal expansion coefficient close to that of a dry film resist, and would provide an inkjet head with thermally homogeneous components.

The manufacturing method for an inkjet head of the present invention that provides a layer comprising such a rigid member as metal or ceramic between the adjacent layers defining ink supply channels, may be widely applied in general as a manufacturing method for an inkjet head using dry film resists.

Other objects and further features of the present invention will become readily apparent from the following description of the embodiments with reference to accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1

is a schematic perspective view of an inkjet printer to which an inkjet head of the present invention is applicable.

FIG. 2

is a partial plan view of an inkjet head of a first embodiment according to the present invention.

FIG. 3

is a cross section taken along line A-A′ in FIG.

2

.

FIG. 4

is a cross section taken along line B-B′ in FIG.

3

.

FIG. 5

is an exemplified variation of the arrangement of ink supply channels shown in FIG.

4

.

FIG. 6

is a graph that shows the relationship among the depth, length and width required for one ink supply channel in order to realize the desired ink hydraulic resistance.

FIG. 7

is a perspective view showing a series of manufacturing steps for an inkjet head of a first embodiment of the invention.

FIG. 8

is a flowchart for explaining the manufacturing steps in FIG.

7

.

FIG. 9

is a flowchart for explaining part of the flowchart in

FIG. 8

more concretely.

FIG. 10

is another flowchart for explaining part of the flowchart in

FIG. 8

more concretely.

FIG. 11

is a partial plan view of an inkjet head of a third embodiment of the present invention.

FIG. 12

is a cross section taken along line A-A′ in FIG.

11

.

FIG. 13

is a cross section taken along line B-B′ in FIG.

12

.

FIG. 14

is a partial plan view of an inkjet head of the third embodiment according to the present invention.

FIG. 15

is a cross section taken along line A—A in FIG.

14

.

FIG. 16

is a cross section taken along line B-B′ in FIG.

15

.

FIG. 17

is a perspective view showing a series of manufacturing steps for an inkjet head of a third embodiment according to the present invention.

FIG. 18

is a flowchart for explaining the manufacturing steps in FIG.

17

.

FIG. 19

is a flowchart for explaining part of the flowchart in

FIG. 18

more concretely.

FIG. 20

is another flowchart for explaining part of the flowchart in

FIG. 18

more concretely.

DETAILED DESCRIPTION OF THE INVENTION

A description will now be given of inkjet head

100

, its manufacturing method, and inkjet printer

1

having the head

100

of the present invention and its manufacturing method, with reference to the accompanying drawings. Those elements in each drawing that are designated by the same reference numerals denote the same elements. and a duplicate description will be omitted. Those elements, which are designated by the same reference number and an alphabetical letter, indicate that they are the same types of components, but are differentiated by the alphabet character and are grouped by simple reference numbers.

FIG. 1

schematically shows an embodiment of color ink et printer (recording device)

1

which may employ the inkjet head

100

of the present invention that is described later in detail. Housing

10

of the recording device

1

pivotally includes platen

12

.

In recording operation, the platen

12

is driven and intermittently rotated by drive motor

14

, whereby printing paper P is fed intermittently at a predetermined pitch in arrow direction W. The housing

10

of the recording device

1

also includes guide rod

16

parallel to and above the platen

12

, and carriage

18

is slidably attached to this guide rod

16

.

The carriage

18

is attached to free-end drive belt

20

that is driven by drive motor

22

, whereby the carriage

18

is reciprocated (scanned) along the platen

12

.

The carriage

18

is mounted with recording head

24

for black color and recording head

26

for multiple colors. The recording head

26

for multiple colors may be comprised of three parts. The recording head

24

for black color is detachably mounted with black ink tank

28

, while the recording head

26

for multiple colors is detachably mounted with color ink tanks

30

,

32

, and

34

. The inkjet head

100

of the present invention is applied to these recording heads

24

and

26

as described later.

The black ink tank

28

stores black ink, whereas the color ink tanks

30

,

32

and

34

respectively store yellow ink, cyan ink and magenta ink.

