JPH11263023A - Recording head - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a recording head an upper face of which can be cleaned good, thereby achieving stable recording characteristics without consuming ink undesirably. SOLUTION: A recording head 1 has a piezoelectric element 15 for generating ultrasonic waves, a base 12 loading the piezoelectric element 15, a lens member 20 layered on the piezoelectric element 15 for condensing the ultrasonic waves and, an ink chamber member having a slit 10 formed at a condensation position of the ultrasonic waves to extend in a main scan direction of the head 1. Ink is supplied from an ink tank 4 via a feed tube 6 to the recording head 1. The ink tank 4 is held to be movable up, down by a lift mechanism 30. When an upper face of the recording head 1 is to be cleaned, the ink tank is lowered and a part of the ink supplied into the recording head 1 is collected to the ink tank 4, thereby lowering a liquid level of the ink located at an upper end of the slit 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording head for forming an image on a recording medium by flying ink droplets corresponding to an image signal toward the recording medium, and more particularly to an ultrasonic wave radiated from a piezoelectric element. The present invention relates to a recording head that forms an image on a recording medium by ejecting ink droplets by the pressure of the recording head.

[0002]

2. Description of the Related Art Conventionally, as a recording head for forming a dot by an ink droplet on a recording medium by ejecting an ink droplet corresponding to an image signal toward the recording medium and forming a desired image on the recording medium, an ultra-high resolution recording head has been used. There is known an apparatus in which a sound wave is focused on an ink liquid surface and an ink droplet is ejected by utilizing the pressure of an ultrasonic wave.

A recording head using this kind of ultrasonic wave is:
In general, a plurality of piezoelectric elements for generating ultrasonic waves according to an image signal are arranged in parallel at the bottom of an ink tank containing ink, and the piezoelectric elements are arranged in the direction in which the piezoelectric elements are arranged along the liquid surface of the ink separated from the piezoelectric elements. It is formed by forming an extended slit. The slit width should be between 100 μm and 500 μm to prevent ink evaporation and stabilize the ink liquid level.
It is set to about μm. Then, ultrasonic waves generated from the respective piezoelectric elements are respectively focused on a plurality of ejection points along the center of the slit, and ink droplets are ejected from desired ejection points by the pressure of the ultrasonic waves.

[0004]

In the above-described conventional recording head, ink droplets are ejected from a plurality of ejection points having a liquid surface connected along a slit.
It is difficult to stabilize the diameter of the ejected ink droplet and the ejection direction of the ink droplet. In particular, when dust or debris (paper dust or the like) generated from a recording medium adheres to the vicinity of the slit and a stable liquid surface cannot be formed at the slit, the diameter of the ink droplet becomes unstable and the ink droplet There is a problem that the ejection direction becomes unstable.

For this reason, in the conventional recording head, a cleaning member such as a sponge is slid on the upper surface of the recording head in which the slit is formed, and the upper surface of the head in the vicinity of the slit is cleaned during standby of the recording operation. .
However, at this time, there is a problem that ink in the recording head is undesirably sucked up by the cleaning member through the slit, and the ink is wasted.
In addition, when the cleaning member is slid on the top surface of the head, ink is undesirably attached to the top surface of the head near the slit, and the attached ink is connected to the ink in the head via the slit, and the ink liquid in the slit is The surface becomes unstable, and the ejection direction of the ink droplet becomes unstable.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and has as its object to prevent undesired waste of ink.
An object of the present invention is to provide a recording head capable of satisfactorily cleaning the head upper surface and obtaining stable recording characteristics.

