Liquid discharge head and apparatus having restricted movement of a movable member

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a liquid discharge head and a liquid discharge apparatus that discharge a desired liquid by generation of a bubble due to thermal energy or the like, and more particularly, to a liquid discharge head and a liquid discharge apparatus having a movable member which is displaced by the use of generation of the bubble.

The term “recording” in the present invention means to attach not only an image such as a character and a figure having a meaning but also an image such as a pattern to a recording medium.

2. Description of the Related Art

Conventionally, in a recording apparatus such as a printer, an ink-jet recording method, a so-called bubble-jet recording method, has been known, in which energy such as heat is given to a liquid ink in a flow path to generate a bubble, ink is discharged from discharge part by an effort based on a steep volume change with the generation of the bubble, and the ink is adhered to the recording medium to form an image. In the recording apparatus using the bubble-jet recording method, a discharge part for discharging ink, a flow path communicating with the discharge part, and an electro-thermal converter as energy generation means for discharging ink provided in the flow path are generally provided, as disclosed in the U.S. Pat. No. 4,723,129.

According to such a recording method, a high-resolution image can be recorded in a high-speed and with a low noise, and the discharge part for discharging ink can be arranged in a high density in a head performing the recording method. Therefore, the recording method has many superior aspects that a recorded image or a color image of a high-resolution can be easily obtained by a small apparatus. Thus, the bubble-jet recording method has been used in various office appliances such as a printer, a copier and a facsimile, and furthermore, it has also been used in an industrial system such as a textile printing apparatus.

As bubble-jet technology has been used in products of various directions, the followings have been requested in recent years.

To obtain a high image quality, drive conditions are suggested by which a liquid discharge method and the like having a high discharge speed of ink and capable of performing good ink discharge based on stable bubble generation has been provided. In addition, from the viewpoint of high-speed recording, a recording method has been suggested in which the shape of the flow path is improved to obtain a liquid discharge head having a high filling (refilling) speed of a discharged liquid into the liquid flow path.

Other than the head described above, an invention having a construction to prevent a back wave being loss energy during discharge is disclosed in Japanese Patent Application Laid-Open No 6-31918, which pays attention to the back wave (a pressure directed to a direction opposite to the direction toward the discharge part) generated with generation of the bubble. The invention described in the gazette is one that a triangular portion of a triangular plate member is arranged opposing to a heater that generates the bubble. In the invention, the back wave is temporarily controlled by a little amount by the plate member. However, since the invention does not mention a relative relation between the growth of the bubble and the triangular portion nor has such conception, the invention has the following problem.

Specifically, in the invention described in the gazette, an ink droplet shape cannot be stable because the heater is positioned at the bottom of a concave portion and cannot have a communication state in-line with the discharge part. Moreover, since the growth of the bubble is permitted from the periphery of the apex portion of a triangle, the bubble grows from one side of the triangular plate member entirely to the opposite side. Accordingly, normal growth of the bubble in the liquid completes as if the plate member does not exist. Therefore, existence of the plate member is not effective to the bubble that has grown. On the contrary, refill to the heater being positioned at the concave portion causes a turbulent flow in a contraction step of the bubble because the entire plate member is surrounded by the bubble, which causes micro bubbles to accumulate in the concave portion and breaks the principle where discharge is performed based on a growing bubble.

Moreover, the European Patent Publication No. 436047A1 suggests an invention that alternately opens/closes a first valve and a second valve, the first valve blocking the vicinity of the discharge part and a bubble generation section between them and the second valve completely blocking the bubble generation section and an ink supply section between them (refer to

FIG. 4

to

FIG. 9

of the gazette). However, in the invention, the three chambers are severally divided in two divisions, ink following the liquid droplet tails long during discharge, and thus considerably more satellite dots are produced compared to a normal discharge method where bubble growth, contraction, and bubble disappearance are performed (thus, it is presumed that effect of meniscus withdrawal due to the bubble disappearance cannot be used). Further, although the liquid is supplied to the bubble generation section with the bubble disappearance during refilling, the liquid cannot be supplied to the vicinity of the discharge part until the next bubble growth begins. Accordingly, not only dispersion of the discharged liquid droplets is large, but also discharge response frequency is extremely small, which are not in practical levels.

On the other hand, a number of inventions using a movable member (a plate member or the like having a free end closer to the discharge part side from a fulcrum) that effectively contributes to liquid droplet discharge are suggested by the inventors, which are totally different from the prior art. Among others, Japanese Patent Application Laid-Open 9-48127 discloses an invention that defines an upper limit of a displacement of the movable member in order to prevent the action of the foregoing movable member from being troubled. In addition, Japanese Patent Laid-Open No. 9-323420 discloses an invention in which the position of a common liquid chamber in an upstream to the above-described movable member is shifted closer to the free end side of the movable member, that is, to a downstream side utilizing the advantage of the movable member. As a presumption for creating the inventions, the inventors adopted a mode that the growth of the bubble is suddenly released to the discharge part side from a state of temporarily wrapping the bubble by the movable member. Accordingly, no attention is paid to individual element of the whole bubble regarding the formation of the liquid droplet and the relative relation thereof.

As the next step, the inventors disclose an invention in Japanese Patent Application Laid-Open 10-24588 that a portion of a bubble generation region is released from the above-described movable member, which is an invention (an acoustic wave) where its attention is paid to the bubble growth by pressure wave propagation as an element regarding the liquid discharge. However, since the invention also pays attention only to the growth of the bubble during the liquid discharge, no attention is paid to individual element of the whole bubble regarding the formation of the liquid droplet and the relative relation thereof.

Despite that the front portion (an edge shooter type) of a bubble by a film boiling, which has been conventionally known, greatly influences the discharge, no invention has paid attention to this conventionally for contributing to the formation of the discharged liquid droplet more effectively. The inventors have researched this with much effort for technical resolution.

Furthermore, the inventors have obtained the following effective finding when they paid attention to the displacement of the movable member and the generated bubble.

The finding is that the displacement of the free end of the movable member to the growth of the bubble is defined (restricted) by a restricting portion (a stopper). By restricting the displacement of the movable member by the restricting portion, the growth of the bubble in the upstream of the flow path is defined, and thus energy propagates for effectively discharging the liquid toward the downstream side where the discharge part is formed.

In the liquid discharge head having the foregoing constitution, there has been a case where dissolved gas in the liquid becomes a remained bubble due to change by passage of time, temperature increase by continuous bubble growth, and the like. Specifically, the bubble generated in the flow path due to change by passage of time, temperature increase by continuous bubble growth, and the like tends to be left in the front and rear of the restricting portion. Particularly, there is a portion where the liquid is hard to flow and stagnate in the vicinity of the restricting portion, and there has been a case when the bubble is left fixedly in the portion. In the following description, such a bubble is referred to as the remained bubble, which is distinguished from the bubble for liquid discharge that is grown by heat and disappeared. If the remained bubble is left fixedly in the front and rear of the restricting portion, deterioration of printing may have been caused because a bubble foaming power was absorbed by the remained bubble to reduce a discharge amount and a discharge speed or a discharge direction became unstable.