While the carriage

18

reciprocates along the platen

12

, the recording head

24

for black color and the recording heads

26

for multiple colors are driven based upon image data obtained from a word-processor, a personal computer, etc., thereby recording given characters, images, etc. on the printing paper P. When the recording operation ends, the carriage

18

returns to a home position, where a nozzle maintenance mechanism (backup unit)

36

is provided.

The nozzle maintenance mechanism

36

includes a movable suction cap (not shown) and a suction pump (not shown) connected to this movable suction cap. When the recording heads

24

and

26

are positioned at the home position, the suction cap becomes adhered to the nozzle plate in each recording head, and nozzles on the nozzle plate are suctioned by driving the suction pump, thus preventing any nozzle clogs.

Next, a description will be given of the inkjet head

100

of the present invention by referencing

FIGs. 2 through 4

. Hereupon,

FIG. 2

is a partial plan view of the inkjet head

100

of the present invention.

FIG. 3

is a cross-sectional view taken along line A—A′ in FIG.

2

.

FIG. 4

is a cross-section view taken along line B—B′ in FIG.

3

.

The inkjet head

100

of the present invention includes pressure-chamber plate

102

, oscillatory plate

104

, nozzle plate

106

and piezoelectric element

108

.

As described later in detail, the pressure chamber plate

102

includes a layered member in which a plurality of dry film resists

103

are laminated onto stainless plate

105

, and forms common ink chamber

110

, a desired number of pressure chambers

112

, a plurality of ink supply channels

114

and introduction path

116

by a photo-lithography manufacturing method. For more details, layers

1

-

3

,

5

,

6

and

8

from the top are each the dry film resist

103

, and layers

4

and

7

from the top are stainless plate

105

in

FIG. 3. A

patterning process which uses a dry film resist facilitates a 0.1-1 μm precision mass manufacture by the photo-lithography manufacturing method, and thus it is useful as a component for an inklet head that requires high precision and low cost.

Optionally, the present invention may make the pressure-chamber plate

102

of an approximately cuboid glass plate, but it exhibits an additional effect if using a dry film resist, as described later.

The common ink chamber

110

supplies ink to each pressure chamber

112

through the ink supply channels

114

. The common ink chamber

110

has such an adjusted ink hydraulic resistance as would absorb a sudden fluctuation in the internal pressure of the pressure chamber

112

, and is connected to an external ink supply device (not shown). The common ink chamber

110

supplies a necessary amount of ink to the pressure chamber

112

, when the pressure chamber

112

recovers the position after discharging ink as a result of compression and contraction. Such an ink supply is controllable by the ink hydraulic resistance.

The pressure chamber

112

is formed as an approximately cuboid space by cutouts in each layer in the pressure-chamber plate

102

and the elastically deformable oscillatory plate

104

. A plurality of pressure chambers

112

align in direction C in

FIGS. 2 and 4

. The pressure chamber

112

receives and stores ink, and jets it from the nozzle

120

via the introduction path

116

as the internal pressure increases. As described later, the internal pressure changes as the piezoelectric element

108

deforms. In addition, as described later, the introduction path

116

is not an indispensable element of the pressure-chamber plate

102

.

A design of the inkjet head

100

requires the determination of a size of ink supply channel

114

. The ink supply channel

114

is so dimensioned that the pressure chamber

112

may jet an adequate amount of ink from the nozzle

120

. When the pressure chamber

112

jets ink from the nozzle

120

, ink also regurgitates to the ink supply channels

114

. Nevertheless, the proper balance in ink hydraulic resistance between a channel from the pressure chamber

112

to the nozzle

120

and that from the pressure chamber

112

to the ink supply channel

114

would enable ink to be jetted mainly from the nozzle

120

.

A description will be given below of how to determine the size (depth Ds, length Ls and width Ws) of ink supply channel

114

having the proper ink hydraulic resistance. The inkjet head

100

of this embodiment sets the nozzle

120

to be 20 μm in diameter and 20 μm in length, the introduction path

116

85 μm across and 70 μm long, and the pressure chamber

112

1700 μm across, 100 μm wide and 130 μm deep.

Table 1 below shows how the matching length Ls and width Ws of the ink supply channel

114

change accordingly when its depth Ds changes in increments of 1 μm from 13 to 30 μm.

FIG. 6

shows a relationship between Ds and Ls, and that between Ds and Ws.