[0007]

In order to achieve the above object, a recording head according to a first aspect of the present invention has an upper surface formed with a slit extending along a horizontal plane spaced a predetermined distance below a recording medium. A storage container for storing the recording liquid such that the liquid surface is held by the slit; and a recording liquid supplied to the storage container to maintain the liquid surface in the slit, and the recording liquid is supplied from the storage container. A recording liquid supply / recovery unit for collecting and lowering the liquid surface held by the slit, and a sound wave based on an image signal that is provided in the storage container and propagates in the recording liquid toward the slit. A sound wave generating means for generating, and a sound wave converging means for converging sound waves generated by the sound wave generating means to the center of the slit and discharging a recording liquid from the slit toward a recording medium, When cleaning the upper surface on which the lit is formed, a part of the recording liquid supplied to the container is recovered by the recording liquid supply / recovery unit, and the liquid surface held by the slit is lowered. And

According to a second aspect of the present invention, there is provided a recording head having an upper surface formed with a slit extending along a horizontal plane spaced a predetermined distance below a recording medium, and the liquid surface is held by the slit. A storage container that stores the recording liquid, a tank that is connected to the storage container via a supply pipe, stores the recording liquid to be supplied to the storage container, and supplies the recording liquid from the tank to the storage container. Between a first position where the liquid surface is held by the slit and a second position where a part of the recording liquid is collected from the storage container to the tank and the liquid surface held by the slit is lowered. Lifting means for raising and lowering the tank relative to the storage container,
A sound wave generating unit that is provided at the bottom of the container and generates a sound wave based on an image signal propagated in the recording liquid toward the slit, and a sound wave generated by the sound wave generating unit is transmitted to a center of the slit. A focusing means for converging and discharging a recording liquid toward the recording medium from the slit, and a cleaning means for cleaning foreign substances attached near the slit by sliding a cleaning member on the upper surface of the storage container. The cleaning means includes a part in which the tank is lowered to the second position by the elevating means, a part of the recording liquid supplied to the storage container is collected in the tank, and a liquid surface held by the slit is In the lowered state, a cleaning member is slid on the upper surface of the container to clean the upper surface.

According to a third aspect of the present invention, there is provided a recording head, wherein the recording medium is conveyed in a first direction along a horizontal plane spaced a predetermined distance below the recording medium conveyed in a substantially horizontal direction. A storage container for storing a recording liquid such that the liquid level is held by the slit, and a storage container provided adjacent to the storage container and provided via a supply pipe. A tank that stores the recording liquid to be supplied to the storage container, and a first position that supplies the recording liquid from the tank to the storage container via the supply pipe and holds the liquid surface at the slit. The tank is transferred to the storage container between a second position where a part of the recording liquid is recovered from the storage container to the tank via the supply pipe and the liquid surface held by the slit is lowered. Ascending and descending relative to Elevating means for raising and lowering, a sound wave generating means extending along the first direction at the bottom of the container and generating sound waves propagating in the recording liquid toward the slit based on an image signal; A plurality of grooves provided in a stacked manner on the sound wave generating means and extending in the first direction and exposed to the recording liquid; and the sound wave generated by the sound wave generating means is transmitted to the slit by the action of the groove. A focusing means for focusing in a second direction orthogonal to the first direction toward the center of the recording medium and discharging a recording liquid from the slit toward a recording medium; Cleaning means for cleaning foreign matter adhering in the vicinity of the slit by causing the tank to descend by the elevating means. Is set to a height at which the recording liquid is not collected, and the cleaning means lowers the tank to the second position by the elevating means, and a part of the recording liquid supplied to the storage container is recovered to the tank. A cleaning member slides on the upper surface of the storage container to clean the upper surface while the liquid surface held by the slit is lowered.

According to the recording head of the present invention, the height position of the tank is determined by detecting the height of the liquid surface of the recording liquid stored in the tank, and the elevation means is moved. It is characterized by being adjusted by actuation.