Specifically, as shown in

FIG. 17A

, if a remained bubble

450

exists in the vicinity of a restricting portion

412

, the liquid discharge operation shown in FIG.

17

B and

FIG. 17C

, and then the remained bubble

450

does not move and becomes residual even if the refill (refilling of the liquid) is performed as shown in FIG.

17

D. This is because the flow of the liquid progresses so as to avoid the vicinity of the restricting portion

412

, little flow of the liquid is made in the vicinity of the restricting portion

412

, and the remained bubble

450

is also left in the portion without being washed down. As described, when the remained bubble

450

is left in the position, a bubble foaming pressure during bubble generation by heating of a heat generator

410

as shown in

FIG. 17E

to

FIG. 17G

is absorbed by the remained bubble residual in the portion, which leads to insufficient liquid discharge.

SUMMARY OF THE INVENTION

The object of the present invention is to prevent the remained bubble from being left in the vicinity of the restricting portion and also to prevent reduction of the liquid discharge performance due to a residual remained bubble.

The present invention is a liquid discharge head that comprises: a heat generator that generates a thermal energy for generating a bubble in a liquid; an discharge part as portions to discharge the liquid; a flow path communicating with the discharge part and having a bubble generation region in which the bubble is generated; a movable member having a free end and is displaced with the growth of the bubble; and a restricting portion to define (restrict) a displacement amount of the movable member, in which the flow path is formed by joining a substantially flat substrate provided with the heat generator and the movable member and a top plate opposing to the substrate and including the restricting portion, and the liquid is discharged from the discharge part by an energy during generation of the bubble, characterized in that the clearance between at least one sidewall of the flow path and the side edge portion of the restricting portion is larger than the clearance between the sidewall and the side edge portion of the movable member.

According to the above constitution, since the liquid can flow through the clearance between the sidewall and the side edge portion of the restricting portion, the foregoing flow of the liquid generated during refilling of the liquid and the like washes down the remained bubble and discharges it from the discharge part even if the remained bubble exists in the vicinity of the restricting portion.

It is preferable that the clearance between the movable member and the restricting portion along the height direction of the flow path, in a non-displacement state of the movable member, is larger than the clearance between the sidewall of the flow path and the side edge portion of the movable member and is smaller than the clearance between the sidewall and the side edge portion of the restricting portion.

Moreover, it is preferable that the sum of the clearance between the movable member and the restricting portion along the height direction of the flow path and the clearance between the movable member and the bottom surface of the flow path, in the non-displacement state of the movable member, is smaller than the clearance between the sidewall and the side edge portion of the restricting portion.

It is also preferable that the distance between the restricting portion and the bottom surface of the flow path in the height direction of the flow path is 15 μm or more, the clearance between the sidewall and the side edge portion of the restricitng portion is 4 μm or more, and the width of the restricting portion is 90% or less of the width of the flow path.

Further, it is preferable that both side edge portions of the restricting portion is convex toward the sidewall and have a shape in which the width continuously becomes narrower from the maximum width portion to the upstream direction and the downstream direction. In this case, the remained bubble moves smoothly along the side edge portion of the restricting portion.

The present invention is also characterized in that the restricting portion is severally formed on the both sidewalls of the flow path, which has a convex shape toward the inside of the flow path, and the clearance between the both restricting portions is larger than the clearance between the sidewall and the side edge portion of the movable member. In such a case, it is preferable that the sidewall has a shape in which the width continuously becomes narrower from the maximum width portion to the upstream direction and the downstream direction.

The liquid discharge apparatus of the present invention includes the liquid discharge head of any one of the foregoing constitutions, and discharges the remained bubble of the dissolved gas in the liquid, which is left in the flow path due to bubble foaming and change by passage of time, during discharge or refilling of the liquid from the discharge part together with the liquid through the clearance between the side edge portion of the restricting portion and the inner wall of the flow path or the clearance between the two restricting portions.

Moreover, the liquid discharge apparatus includes recovery means for recovering the state of the liquid discharge head, and the remained bubble is discharged by the recovery means.

It is to be noted that the terms “upstream” and “downstream” used in the description of the present invention are expressed as an expression regarding the flow direction of the liquid that directs from a supply source of the liquid toward the discharge part via the bubble generation region (or the movable member), or regarding a constitutional direction.

In addition, the “downstream side” regarding the bubble itself means the bubble generated in the downstream side relative to the center of the bubble regarding the direction of the flow or the constitutional direction, or the bubble generated in a region downstream side of the area center of the heat generator. In the same manner, the “upstream side” regarding the bubble itself means the bubble generated in the upstream side relative to the center of the bubble regarding the direction of the flow or the constitutional direction, or the bubble generated in a region upstream side of the area center of the heat generator.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a typical side sectional view of a liquid discharge head of a first embodiment of the present invention.

FIGS. 2A

,

2

B,

2

C,

2

D and

2

E are views explaining discharge process of the liquid from the liquid discharge head shown in FIG.

1

.

FIGS. 3A

,

3

B and

3

C are views explaining a state where liquid flows between a movable member and a restricting portion.

FIG. 4

is an enlarged sectional view of a principal portion of the liquid discharge head shown in

FIG. 1

in a direction perpendicular to a flow path.

FIG. 5

is a graph showing a temporal change of a displacement speed and a volume of a bubble and a displacement speed and a displacement volume of the movable member.

FIGS. 6A

,

6

B,

6

C,

6

D,

6

E,

6

F and

6

G are views explaining discharge process of a remained bubble in the liquid discharge head shown in FIG.

1

.

FIGS. 7A

,

7

B,

7

C,

7

D,

7

E,

7

F and

7

G are other views explaining discharge process of a remained bubble in the liquid discharge head shown in FIG.

1

.

FIG. 8

is a perspective view of a principal portion of the liquid discharge head shown in FIG.

1

.

FIG. 9

is a sectional plan view of the principal portion of the liquid discharge head shown of a second embodiment of the present invention.

FIG. 10

is a sectional plan view of the principal portion of the liquid discharge head shown of a third embodiment of the present invention.

FIG. 11

is a sectional plan view of the principal portion of the liquid discharge head shown of a fourth embodiment of the present invention.

FIG. 12

is a graph showing a relation between a heat generator area and an ink discharge amount.

FIGS. 13A and 13B

are typical sectional side views explaining a constitution of an element substrate of the liquid discharge head of the present invention.

FIG. 14

is a graph showing a pulse waveform applied to the heat generator.

FIG. 15

is a typical perspective view showing an example of a recording apparatus of the present invention.

FIG. 16

is a block diagram of an entire recording apparatus for performing an ink-jet recording by the liquid discharge head of the present invention.