Size of Ink Supply Channel 114 (μm)

Depth Ds

Length Ls

Width Ws

13

172.2

190.9

14

49.6

51.0

15

34.5

33.1

16

29.7

26.7

17

27.7

23.5

18

26.9

21.6

19

26.7

20.2

20

26.7

19.2

21

26.8

18.4

22

27.1

17.7

23

27.5

17.2

24

28.0

16.8

25

28.6

16.5

26

29.2

16.2

27

29.9

15.9

28

30.6

15.7

29

31.3

15.5

30

32.0

15.4

In an attempt to form the ink supply channel

114

by a patterning process using a dry film resist, the depth Ds of the ink supply channel

114

is determined by the thickness of the dry film resist. This embodiment prepares 14 μm, 24 μm and 29 μm as the thickness of the dry film resist. Referring to these values in

FIG. 6

, it is understood that Ds fluctuation would greatly change, where Ds−14 μm, required values of both Ls and Ws and would provide the manufacturing with only a small margin for patterning size. In contrast, Ds fluctuation would not greatly change, where Ds−24 μm or 29 μm, required values of both Ls and Ws, providing a mitigated patterning size precision for the photo-lithography manufacturing method. Accordingly, this embodiment has selected Ds−29 μm that would cause less fluctuation. Empirically, the Ds fluctuation would result in a decrease by −1 μm or so in the joining process that will be described later.

FIG. 6

shows that one ink supply channel having a size of Ls=31.3 μm and Ws=15.5 μm may be formed where Ds=29 μm is selected. According to

FIG. 3

, the length Ls of an ink supply channel is also the length of a wall between each pressure chamber

112

and the common ink chamber

110

, and this wall requires a certain degree of rigidity and strength (at least longer than an interval between the adjacent pressure chambers

112

). This wall also requires a sufficient adhesion area for firm adhesion with upper and lower layers. Ink's hydraulic resistance of the ink supply channel

114

is equivalently maintained as far as its length Ls is in proportion to the number of the channels. Accordingly, this embodiment has used four ink supply channels each of which has a size of Ls=125 μm, which is calculated by Ls=31.3 μm x 4≈125 μm, Ds=29 μm and Ws=15.5 μm.

These four ink supply channels

114

are connected to each pressure chamber

112

, but arranged, as best shown in

FIG. 4

, in a 2×2 matrix in direction C and direction D perpendicular to the direction C.

According to this embodiment, as shown in FIG.

4

and

FIG. 5

which will be described later, where four ink supply channels

114

are referred to as

114

a

to

114

d,

the Young's modulus for a layer (stainless layer

105

a

in

FIG. 3

) which partitions

114

a

and

114

c

as well as

114

b

and

114

d

is higher than the Young's modulus of the dry film resist layer

103

c

forming

114

a

and

114

b,

and higher than the Young's modulus of the dry film resist layer

103

d

forming

114

c

and

114

d.

The stainless layer

105

a

may use another rigid metal or ceramic material.

The layer

105

a

having such a high Young's modulus, which will be described by referring to

FIG. 7

later, allows the ink supply channels

114

to be formed in the layers

103

c

and

103

d

with high precision using a dry film resist.

As a typical conventional inkjet head arranges and levels with one another all the ink supply channels

114

in direction C, this arrangement prevents the pressure chamber

112

to be narrowed in the direction C, limiting the realization of high resolution. The width of each pressure chamber

112

in this embodiment is 100 μm. If four ink supply channels

114

having width Ws=15.5 μm are formed on the same dry film resist layer as the pressure chamber

112

, the remaining width in the dry film resist would be about 13 μm, thus making the patterning difficult.

Accordingly, a 5 pl ink drop jet has been realized by dividing and laminating four ink supply channels into two each in the direction of the depth (direction D) of the pressure chamber, as shown in FIG.

4

. The pitch between the adjacent pressure chambers (nozzles) has been then {fraction (1/150)}inches (=169 μm). Four rows of nozzles

120

could realize the resolution of about 600 dpi. When the pressure chamber width is further narrowed in accordance with the settings of the characteristics of a drive element and an ink jet, the ink supply channel

114

may be likewise designed.