According to a fifth aspect of the present invention, there is provided the recording head according to the first aspect, wherein the first direction crosses the transport direction of the recording medium along a horizontal plane separated by a predetermined distance below the recording medium transported in a substantially horizontal direction. A storage container for storing a recording liquid such that the liquid level is held by the slit, and a storage container provided adjacent to the storage container and provided via a supply pipe. A tank that stores the recording liquid to be supplied to the storage container, and a first position that supplies the recording liquid from the tank to the storage container via the supply pipe and holds the liquid surface at the slit. The tank is transferred to the storage container between a second position where a part of the recording liquid is recovered from the storage container to the tank via the supply pipe and the liquid surface held by the slit is lowered. Ascending and descending relative to Elevating means for raising and lowering, a sound wave generating means extending along the first direction at the bottom of the container and generating sound waves propagating in the recording liquid toward the slit based on an image signal; A plurality of grooves extending in the first direction provided on the upper surface exposed to the recording liquid and provided on the sound wave generating means, and the sound waves generated by the sound wave generating means are transmitted by the action of the grooves; A sound wave converging means for converging in a second direction orthogonal to the first direction toward the center of the slit and discharging a recording liquid from the slit toward a recording medium; and a cleaning member on an upper surface of the storage container. A cleaning means for cleaning foreign matter adhering in the vicinity of the slit by making a sliding contact, wherein the tank is lowered by the elevating means.
The position is such that the recording liquid filled between the upper surface of the sound wave focusing means and the upper surface of the storage container is separated from the recording liquid stored in the tank by the air flowing through the slit. The cleaning means is set at a height, and in a state where the tank is lowered to the second position by the elevating means and the recording liquid is divided, a cleaning member is slid on the upper surface of the storage container to bring the upper surface into contact. It is characterized by cleaning.

Further, according to a sixth aspect of the present invention, in the recording head according to the first aspect, the recording medium is conveyed in a first direction transverse to a conveying direction of the recording medium along a horizontal plane spaced a predetermined distance below the recording medium conveyed in a substantially horizontal direction. A storage container for storing the recording liquid such that the liquid level is held by the slit, a storage container provided adjacent to the storage container, and formed at the bottom of the storage container. A tank that is connected to the container via a supply pipe connected to the hole and stores the recording liquid to be supplied to the container, and supplies the recording liquid from the tank to the container via the supply pipe. A first position in which the liquid surface is held by the slit, and a second position in which a part of the recording liquid is recovered from the storage container to the tank via the supply pipe and the liquid surface held by the slit is lowered. 2
Lifting means for raising and lowering the tank relative to the storage container between the first position and the first position, wherein the first portion is located at a bottom of the storage container and separated from a hole to which the supply pipe is connected.
A sound wave generating means for generating a sound wave propagating in the recording liquid toward the slit based on an image signal, and provided on the sound wave generating means in a layered manner. A plurality of grooves extending in the first direction are provided on the exposed upper surface, and the sound waves generated by the sound wave generating means are directed to the center of the slit by the action of the grooves at right angles to the first direction. A sound wave converging means for converging in a second direction and discharging a recording liquid from the slit toward a recording medium, and a cleaning member slidably brought into contact with the upper surface of the storage container to clean foreign matters adhering in the vicinity of the slit. A hole formed in the bottom of the container is formed at a position facing one end of a slit formed on the upper surface of the container, and the hole is formed by the elevating means. The second position where the ink is lowered is a position where the recording liquid filled between the upper surface of the sound wave focusing means and the upper surface of the storage container flows into the hole through one end of the slit. The cleaning liquid is set to a height that is separated from the recording liquid stored in the tank.
In a state in which the recording liquid is lowered to the position and the recording liquid is separated, a cleaning member is slid on the upper surface of the storage container to clean the upper surface.

[0013]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows a recording head 1 of the present invention together with its peripheral members. A platen roller 2 is provided at a position facing the upper surface 1a of the recording head 1 via a predetermined gap. The platen roller 2 is rotated in a predetermined direction with the recording paper P wound around the platen roller 2. As a result, the recording paper P is conveyed in a direction substantially orthogonal to the rotation axis of the platen roller 2 while maintaining a certain gap with respect to the head upper surface 1a.