FIGS. 17A

,

17

B,

17

C,

17

D,

17

E,

17

F and

17

G are views explaining discharge process of the liquid from a conventional liquid discharge head.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be described with reference to accompanying drawings as follows.

First Embodiment

FIG. 1

is a typical side sectional view of a liquid discharge head of this embodiment. And,

FIGS. 2A

to

2

E are views explaining discharge process of the liquid from the liquid discharge head shown in FIG.

1

.

The constitution of the liquid discharge head will be described by using FIG.

1

.

The liquid discharge head comprises: an element substrate having a heat generator

10

as bubble generation means and a movable member

11

; a top plate

2

where a stopper (a restricting portion)

12

is formed; and an orifice plate

5

where discharge part

4

is formed.

A flow path

3

where the liquid flows is formed by making the element substrate

1

and the top plate

2

fixed with each other in a laminated state. The flow path

3

is formed parallelly in the liquid discharge head in plural numbers to be communicated with the discharge part

4

discharging the liquid, which is formed in the downstream side (the left side in FIG.

1

). A bubble generation region exists in a region close to a plane that contacts the heat generator

10

and the liquid. Moreover, a common liquid chamber

6

having a large volume is provided so as to communicate simultaneously with the upstream side (the right side of

FIG. 1

) of each flow path

3

. Specifically, each flow path

3

has a shape diverged from the single common liquid chamber

6

. The liquid chamber height of the common liquid chamber

6

is formed higher than that of the liquid path

3

.

The movable member

11

is a cantilever state with one end being supported, fixed to the element substrate in the upstream of an ink flow, and the downstream portion from a fulcrum

11

a

is movable in a vertical direction to the element substrate

1

. In an initial state, the movable member

11

is positioned approximately parallel to the element substrate

1

while keeping a gap between the element substrate

1

.

The movable member

11

disposed on the element substrate

1

is disposed such that a free end

11

b

is positioned in a substantially central region of the heat generator

10

. The stopper

12

provided on the top plate

2

defines the displacement amount of the free end

11

b

in an upward direction by allowing the free end

11

b

of the movable member

11

to contact the stopper

12

. During a displacement amount restricting time (a movable member contacting time) of the movable member

11

, the upstream side from the movable member

11

and the stopper

12

and the downstream side from the movable member

11

and the stopper

12

are substantially blocked in the flow path

3

.

It is preferable that a position Y of the free end

11

b

and an end X of the stopper

12

are positioned perpendicular to the element substrate

1

. More preferably, the X and Y, together with a Z being the center of the heat generator

10

, are positioned on a plane perpendicular to the substrate.

Further, the height of the flow path

3

in the downstream side from the stopper

12

is suddenly increased. With this constitution, a bubble

40

in the downstream side of the bubble generation region has a sufficient flow height even when the movable member

11

is defined by the stopper

12

. Accordingly, the growth of the bubble

40

is not blocked, and the liquid can be directed smoothly to the discharge part

4

. Moreover, uneven pressure balance in a height direction from the bottom end to the top end of the discharge part

4

is reduced. Thus, good liquid discharge can be performed.

The ceiling shape in the common liquid chamber

6

side (upstream side) from the stopper

12

is designed to be steeply risen. In the case where the movable member

11

did not exist in this constitution, the pressure has not been easily directed to the discharge part

4

because the fluid resistance in the downstream side of the bubble generation region was larger than that in the upstream side. However, in this embodiment, the movement of the bubble

40

to the upstream side of the bubble generation region is substantially blocked during bubble formation due to the movable member

11

. Accordingly, the pressure used for discharge is positively directed to the discharge part

4

, and ink is quickly supplied to the bubble generation region because the fluid resistance in the upstream side of the bubble generation region is small during ink supply.

According to the foregoing constitution, the growth component to the downstream side and the upstream side of the bubble

40

are not equal, but the growth component to the upstream side is reduced to suppress the movement of the liquid to the upstream side. Since the liquid flow to the upstream side is suppressed, the withdrawal amount of the meniscus after discharge is reduced, and the amount of the meniscus protruded from an orifice plane

5

a

during refilling is also reduced accordingly. Therefore, a meniscus vibration is suppressed, and stable discharge is performed in all drive frequencies from a low frequency to a high frequency.

It is to be noted that, in this embodiment, the space between the downstream portion of the bubble

40

and the discharge part

4

is in an “in-line communication state” in which a flow path structure is in-line with the liquid flow. More preferably, it is desirable that an ideal state is formed where an discharge state of an discharged droplet

66

(described later) such as the discharge direction and the discharge speed is stabilized in a high-level by making the propagation direction of the pressure wave occurred during the generation of the bubble

40

and the flow direction and the discharge direction of the liquid with the pressure wave aligned. In this embodiment, as a definition to achieve or approach the ideal state, the discharge part

4

and the heat generator

10

, particularly, a portion of the heat generator

10

closer to the discharge part

4

(downstream side), which influences a portion of the bubble

40

closer to the discharge part

4

, may be directly connected in-line. This is the state where the downstream side of the heat generator

10

can be observed when viewed from outside of the discharge part

4

in the state where the liquid is not filled in the flow path

3

.

Next, description will be made regarding the dimensions of each constituent element.

In the present invention, diversion of the bubble

40

to the upper surface of the movable member

11

(diversion of the bubble

40

to the upstream side of the bubble generation region) has been examined. And the inventors have found out that the diversion of the bubble

40

to the upper surface of the movable member

11

is eliminated by the relation between the moving speed of the movable member

11

and a bubble growing speed (in other words, the moving speed of the liquid), and thus a good discharge characteristic can be obtained.

Specifically, the present invention eliminates the diversion of the bubble

40

to the upper surface of the movable member

11

to obtain the good. discharge characteristic by restricting the displacement of the movable member

11

with the restricting portion

12

at the time when both the volume changing rate of the bubble

40

and the displacement volume changing rate of the movable member

11

are in an increasing tendency.

This will be described in detail by using

FIG. 3

as follows.

Firstly, in the state of

FIG. 3A

, the pressure wave is generated instantaneously when a bubble

840

is generated on a heat generator

810

, and the pressure wave moves the liquid around the heat generator

810

to grow the bubble

840

. Then, a movable member

811

is initially displaced upward so as to follow the movement of the liquid (FIG.

3

B). When time passes, the displacement speed of the movable member

811

is suddenly reduced because the inertial force of the liquid becomes small and due to the elasticity of the movable member

811

. At this point, since the moving speed of the liquid is not reduced so much, the difference between the moving speed of the liquid and that of the movable member

811

becomes larger. Then, in the case where the gap between the movable member

811

(a free end

811

b

) and a stopper

812

is still wide as shown in

FIG. 3C

, the liquid flows into the upstream side (an arrow direction) of the bubble generation region through the gap, which makes the state where the movable member

811

is hard to contact the stopper

812

and a part of discharge force is lost. Therefore, in such a case, a restricting (blocking) effect of the movable member

811

by the restricting portion (the stopper

812

) cannot be exerted.