Although the present invention thus arranges some of the ink supply channels

114

in the direction C and the remaining in the direction D perpendicular to C direction, it may be easily understood that any number from 1 to 3 may be selected for arrangement in the direction C. For example, three ink supply channels arranged in the C direction and one in the D direction would realize higher resolution than the conventional configuration, and thus this variation is also within the scope of the present invention. The arrangement of one in the C direction and the remaining three in the D direction will be described later.

“A direction perpendicular to the direction (the direction C) in which the piezoelectric elements are arranged” in this application apparently includes not only the direction D but direction E, as the embodiment will be described later. The ink supply channels

114

need not form a complete matrix. For example, the present invention covers such a structure as would arrange the ink supply channels

114

two-dimensionally at random as shown in

FIG. 5

, when the inkjet head

100

is sectioned on a plane parallel to the direction in which the piezoelectric elements

108

are arranged. Those structures which arrange “the ink supply channels two-dimensionally at random” cover all the structures except the one that arranges the ink supply channels

114

only in the direction in which the piezoelectric elements

108

are arranged.

The locations of the introduction path

116

and nozzle

120

are not limited to those shown in FIG.

3

. For example, a nozzle plate including nozzles may be in the left end in

FIG. 2

so as to jet ink parallel to the direction E, while the introduction path

116

is omitted.

The oscillatory plate

104

and piezoelectric element

108

, which are composed as a bimorph layered member, form one surface of each pressure chamber

112

. The piezoelectric element

108

is connected to the drive circuit

200

, and the drive circuit

200

supplies a drive signal to separate electrode

109

as an external electrode of the piezoelectric element

108

. This embodiment does not divide the piezoelectric elements

108

for each pressure chamber

112

, and the oscillatory plate

104

and piezoelectric elements

108

extend over multiple pressure chambers

112

.

The oscillatory plate

104

preferably comprises an elastically deformable metal thin film that has a certain degree of rigidity, like a chromium and nickel film, and serves to transmit a deformation of the piezoelectric element

108

to the pressure chamber

112

. The thickness of the oscillatory plate

104

is about 2 μm, for example.

The piezoelectric element

108

in this embodiment has been grown as a single layer by sputtering, but may include a layered structure. Unlike this embodiment where the oscillatory plate

104

and piezoelectric elements

108

are laminated all over MgO substrate

122

as described later, the piezoelectric elements

108

may be formed only within a limited predetermined area. The piezoelectric element

108

as a single layer does not include an internal electrode, and is connected to a signal electrode as an external electrode. An internal electrode is provided in each layer, and connected to the foregoing external electrode in the stacked layers. The piezoelectric element

108

can employ any structure known in the art, and a detailed description thereof will be omitted. Each pressure chamber

112

includes a separate piezoelectric element

108

in this embodiment, but instead may be assigned, where one piezoelectric element

108

may be divided into a plurality of piezoelectric blocks by multiple grooves, each piezoelectric block.

The piezoelectric element

108

does not deform when no drive signal is transmitted to the external electrode and thus the electrical potential of the internal electrode is zero. When a drive signal is supplied to the external electrode, each piezoelectric element

108

is deformable in the direction D in

FIG. 4

independently of other piezoelectric elements

108

. In other words, the direction D is a polarization direction for the piezoelectric element. When the transmission of a drive signal is halted from the drive circuit

200

to the external electrode, i.e., by discharging the electric charge accumulated in the piezoelectric element

108

, the piezoelectric element restores its original state.

Next, a description will be given of the manufacturing method of the inkjet head

100

according to the present invention, with reference to

FIGS. 7

to

10

.

A patterning process using a dry film resist in this embodiment forms three layers separately, heats them at about 150 degrees, joins them together, and cures them (steps

1100

to

1400

).

FIG. 7

shows only two adjacent pressure chambers for illustration purposes. Each of the steps

1100

to

1300

may be accomplished prior or parallel to other steps.

More specifically, the nozzle plate

106

(layer (A)) including nozzles

120

is made, as shown in

FIGS. 7

(A) and

8

, from stainless metal (step

1100

). Each nozzle

120

is preferably processed into a cone shape (or taper shape in section) by a punch using a pin (not shown), which extends from front surface

106

a

on the nozzle plate

106

to its back surface

106

b

(which is joined to the pressure-chamber plate

102

). One of the reasons for joining the nozzle plate

106

to the pressure-chamber plate

102

rather than integrating the pressure-chamber plate

102

with the nozzle plate

106

is to obtain such a cone nozzle

120

.