On the other hand, in the present invention, restricting of the movable member

11

by the restricting portion

12

is performed at the stage where the displacement of the movable member

11

substantially follows the movement of the liquid. Herein, in the present invention, the displacement speed of the movable member

11

and the growing speed (the moving speed of the liquid) are respectively expressed as a “changing rate of the displacement volume of the movable member” and a “changing rate of the bubble volume” for convenience. It is to be noted that the “changing rate of the displacement volume of the movable member” and “changing rate of the bubble volume” are ones that the displacement volume of the movable member and the bubble volume are differentiated.

With such a constitution, the liquid flow causing the diversion of the bubble

40

to the upper surface of the movable member

11

is substantially eliminated and a closed state of the bubble generation region can be more ensured. Thus, the good discharge characteristic can be obtained.

Furthermore, according to this constitution, the bubble

40

keeps on growing even after the movable member

11

is defined by the stopper. At this point, it is desirable that the flow path height of the flow path

3

in the downstream portion from the stopper

12

is sufficiently provided so as to promote free growth of the downstream side component of the bubble

40

.

In the present invention, restricting the displacement of the movable member by the restricting portion refers to the state where the changing rate of the displacement volume of the movable member is 0 or negative.

As shown in

FIG. 4

, The clearance “a” between a sidewall

20

and the side edge portion of the stopper

12

is larger than the clearance “b” between the sidewall

20

of the flow path

3

and the side edge portion of the movable portion

11

. Specifically, the clearance “a” is 10 μm and the clearance “b” is 3 μm in this embodiment. Moreover, the clearance “c” between the movable member

11

and the stopper along the height direction of the flow path

3

in the non-displacement state of the movable member

11

(the state where the bubble

40

is not generated) is 5 μm. The relation of a>c>b is established. In addition, the clearance “d” between the movable member

11

and the bottom surface of the flow path

3

(the upper surface of the element substrate) along the height direction of the flow path

3

in the non-displacement state of the movable member

11

is 4.5 μm, and the sum (c+d) of the clearance “d” and the foregoing clearance “c” is 9.5 μm which is smaller than the foregoing clearance “a”. In the drawing, reference symbol H

1

denotes a flow path height; H

2

, a protrusion height of the stopper; and H

3

, a stopper height.

It is to be noted that, in this embodiment, the height and the width of the flow path

3

are 55 μm and 25 μm respectively, the thickness and the width of the movable member

11

is 5 μm and 19 μm respectively, and the protrusion height (the height from the flow path ceiling plane of the top plate

2

to the tip portion of the stopper

12

) and the width of the stopper

12

are 30.5 μm and 5 μm respectively. When the height of the stopper is t

1

and the gap between the upper surface of the movable member

11

and the stopper

12

in a height direction is t

2

(=c), stable discharge characteristic of the liquid could be exerted by setting t

2

to 15 μm or less when t

2

is 30 μm or more. This embodiment sufficiently satisfies the condition because t

2

=30.5 μm and t

2

=c=5 μm. It is to be noted that, in each drawing other than

FIG. 4

, each dimension does not include an error for easy reading and is not shown accurately.

Next, the discharge operation of the liquid discharge head of this embodiment will be described in detail by using

FIG. 2A

to FIG.

2

E and

FIG. 5

showing the displacement speed and the temporal change of the volume of the bubble and the displacement speed and the displacement volume of the movable member.

In

FIG. 5

, the changing rate of the bubble volume v

1

, the bubble volume V

d1

, the changing rate of the displacement volume of the movable member v

2

and the displacement volume of the movable member V

d2

are respectively shown in a solid line, a two-dot chain line, a broken line and a one-dot chain line. In addition, the changing rate of the bubble volume v

1

, the bubble volume V

d1

, the changing rate of the displacement volume of the movable member v

2

and the displacement volume of the movable member V

d2

show the rise of the bubble volume V

d1

, the volume, the displacement volume of the movable member V

d2

and the volume respectively as a positive. Since the displacement volume of the movable member V

d2

shows the rise of the volume when the movable member

11

is displaced from the initial state of

FIG. 2A

to the top plate

2

as the positive, the displacement volume of the movable member V

d2

shows a negative value when the movable member

11

is displaced from the initial state to the element substrate

1

side.

FIG. 2A

is a state before the energy such as an electric energy is applied to the heat generator

10

, which shows a state before the heat generator

10

generates heat. The movable member

11

, as described later, is positioned relative to the bubble generated by the heat from the heat generator in a region opposing to a half portion of the bubble

40

of the upstream side.

This state is equivalent to an A point of time=0 in FIG.

5

.

FIG. 2B

shows the state where a part of the liquid that fills the bubble generation region is heated by the heat generator

10

and the bubble

40

has started foaming with the film boiling. This state is equivalent to a period from a B point to immediately before a C

1

point in

FIG. 5

, which shows a state that the bubble volume V

d1

is increased as time passes. It is to be noted that, at this point, the displacement of the movable member

11

begins later than the volume change of the bubble

40

. Specifically, the pressure wave based on generation of the bubble

40

due to the film boiling propagates in the flow path

3

, and the liquid moves to the downstream side and the upstream side by making the central region of the bubble generation region a border, accordingly. In the upstream side, the movable member

11

begins to be displaced by the liquid flow with the growth of the bubble

40

. And, the liquid movement to the upstream side is directed to the common liquid chamber

6

through the gap between the sidewall

20

of the flow path

3

and the movable member

11

. The clearance between the stopper

12

and the movable member

11

at this point is reduced as the movable member

11

is displaced. The discharged droplet

66

begins to be discharged from the discharge part

4

in this state.

FIG. 2C

shows a state where the free end

11

b

of the movable member

11

contacts the stopper

12

because of further growth of the bubble

40

. This state is equivalent to a period from a C

1

point to C

3

point.

The changing rate of the displacement volume of the movable member v

2

is quickly reduced in a period from the state shown in

FIG. 2B

to the point before the state shown in

FIG. 2C

where the movable member

11

contacts the stopper

12

, that is, at the B point in transition from the B point to the C

1

point in FIG.

5

. The reduction is caused because the flow resistance of the liquid between the movable member

11

and the stopper

12

is quickly increased immediately before the movable member

11

contacts the stopper

2

. The changing rate of the bubble volume v

1

is also reduced quickly.

Then, the movable member

11

further approaches to contact the stopper

12

. The contact between the movable member

11

and the stopper

12

is more ensured by making the dimensions of the protrusion height t

1

of the stopper

12

and the clearance t

2

(=c) between the upper surface of the movable member

11

and the tip portion of the stopper

12

are defined as described above. And then, when the movable member

11

contacts the stopper

12

, the displacement upward from the contact point is defined (C

1

to C

3

point in FIG.

5

). Accordingly, the liquid movement to the upstream direction is largely limited. In accordance with this, the growth of the bubble

40

to the upstream side is limited by the movable member

11

. However, since movement force of the liquid to the upstream direction is large, the movable member

11

receives a large amount of stress that pulls the movable member

11

to the upstream direction, which causes a little deformation upward in a convex state. At this point, although the bubble keeps on growing, the downstream side of the bubble

40

further grows because the growth to the upstream side is defined by the stopper

12

and the movable member

11

, and the growth height of the bubble

40

in the downstream side of the heat generator

10

is higher in comparison with the case where the movable member

11

is not provided. Specifically, as shown in

FIG. 5

, the changing rate of the displacement volume of the movable member v

2

is zero in the period between the C

1

and the C

3

point because the movable member

11

contacts the stopper, and the bubble

40

keeps on growing to the downstream side until the C

2

point that is a little temporally later than the C

1

point and the bubble volume V

d1

is the maximum value at the C

2

point.

On the other hand, a portion of the bubble

40

in the upstream side is in a small size in the state where the inertial force of the liquid flow to the upstream side bends the movable member

11

in the convex shape toward the upstream side to charge the stress because the displacement of the movable member

11

is defined by the stopper

12

. In a portion of the bubble

40

in the upstream side, the amount of the bubble that goes into the upstream side region is defined to almost as zero by the stopper

12

, the sidewall of the flow path, the movable member

11

and the fulcrum

11

a.

The liquid flow to the upstream side is largely defined with this to prevent a fluid cross talk to an adjacent flow path and backflow and pressure vibration, which blocks the high-speed refill, in a supply path system.

FIG. 2D

shows the state where the negative pressure inside the bubble

40

, after the foregoing film boiling, has overcome the liquid movement in the flow path

3

to the downstream side to begin the contraction of the bubble

40

.

The movable member

11

is displaced downwardly (the C

3

point to a D point in

FIG. 5

) in accordance with the contraction of the bubble

40

(the C

2

point to an E point in FIG.

5

). The movable member

11

has the stress of a cantilever spring and the stress of the upward convex deformation as described above, by which the downward displacement speed is increased. Then, since the flow of the liquid to the downstream direction in the upstream side of the movable member

11

, which is a low flow path resistance region formed between the common liquid chamber

6

and the flow path

3

, quickly becomes a large flow due to a small flow path resistance to flow into the flow path

3

via the stopper

12

. With these operations, the liquid in the common liquid chamber

6

side is guided into the flow path

3

. The liquid guided into the flow path

3

directly goes between the stopper

12

and the movable member

11

that has been displaced downwardly, flows to the downstream side of the heat generator

10

, and simultaneously functions so as to promote disappearance the bubble

40

that has not completely disappeared yet. The liquid flow, after having helped disappearance, further forms a flow in the discharge part direction to help recover the meniscus, and thus increases the refill speed.

At this stage, a liquid column that consists of the discharged droplet

66

, which has discharged from the discharge part

4

, becomes the liquid droplet to be flown to outside.

Since the flow of the liquid into the flow path

3

via the portion between the foregoing movable member

11

and stopper

12

increases the flow speed in the top plate

2

side, there is few residual micro bubbles and the like, which contributes to the stability of discharge.

Moreover, since a cavitation generating point due to disappearance shifts to the downstream side of the bubble generation region, damage to the heat generator reduces. At the same time, this phenomenon also reduces adhesion of burn to the heat generator

10

, which improves the discharge stability.

FIG. 2E

shows the state where the movable member

11

is overshot downwardly from the initial state after the bubble

40

has been completely disappeared and is displaced (after the E point in FIG.

5

).

The overshooting of the movable member

11

is damped and converged in a short time, although it depends on the rigidity of the movable member and the viscosity of the liquid used, to return to the initial state.

The case where the liquid discharge is normally performed has been described above with reference to

FIG. 2A

to FIG.

2

E. In a conventional liquid discharge head, there has been the case where printing was deteriorated because the discharge amount and the discharge speed were reduced, the discharge direction became unstable and the like. Particularly, such a phenomenon may have occurred when the protrusion height of the stopper was 15 μm or more. When the inventors examined the causes of the printing deterioration, they found out that the bubble has been remained in the flow path as shown in

FIG. 17A

to

FIG. 17G

to cause the printing deterioration. Specifically, there has been the case where the dissolved gas in the ink became the bubble due to temperature increase and the like by the change by passage of time and the continuous foaming and the bubble stayed in the vicinity before and after the stopper. Normally, such a bubble is washed down by the ink flow to be discharged from the discharge part. However, there is a case where the bubble that exists in this position is not washed down but stays as it is because the ink flow proceeds so as to avoid the vicinity of the stopper and little liquid flow is made in the vicinity of the stopper. The bubble does not move but remains even if the ink discharge and refilling are repeated, and the bubble absorbs the bubble foaming power to cause the reduction of the discharge amount and the discharge speed and the unstable discharge direction.

On the contrary, in this embodiment, since there is a sufficient clearance “a” between the stopper

12

and the sidewall

20

, ink flows passing the clearance “a”. Accordingly, the bubble that exists in the vicinity of the stopper is washed down together with ink to be discharged from the discharge part.

FIG. 6A

to

FIG. 6G

show the case where a large remained bubble

50

is generated in the flow path

3

due to the change by passage of time during non-operation period of ink. As shown in

FIG. 6A

, preparatory discharge that does not contribute to printing is performed as a preliminary operation before a printing operation in the state where the large remained bubble

50

exists in the vicinity of the stopper

12

. When power is supplied to the heat generator

10

for the preparatory discharge, the bubble

40

is generated to grow in near the heat generator

10

, as shown in

FIG. 6B

, and a part of the bubble

40

protrudes from the discharge part. Then, when heating is stopped and the bubble

40

begins to contract as shown in

FIG. 6C

, the movable member

11

recovers from the maximum displacement state, and ink is drawn toward the bubble

40

. And then, a part of ink that protrudes from the discharge part

4

is cut off from ink in the flow path

3

to be discharged as an ink droplet toward a preparatory discharge receiving member (not shown) in the outside. As shown in

FIG. 6D

, in the state where the bubble

40

is almost disappeared and the movable member

11

almost recovers to a stationary state, the ink flow occurs from the upstream side (the common liquid chamber

6

side) to the downstream side (the discharge part

4

side) so as to refill ink for an discharged amount. At this point, different from the conventional liquid discharge head, a flow that goes through sufficient clearance “a” between the stopper

12

and the sidewall

20

also occurs in this embodiment. This ink flow washes down and discharges the large remained bubble

50

, which exists in the vicinity of the stopper, from the discharge part

4

. As described, according to this embodiment, the large remained bubble

50

occurred due to the change by passage of time during the non-operation period of ink is discharged from the discharge part

4

at the time of refilling after the preparatory ink discharge. Accordingly, high-quality ink discharge can be performed during printing in the state where the remained bubble

50

does not exist in the flow path

3

. It is to be noted that the front and the rear length of the stopper can be made longer to suppress ink movement to the upstream side during bubble foaming, depending on the dimension of the clearance.