Next, layer (B) is formed, as shown in FIG.

7

(B), by laminating a dry film resist onto the stainless plate

105

(step

1200

). More in detail, the step

1200

includes steps shown in FIG.

9

. First, as shown in FIG.

7

(B){circle around (1)}, the introduction path

116

and common ink chamber

110

are formed by etching the rigid stainless plate

105

(step

1202

). Apparatuses necessary for etching are known to those skilled in this art, and a detailed description and illustration thereof will be omitted. In this embodiment, the nozzle plate

106

forms the layer (A) while the stainless plate

105

the layer (B). If both plates are formed on the same layer, etching of the stainless plate

105

would disadvantageously result in also etching of the nozzle plate

106

. Thus, the above structure prevents such a disadvantage. However, it is noted that this embodiment does not argue that the inkjet head

100

of the present invention should be manufactured by joining these three layers, and those skilled in this art would understand that it is manufactured by an arbitrary number of layers. For example, joining two layers would make the inkjet head, as in inkjet head

100

B that will be described later with reference to FIG.

17

.

Then, as shown in FIG.

7

(B){circle around (2)}, the dry film resist

103

(which corresponds to the dry film resist

103

e

in

FIG. 3

) is laminated as a first layer onto the stainless plate

105

so that those parts corresponding to the pressure chamber

112

and common ink chamber

110

may be exposed by a masking process (step

1204

). Apparatuses necessary to laminate and expose a dry film resist are apparent to those skilled in the art, and a detailed description and illustration thereof will be omitted herewith. Desirably, a dry film resist, when used, is laminated on a rigid member (such as the stainless plate

105

, nozzle plate

106

, MgO substrate

122

, etc.) as a substrate, and then joined together. It is needless to say that a rigid member is not limited to the stainless plate or MgO substrate.

As shown in FIG.

7

(B){circle around (3)}, a dry film resist

103

is then laminated as a second layer (which corresponds to the dry film resist

103

d

in

FIG. 3

) onto the dry film resist

103

as the first layer so that those parts corresponding to the pressure chamber

112

, the ink supply channel

114

and the common ink chamber

110

may be exposed by a masking process (step

1206

).

As shown in FIG.

7

(B){circle around (4)}, a dry film resist

103

as an adhesive layer onto the rear surface of the stainless plate

105

so that those parts corresponding to the introduction path

116

and the common ink chamber

110

may be exposed by a masking process (step

1206

). This adhesive layer corresponds to the dry film resist

103

f

in FIG.

3

.

The development at both sides would complete the layer (B) as shown in FIG.

7

(B){circle around (5)}(step

1208

).

As shown in

FIG. 7

(C), layer (C) is formed by laminating a bimorph layered member and a dry film resist (step

1300

). The layer (C) includes as much as three dry film resist layers. To give the details, the step

1300

is composed of steps shown in FIG.

10

. First, as shown in FIG.

7

(C){circle around (1)}, create a layered member for the MgO substrate

122

, piezoelectric element

108

and oscillatory plate

104

(step

1302

). The MgO substrate

122

serves to assist in stably creating the dry film resist layers

103

a

to

103

d

which will be described later as well as stably creating bimorph layered members

104

and

108

.

More specifically, separate electrode

109

(signal electrode) is formed, as shown in

FIG. 2

, onto the MgO substrate

122

. The piezoelectric elements

108

as a single layer are then grown by using sputtering in a lattice direction on the MgO substrate

122

throughout one surface of the MgO substrate

122

. A chromium membrane is grown by using sputtering with an electric tube throughout one surface of the piezoelectric element

108

. FIG.

7

(C) illustrates the bimorph layered member as one layer composed of the piezoelectric element

108

and oscillatory plate

104

.

In an attempt to use a layered piezoelectric element

108

, the piezoelectric element

108

is formed by, for example, mixing each of multiple green sheets with a solvent such as ceramic powder, kneading them into a paste, and forming a thin film of an about 50 μm thickness using a doctor blade. A strong dielectric substance may be used such as Ba, TiO

3

, PbTiO

3

, (NaK)NbO

2

as generally-used materials for a piezoelectric element.