In addition,

FIG. 7A

to

FIG. 7G

show the case where a relatively small remained bubble

60

is generated in the flow path

3

due to temperature increase with continuous printing (continuous bubble foaming) during ink operation. In this case as well, when power is supplied to the heat generator

10

in the state where the remained bubble

60

exists in the vicinity of the stopper

12

, substantially similarly to the case shown in

FIG. 6A

to

FIG. 6G

, the bubble

40

is generated near the heat generator

10

as shown in FIG.

7

B. Then, when heating is stopped and the bubble

40

begins to contract as shown in

FIG. 7C

, ink is drawn toward the bubble

40

and the ink droplet is discharged to a recording medium

150

(refer to

FIG. 15

) or the like of the outside. And then, as shown in

FIG. 7D

, when the bubble

40

is almost deformed and the ink flow occurs from the upstream side (the common liquid chamber

6

side) to the downstream side (the discharge part

4

side), the flow that goes through the sufficient clearance “a” between the stopper

12

and the sidewall

20

also occurs. This ink flow washes down and discharges the remained bubble

60

, which exists in the vicinity of the stopper, from the discharge part

4

. As described, even if the remained bubble

60

is generated, it is occasionally discharged from the discharge part

4

. Thus, it does not grow into a large remained bubble as shown in the case of

FIG. 6A

to

FIG. 6G

, but it is discharged together with ink before influence is given to printing quality.

Next, description will be made particularly regarding an elevated bubble

41

elevated from both side portions of the movable member

11

and the meniscus of the liquid at the discharge part

4

by using

FIG. 8

being the transparent perspective view of the head shown in FIG.

1

. It is to be noted that although the shape of the stopper

12

and the shape of the low flow path resistance region

3

a

in the upstream side from the stopper

12

are different from those shown in

FIG. 1

, basic characteristic are the same.

In this embodiment, the clearance “b” of a small amount exists between the wall surface of the sidewall

20

constituting the flow path

3

and the both side portions of the movable member

11

, which enables a smooth displacement of the movable member

11

. Furthermore, in a growing process of the bubble foaming by the heat generator

10

, the bubble

40

displaces the movable member

11

and elevates toward the upper surface side of the movable member

11

via the foregoing clearance “b” to go into the low flow path resistance region

3

a

by a little amount. The elevated bubble

41

that has gone into the region controls the shaking of the movable member

11

and stabilizes the discharge characteristic by bending on the rear surface (the opposite surface to the bubble generation region) of the movable member.

Furthermore, in the bubble disappearance process of the bubble

40

, the elevated bubble

41

promotes the liquid flow from a low flow path resistance region

703

a

to the bubble generation region, and completes disappearance in combination with a high-speed drawing back of the meniscus from the discharge part

4

side. Particularly, few bubbles remains in the corner of the movable member

11

and the flow path

3

by the liquid flow caused by the elevated bubble

41

.

As described, in the liquid discharge head of the foregoing constitution, the discharged droplet

66

is discharged in a state close to the liquid column having a spherical portion at its tip at the moment when the liquid is discharged from the discharge part

4

by generation of the bubble

40

. The same phenomenon occurs in a conventional head structure. However, in this embodiment, a space is formed in which the flow path

3

having the bubble generation region is substantially closed except for the discharge part

4

when the movable member

11

is displaced by the growing process of the bubble and the displaced movable member

11

contacts the stopper. Therefore, if the bubble is disappeared in this state, the closed spaced described above is maintained until the movable member

11

is released from the stopper

12

, and thus, most of the disappearance energy of the bubble

40

works as a force to move the liquid in the vicinity of the discharge part

4

to the upstream direction. As a result, the meniscus is quickly drawn back from the discharge part

4

into the flow path

3

immediately after the disappearance of the bubble

40

has begun, and a tail portion that forms the liquid column by connecting with the discharged droplet

66

in the outside is quickly cut off by the meniscus with a strong force. With this action, the satellite dot formed by the tail portion becomes small and the printing resolution can be improved.

Moreover, since the tail portion is not continuously drawn by the meniscus for a long time, the discharge speed is not reduced and the distance between the discharged droplet

66

and the satellite dot is shortened. Thus, the satellite dot is drawn back to the rear of the discharged droplet

66

due to a so-called slipstream phenomenon. As a result, coalescence of the discharged droplet

66

and the satellite dot could occur, and the liquid discharge head with few satellite dots can be provided.

In addition, in this embodiment, the movable member

11

is provided to suppress only the bubble

40

that grows in the upstream direction regarding the liquid flow directed to the discharge part

4

. More preferably, the free end

11

b

of the movable member

11

is positioned substantially at the central portion of the bubble generation region. According to this constitution, the inertial force of the back wave and the liquid to the upstream side due to the bubble growth can be suppressed, which is not directly related to the liquid discharge, and the growing component of the bubble

40

to the downstream side can be directed to the discharge part

4

directly.

Furthermore, since the flow path resistance of the low flow path resistance region

3

a

, which is in the opposite side to the discharge part

4

with the stopper

12

as a border, is low, the liquid movement to the upstream direction due to the growth of the bubble

40

becomes a large flow by the low flow path resistance region

3

a

. Thus, when the displaced movable member

11

contacts the stopper

12

, the movable member

11

receives the stress that pulls the movable member

11

to the upstream direction. Accordingly, if disappearance begins in this state, the foregoing closed space can be maintained for a certain period of time until the repulsive force of the movable member

11

overcomes the liquid movement force because the liquid movement in the upstream direction due to the growth of the bubble

40

is largely residual. Specifically, a high-speed drawing back of the meniscus is more ensured with this constitution. When the disappearance process of the bubble

40

proceeds and the repulsive force of the movable member

11

overcomes the liquid movement force of the bubble growth in the upstream direction, the movable member

11

is displaced downwardly to return to the initial state and the flow in the downstream direction occurs in the low flow path resistance region

3

a

accordingly. The flow in the downstream direction in the low flow path resistance region

3

a

quickly becomes a large flow because of the small flow path resistance and flows into the flow path

3

via the stopper

12

. As a result, the drawing back of the foregoing meniscus can be quickly stopped to converge the vibration of the meniscus in high-speed.

As described above, since the liquid discharge head of this embodiment has the large clearance “a” between the stopper

12

and the sidewall

20

of the flow path

3

, the ink flow that goes through the clearance “a” occurs during the ink refilling and the like. Thus, the bubble in the vicinity of the stopper

12

, which conventionally has been apt to remain, can be discharged and the discharge energy by heating can be effectively transmit to the liquid, and the liquid can be stably discharged so that a desired discharge characteristic can be certainly exerted.