Among these green sheets, a first internal electrode pattern is formed and printed on one surface of each of three green sheets, while a second internal electrode pattern is formed and printed on one surface of each of other three green sheets. Nothing is printed on the remaining sheets. The first and second internal electrodes are printed and patterned by mixing powder of metal alloy of silver and palladium with a solvent into a paste, and applying the paste to the sheets.

The three sheets printed with the first electrode are alternately adhered to the three sheets printed with the second electrode, and then adhered to the remaining six sheets, whereby the layered piezoelectric element

108

is formed. Those lower green sheets that do not include any internal electrode become a fundamental part in the piezoelectric element

108

. These green sheets are sintered in a layered state.

As shown in FIG.

7

(C){circle around (2)}, a dry film resist

103

is laminated as a first layer (which corresponds to the dry film resist

103

a

in

FIG. 3

) onto the oscillatory plate

104

, whereby part corresponding to the pressure chamber

112

is exposed by the masking process (step

1304

).

As shown in FIG.

7

(C){circle around (3)}, a dry film resist

103

is laminated as a second layer (which corresponds to the dry film resist

103

b

in

FIG. 3

) onto the dry film resist laminate

103

a

as the first layer, whereby part corresponding to the pressure chamber

112

and common ink common

110

is exposed by the masking process (step

1306

).

As shown in FIG.

7

(C){circle around (4)}, a dry film resist

103

is then laminated as a third layer (which corresponds to the dry film resist

103

c

in

FIG. 3

) onto the dry film resist laminate

103

b

as the second layer, whereby part corresponding to the pressure chamber

112

, ink supply channel

114

and common ink chamber

110

is exposed by the masking process (step

1308

).

As shown in FIG.

7

(C){circle around (5)}, the above layers are developed (step

1310

), whereby the layered members which laminate the piezoelectric element

108

to the dry film resist

103

c

in

FIG. 3

onto the MgO substrate

122

are created.

Then, the stainless layer

105

a

whose part corresponding to the pressure chamber

112

has been removed beforehand by etching is characteristically joined, as shown FIG.

7

(C){circle around (6)}, onto the dry film resist layer

103

c

(step

1312

). And the MgO substrate

122

is removed. In this embodiment, the number of joint areas among the layers (A) through (C) is two (one between the layers (A) and (B), and one between the layers (B) and (C)), as shown in FIG.

7

. Thus, only two stainless layers

105

(namely,

105

a

and

105

b

) are provided. These layers (A) through (C) will be joined and cured later (step

1400

).

The stainless layer

105

a

serves to prevent the dry film resist layer

103

c

etc. to flow into the dry film resist layer

103

d

when the layer (C) is joined to the layer (B). The conventional photo-lithography manufacturing method using a dry film resist, has used no member corresponding to the stainless layer

105

a,

and been disadvantageous in that the dry film resist layer

103

c,

for example, readily flows into the ink supply channels

114

c

and

114

d

on the dry film resist layer

103

d,

deteriorating a patterning size precision.

This embodiment provides the stainless layer

105

a

(or an alternative rigid member such as metal or ceramic) between two dry film resist layers

103

c

and

103

d

to be joined, and advantageously forms multi-layer ink supply channels

114

with high precision. In other words, each ink supply channel

114

that remains stable before and after the joining process would provide high processing precision and facilitate a miniature inkjet head. Although the stainless layer

105

a

is joined onto the dry film resist layer

103

c

in this embodiment, the stainless layer

105

a

may be joined onto the dry film resist layer

103

d

in the layer (B) instead of or in addition to this.

In addition, this embodiment sets the (B) layer to be three layers (excluding the adhesive layer) and the layer (C) to be five layers in FIG.

7

(C){circle around (5)}, then laminating the stainless layer

105

a

on these layers. Nevertheless, the number of laminated layers of layers (B) and (C) may be changed to a desired number, and the thickness of each layer may be adjusted desirably. In other words, the stainless layer

105

a

may be located between the adjacent dry film resist layers at an arbitrary joint surface among the dry film resist layers

103

a

to

103

e.

The stainless layer

105

a

thus serves as a shielding member that shields both opposite ink supply channels (such as

114

a

and

114

c,

114

b

and

114

d

), and may use, in addition to metal or ceramic, a member made of resin (e.g., PEN) or composite resin (e.g., FRP). In particular, such a member has a thermal expansion coefficient similar to that of other dry film resist layers

103

, and it has an effect of reducing a thermal residual stress during a heat treatment, such as at the time of joining. The head components are so thermally homogeneous that each component exhibits little thermal expansion offset after undergoing the heat treatments at the time of adhering and joining in the head manufacturing process. Consequently, such a resin is effective in reducing the thermal residual stress.

FIGS. 11

to

13

show inkjet head

100

A that is an exemplified variation of the present invention. As best shown in

FIG. 13

, four ink supply channels

114

A align with the direction D one by one. It is understood that the inkjet head

100

A has only one ink supply channel

114

A in the direction C, and would realize the higher resolution than the inkjet head

100

. These four ink supply channels

114

A shown in

FIG. 13

need not align with a straight line, as is the case with FIG.

5

.

FIGS. 14

to

16

show inkjet head

100

B that is another exemplified variation of the present invention. As best shown in

FIG. 15

, the common ink chamber

110

B has a shape of the common ink chamber

110

shown in

FIG. 3

plus sidelong groove

115

extending towards the pressure chamber

112

in the inkjet head

100

B.

Two ink supply channels

114

B are arranged parallel to the direction D in the longitudinal direction of the pressure chamber (that is, direction E). The inkjet head

100

B has only one ink supply channel

114

B in the direction in which the pressure chambers

112

are arranged (i.e., the direction C), and may realize the higher resolution than the inkjet head

100

. These two ink supply channels

114

B shown in

FIG. 15

need not align with a straight line, as is the case with FIG.

5

.

FIG. 15

simplifies the size of each ink supply channel

114

B for illustration purposes, and emphasizes only its location.

With reference to

FIGS. 17 through 20

, a description will now be given of the manufacturing method of the inkjet head

100

B of the present invention.

A patterning process using a dry film resist in this embodiment forms two layers separately, heats them at about 150 degrees, joins them together, and cures them (steps

2100

to

2300

).

FIG. 17

shows only two adjacent pressure chambers for illustration purposes. Either steps

2100

or

2300

may be accomplished prior or parallel to the other steps.

More specifically, layer (A) is formed by laminating a dry film resist onto the nozzle plate

106

including the nozzles

120

, as shown in FIGS.

17

(A) and

18

(step

2100

). More specifically, the step

2100

includes the steps shown in FIG.

19

. At first, as shown in FIG.

17

(A){circle around (1)}, the nozzle plate is formed in the same way as the step

1100

in

FIG. 8

(step

2102

).

Next, as shown in

FIG. 17

(A){circle around (2)}, a dry film resist

103

(which corresponds to the dry film resist

103

j

in

FIG. 15

) is laminated onto the nozzle plate

106

, whereby part corresponding to the introduction path

116

, a fundamental part of the common ink chamber

110

B, and the sidelong groove

115

is exposed by the masking process (step

2104

).

Then, as shown in FIG.

17

(A){circle around (3)}, the dry film resist

103

is developed, whereby the layer (A) is completed as shown in FIG.

17

(A){circle around (3)}(step

2106

). Thus, this embodiment laminates the dry film resist

103

onto the nozzle plate

106

.

On the other hand, as shown in FIG.

17

(B), the layer (B) is formed by laminating a bimorph layered member and dry film resists (step

2200

). The layer (B) includes as much as four dry film resist layers. More specifically, step

2200

includes the steps shown in FIG.

20

. First, as shown in FIG.

17

(B){circle around (1)}, a layered member is formed including the MgO substrate

122

, piezoelectric element

108

and oscillatory plate

104

in the same way as the steps shown in

FIG. 20

(step

2202

).

FIG. 17B

shows as one layer a bimorph layered member including the piezoelectric element

108

and the oscillatory plate

104

.

Next, as shown in FIG.

17

(B){circle around (2)}, a dry film resist

103

is laminated as a first layer (which corresponds to the dry film resist

103

f

in

FIG. 15

) onto the oscillatory plate

104

, and part corresponding to the pressure chamber

112

is exposed by the masking process (step

2204

).