Second Embodiment

FIG. 9

is a typical plan view of the flow path of a second embodiment according to the present invention. Description is omitted for the portions substantially same as the first embodiment. In the first embodiment, the clearance “a” between the stopper

12

and the sidewall

20

of the flow path

3

was symmetric, but this embodiment has a constitution where only either one clearance “a

1

” of a stopper

21

is large and the other clearance “a

2

” is small. In this constitution, the ink flow that washes down the remained bubbles

50

and

60

in the vicinity of the stopper

21

can be generated, the same effect as the first embodiment can be obtained.

Third Embodiment

FIG. 10

is a typical plan view of the flow path of a third embodiment according to the present invention. Description is omitted for the portions substantially same as the first embodiment. In this embodiment, the both side edge portions of a stopper

22

is convex toward the sidewall

20

and is in a shape that the width thereof is continuously becomes narrower from the maximum width portion toward the upstream side and the downstream side. The large clearance “a” is maintained between the maximum width portions, that is, the tip portion of the convex shape and the sidewall

20

as described above. According to this embodiment, in addition to the effect of the first embodiment, a shape where the ink flow is apt to stagnate does not exist between the stopper

22

and the sidewall

20

. Specifically, the remained bubbles

50

and

60

moves smoothly along a slope of the side edge portion of the stopper

22

and quickly discharged from the discharge part

4

together with the ink flow.

Fourth Embodiment

FIG. 11

is a typical plan view of the flow path of a fourth embodiment according to the present invention. Description is omitted for the portions substantially same as the first embodiment.

In this embodiment, stoppers

23

are severally formed on the both sidewalls

20

of the flow path

3

. The stopper

23

has a shape that becomes convex toward the inside of a flow path

20

, and is formed such that the width continuously becomes narrower from the maximum width portion toward the upstream side and the downstream side. The large clearance “a” is maintained between the both stoppers

23

at the tip portion of the convex shape, and the clearance “a” is the equal size as the clearance between the stopper

12

and the sidewall

20

in the first embodiment. According to this embodiment, in addition to the effect of the first embodiment, a shape where the ink flow is apt to stagnate does not exist between the stoppers

23

. Specifically, similarly to the third embodiment, the remained bubbles

50

and

60

moves smoothly along a slope of the side edge portion of the stoppers

23

and quickly discharged from the discharge part

4

together with the ink flow.

Although it will not be described in detail, even with the constitution in which the stoppers

23

are severally formed on the both sidewalls

20

of the flow path

3

, the same effect can be obtained by making the dimensions of the stopper

23

, the movable member

11

and the flow path

3

be substantially the same dimensions as the first embodiment.

Movable Member

Next, description will be made in detail regarding the movable member

11

used in the liquid discharge head of each of the foregoing embodiments.

As a material for the movable member

11

, the followings are desirable other than silicon nitride, which are: metal such as silver, nickel, gold, iron, titanium, aluminum, platinum, tantalum, stainless steel and phosphor bronze, having high durability, and alloy thereof; resin having nitrile group such as acrylonitrile, butadiene and styrene; resin having amide group such as polyamide; resin having carboxyl group such as polycarbonate; resin having aldehyde group such as polyacetals; resin having sulfone group such as polysulfone; resin such as other liquid crystal polymers and compound thereof; metal such as gold, tungsten, tantalum, nickel, stainless steel and titanium, having high ink-resistance, alloy thereof and one with improved ink-resistance by coating such material on the surface; or resin having amide group such as polyamide; resin having aldehyde group such as polyamide; resin having ketone group such as polyether etherketone; resin having imide group such as polyimide; resin having hydroxide group such as phenol resin; resin having ethyl group such as polyethylene; resin having alkyl group such as polypropylene; resin having epoxy group such as epoxy resin; resin having amino group such as melamine resin; resin having methylol group such as xylene resin and compound thereof; and ceramic such as silicon dioxide and silicon nitride and compound thereof.

Next, description will be made for the arrangement relation of the heat generator

10

and the movable member

11

. Optimum arrangement of the heat generator

10

and the movable member

11

can appropriately control and effectively utilize the liquid flow during the bubble foaming by the heat generator

10

.

In a prior art of an ink-jet recording method in which a state change with steep volume change (generation of the bubble) is produced in ink by giving an energy such as heat to ink, ink is discharged from the discharge part

4

by an operating force based on the state change, and ink is adhered to the recording medium to form an image, which is a so-called bubble-jet recording method, the area of the heat generator and the ink discharge amount are in a proportional relation as shown in FIG.

12

. It is noted that there exists a non-foaming effective region S. And, it is understood from the appearance of the burn that the non-foaming effective region S exists around the heat generator

10

. As a result, the region including approximately 4 μm around the heat generator is not involved in the bubble foaming.

Accordingly, to utilize the bubble foaming pressure, the portion directly above the foaming effective region, which is 4 μm or more inside around the heat generator

10

, is the region that effectively operates to the movable member

11

. In the case of the present invention, it is extremely important that an operating step is divided into the step that individually operates to the liquid flows in the flow path

3

of the bubble in the upstream side and the downstream side from substantially central region of the bubble generation region (practically, the area of approximately 10 μm from the center in the liquid flow direction) and the step that generally operates to the liquid flows, and that the movable member

11

is arranged such that only the portion in the upstream side from the central region faces the movable member

11

. In this embodiment, the bubble foaming effective region is 4 μm or more inside around the heat generator

10

, but the region is not limited to this depending on the kind the forming method of the heat generator

10

.

Element Substrate

Next, description will be made for the constitution of the element substrate

1

provided with the heat generator for giving heat to the liquid, which is used in the liquid discharge head of each of the foregoing embodiments.

FIG.

13

A and

FIG. 13B

show typical sectional side views of the principle portion of the liquid discharge head being an example of the present invention.

FIG. 13A

is the liquid discharge head with a protective film (described later) and

FIG. 13B

is the liquid discharge head without the protective film. The top plate

2

with a groove, in which the groove constituting the foregoing flow path

3

is provided, is arranged above the element substrate

1

.

In the element substrate

1

, a silicon oxide film or a silicon nitride film

106

aiming at insulation and heat storage is deposited on a base

10

such as silicon, and an electrical resistance layer

105

(the thickness of 0.01 to 0.2 μm) constituting the heat generator

10

such as hafnium boride (HfB2), tantalum nitride (TaN) and aluminum nitride (TaAl) and a wiring electrode

104

(the thickness of 0.2 to 1.0 μm) such as aluminum are patterned as shown in

FIG. 13A. A

voltage is applied from the wiring electrode

104

to a resistance layer

105

, and a current is flown to the resistance layer

105

to generate heat. A protective layer

103

of silicon oxide, silicon nitride or the like is formed on the resistance layer

105

between the wiring electrodes

104

in the thickness of 0.1 to 2.0 μm, and an anti-cavitation layer

102

such as tantalum (the thickness of 0.1 to 0.6 μm) is further deposited thereon to protect the resistance layer

105

from various kinds of liquid such as ink.