Subsequently, as shown in FIG.

17

(B){circle around (3)}, dry film resists

103

are laminated as second to fourth layers (which correspond to the dry film resists

103

g

to

103

i

in

FIG. 15

) onto the dry film resist laminate

103

as the first layer, and part corresponding to the pressure chamber

112

and common ink common

110

is exposed by the masking process (step

2206

).

The member is developed as shown in FIG.

17

(B){circle around (4)}(step

2208

), and the layered member which laminates the piezoelectric element

108

through the dry film resist

103

i

in

FIG. 15

onto the MgO substrate

122

is formed.

Characteristically, the stainless layer

105

c

in which part corresponding to the introduction path

116

and ink supply channel

114

B has been removed beforehand by etching is then joined, as shown FIG.

17

(B){circle around (5)}, onto the dry film resist layer

103

i

(step

2210

). The MgO substrate

122

is then removed. There is only one joint surface between the layers (A) and (B) in this embodiment as shown in

FIG. 17

, and thus only one stainless layer

105

is located. However, if the manufacturing process needs increase rigidity, any number of stainless layers may be added. These layers (A) and (B) will be joined later and cured (step

2300

).

The reason why the stainless layer

105

c

is located on the dry film resist layer

103

i

is that the layer including ink supply channels

114

B overhangs on the sidelong groove

115

from the position where the ink supply channels

114

B are provided, and thus, if this part does not have rigidity of a certain degree, it would infiltrate into the sidelong groove

115

.

The present invention may arbitrarily combine the foregoing arrangements of the ink supply channels

114

. For example, two out of four ink supply channels could be arranged in the direction D as shown in

FIG. 13

, whereas the remaining two in the direction E as shown

FIGS. 15 and 16

.

The inkjet head

100

of the present invention layers in the direction D and experiences the exposure and development, etc., and the ink supply channels

114

are formed parallel or perpendicular to the direction D. Nevertheless, it is apparently understood that those ink supply channels

114

inclined at a predetermined angle with respect to the direction D fall within the scope of the present invention. The ink supply channel

114

may take an arbitrary sectional shape in addition to the rectangular shape. Its cross-sectional area needs not be fixed, e.g., and it may have a gradually expanding cross-section. It is apparently understood that the ink supply channel

114

can be applied for connection with the piezoelectric element

112

and the common ink chamber

110

that have an arbitrary shape in addition to a cuboid shape.

Further, the present invention is not limited to these preferred embodiment, but various variations and modifications may be made without departing from the scope of the present invention.

As described, according to the inventive inkjet head and the inventive inkjet printer having the inkjet head, all the ink supply channels do align with a direction in which the piezoelectric elements are arranged. Thereby, the head is miniaturized by reducing a nozzle pitch in the direction in which the piezoelectric elements are arranged. The inkjet head of the present invention becomes smaller than the conventional one, exhibiting higher degree of integration and resolution.

Increasing of the number of ink supply channels using the equivalence of ink hydraulic resistance provides a wall defining the ink supply channel with a desired length, desired strength and adhesiveness.

Further, the present invention may provide a rigid member made of such metal or ceramic as has a high Young's modulus between adjacent layers which form the ink supply channels, so as to stably maintain the opposite ink supply channels, when these layers are joined to be an inkjet head. Such a member particularly enables a plurality of layers of ink supply channels to be manufactured with high precision in the manufacturing method of an inkjet head using a dry film resist. A resin or composite resin member, if provided in place of metal, has a thermal expansion coefficient close to that of a dry film resist and thus would reduce a thermal expansion offset result in each layer even when the manufacturing process includes a heat treatment. As a result, a member made of resin etc. would bring about an effect of reducing a thermal residual stress.

Number	Name	Date	Kind
5896149	Kitahara et al.	Apr 1999	A
5940099	Karlinski	Aug 1999	A

Number	Date	Country
07156382	Jun 1995	JP
09295403	Nov 1997	JP

Inkjet head having plural ink supply channels between ink chambers and each pressure chamber

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (1)

US Referenced Citations (2)

Foreign Referenced Citations (2)