Particularly, a pressure and a shock wave generated during generation and disappearance of the bubble

40

is very strong, and they significantly reduces the durability of an oxide film that is hard and fragile. Accordingly, a metal material such as tantalum (Ta) or the like is used as the anti-cavitation layer

102

. Alternatively, a constitution in which the resistance layer

105

does not require the protective film

103

may be adopted depending on the combination of the liquid, a flow path constitution and a resistance material. An example of such constitution is shown in FIG.

13

B. As a material for the resistance layer

105

that does not require the protective film

103

, an iridium-tantalum-aluminum alloy is cited.

As described, as a constitution of the heat generator

10

in each of the foregoing embodiments, only the resistance layer

105

(heat generation portion) between the electrodes

104

may be adopted, or a constitution including the protective film

103

to protect the resistance layer

105

may be adopted.

In each embodiment, one having the heat generation portion, which is constituted of the resistance layer

105

, that generates heat in accordance with an electric signal is used as the heat generator

10

. However, the heat generator is not limited to such type. One that generates the bubble

40

having a sufficient size for discharging the liquid to be discharged in a foaming liquid may be adopted. For example, a photothermo converter that generates heat by receiving a beam such as a laser and the heat generator having the heat generation portion that generates heat by receiving a high frequency may be used.

Furthermore, other than the heat generator

10

constituted of the resistance layer

105

constituting the foregoing heat generation portion and the wiring electrode

104

for supplying the electrical signal to the resistance layer

105

, function devices such as a transistor, a diode, a latch and a shift register that selectively drive the heat generator

10

(an electro-thermal converter) may be integrally fabricated on the element substrate

1

by a semiconductor manufacturing process.

To discharge the liquid by driving the heat generation portion of the heat generator

10

provided on the element substrate

1

, a rectangular pulse as shown in

FIG. 14

is applied to the foregoing resistance layer

105

via the wiring electrode

104

to generate heat steeply the resistance layer

105

between the wiring electrodes

104

. In the head of each of the foregoing embodiments, the heat generator

10

was driven by applying the voltage 24 [V], the pulse width 7 [μm], the current 150 [mA] and the electrical signal 6 [kHz], and ink being the liquid was discharged from the discharge part

4

by the above-described operation. However, the conditions of the drive signal are not limited to this, and any drive signal that can appropriately foam the foaming liquid may be used.

Recording Apparatus

In the following, description will be made regarding an example of a recording apparatus using the liquid discharge head that has been described in each embodiment.

FIG. 15

is a typical perspective view showing an example of a recording apparatus assembled with the foregoing liquid discharge head and using ink as a discharge liquid. A carriage HC mounts a head cartridge capable of attaching/detaching a liquid tank portion

90

to contain ink and a recording head portion being the liquid discharge head

200

, which reciprocates in a width direction of a recording medium

150

such as a recording paper carried by recording medium carrying means.

When the drive signal is supplied to liquid discharge means on the carriage HC from drive signal supply means (not shown), ink (recording liquid) is discharged from the recording head portion to the recording medium in accordance with the signal.

In addition, the recording apparatus of this embodiment includes: a motor

111

as a drive source to drive the recording medium carrying means and the carriage; gears

112

and

113

, a carriage shaft

115

, a recovery apparatus

116

and the like. A recording of a good image could be obtained by discharging the liquid to various kinds of recording media, with this recording apparatus and the liquid discharge method performed by the recording apparatus.

FIG. 16

is a block diagram of the entire recording apparatus for performing an ink-jet recording by the liquid discharge head of each of the foregoing embodiments.

The recording apparatus receives printing information from a host computer

300

as the drive signal. The printing information is temporarily stored in an input interface in the printing apparatus, and at the same time, is converted into processible data in the recording apparatus, and then input to a CPU (a central processing apparatus)

302

that also serves as head drive signal supply means. The CPU

302

based on a control program stored in a ROM (a read only memory)

303

, processes the data input to the foregoing CPU

302

by using a peripheral apparatus such as a RAM (a random access memory)

304

to convert into data (image data) to be printed.

Further, the CPU

302

makes drive data for driving a driving motor

306

, which is synchronized with the image data to move the carriage mounting the recording paper and the recording head portion, in order to record the image data on a proper position of the recording paper. The image data and motor driving data are transferred to the recording head portion

200

and the driving motor

306

via a head driver

307

and a motor driver

305

respectively to be driven in a controlled timing, and form an image.

As the recording medium

150

used in the recording apparatus of this kind and to which the liquid such as ink is attached, the followings can be used, which are: various kinds of papers and OHP sheet; a plastic material used for a compact disc, a decoration plate and the like; a cloth; metal material such as aluminum and copper; leather material such as calf skin, pig skin and artificial leather, a wood material such as a wood and a block board; a bamboo material; a ceramics such as a tile; a three-dimensional structure body such as a sponge; and the like.

Furthermore, the recording apparatus includes: a printer apparatus that performs recording to various kinds of papers, OHP sheet and the like; a recording apparatus for plastic that performs recording to the plastic material such as the compact disc; a recording apparatus for metal that performs recording to the metal plate; a recording apparatus for leather that performs recording to leather; a recording apparatus for wood that performs recording to the block board; a recording apparatus for ceramics that performs recording to the ceramic material; a recording apparatus that performs recording to the three-dimensional mesh structure body such as the sponge; and a textile printing apparatus that performs recording to the cloth.

Additionally, as the discharge liquid used for the liquid discharge heads, a liquid that conforms to each recording medium and recording conditions.

According to the present invention, the clearance between the sidewall and the side edge portion of the restricting portion is large, and the liquid can flow through the clearance. Accordingly, even if the remained bubble exists in the vicinity of the restricting portion, the foregoing liquid flow occurred during refilling of the liquid and the like washes down and the remained bubble can be discharged from the discharge part. Therefore, the bubble foaming pressure due to heat generation for the liquid discharge is not absorbed by the remained bubble but is effectively transmitted to the liquid, and thus the liquid can be stably discharged.

When the side edge portion of the restricting portion has a shape where its width continuously becomes narrower from the maximum width portion toward the upstream side and downstream side, the remained bubble moves smoothly along the side edge portion of the restricting portion, and the discharge of the remained bubble can be performed more certainly.

Number	Name	Date	Kind
4723129	Endo et al.	Feb 1988	A
5278585	Karz et al.	Jan 1994	A
6168264	Yoshihira et al.	Jan 2001	B1

Number	Date	Country
0 721 841	Jul 1996	EP
0 976 562	Feb 2000	EP
1 005 991	Jun 2000	EP
4-250051	Sep 1992	JP
5-104719	Apr 1993	JP
6-31918	Feb 1994	JP
9-48127	Feb 1997	JP
9-323420	Dec 1997	JP
0 819 528	Jan 1998	JP
10-24588	Jan 1998	JP

Liquid discharge head and apparatus having restricted movement of a movable member

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