A slit 10 is formed on the upper surface 1a of the recording head 1 so as to extend in a direction transverse to the transport direction of the recording paper P, that is, in parallel with the rotation axis of the platen roller 2. An ink tank 4 containing ink to be supplied to the recording head 1 is provided at a position adjacent to the recording head 1. The ink tank 4 is connected to the recording head 1 via a supply tube 6.

FIG. 2 is a perspective view schematically showing the recording head 1 in a partially disassembled state. The recording head 1 has a rectangular plate-shaped base material 12 having an upper surface 12a extending substantially horizontally. On the upper surface 12a of the substrate 12, a plurality of extraction electrodes 13 extending in the sub-scanning direction (the direction of arrow Y in the drawing) of the recording head 1 are formed at a predetermined pitch in an array. Further, a piezoelectric element 15 for generating an ultrasonic wave is provided on the upper surface 12a of the base material 12 via these extraction electrodes 13. A supply tube 6 is provided on a portion of the base material 12 where the piezoelectric element 15 is not mounted.
And an ink supply hole 12b for connecting the ink supply port.

The piezoelectric element 15 extends in the sub-scanning direction of the recording head 1 and includes a plurality of individual electrodes 14 arranged in an array.
(See FIG. 3). The piezoelectric body 16 is made of a lead titanate-based piezoelectric ceramic having a relative dielectric constant of 200 and has a thickness of about 50 μm, and the common electrode 17 is sequentially laminated in a direction away from the base material 12. Each individual electrode 14 of the piezoelectric element 15 is provided corresponding to the extraction electrode 13 formed on the upper surface 12a of the substrate 12, has a length of, for example, 5.0 mm in the sub-scanning direction, and is orthogonal to the sub-scanning direction. It has a width of 60 μm in the main scanning direction (the direction of arrow X in the figure), and has a width of 2 μm in the main scanning direction.
It is formed at a pitch of 5 μm. Also, the common electrode 17
Has a length of, for example, 2.0 mm in the sub-scanning direction, and is provided so as to cover all the individual electrodes.

Then, each individual electrode 14 of the piezoelectric element 15 and each lead electrode 13 on the base material 12 are superposed and aligned, and the piezoelectric element 15 and the base material 12 are pressure-bonded through an epoxy resin to form each electrode. Are electrically connected. Each lead electrode 13 is connected to a drive IC 19 for driving the piezoelectric element 15 via a bonding wire 18. The common electrode 17 is connected to a common terminal (not shown) of the driving IC 19. Further, a signal (not shown) for outputting a burst signal (hereinafter, also referred to as a burst wave) based on an image signal input from a signal source (not shown) to each individual electrode 14 is provided to the drive IC 19 connected to each extraction electrode 13. The processing unit is connected.

A substantially rectangular plate-like lens member 20 for focusing the ultrasonic waves generated from the piezoelectric element 15 at the center of the slit 10 formed on the upper surface 1a of the recording head 1 is laminated on the piezoelectric element 15. Have been. On the upper surface of the lens member 20, a plurality of lens grooves 20a extending in the main scanning direction based on the Fresnel zone theory are formed. The plurality of lens grooves 20a are formed symmetrically with respect to the center line in the sub-scanning direction of the lens member 20, and the depth of each lens groove 20a is (2n + 1) of the wavelength of the ultrasonic wave propagating through the ink. / 4 times (n is an integer of 0 or more).

An ink chamber member 11 is provided on the upper surface 12a of the substrate 12 so as to cover the ink supply hole 12b together with the piezoelectric element 15 and the lens member 20. The upper surface of the ink chamber member 11 is
A slit 10 having a width of 300 μm in the sub-scanning direction is formed on the upper surface of the ink chamber member 11. The height of the ink chamber member 11 is set to 2.5 mm from the bottom of the lens groove 20a to the slit 10 so that the focus position of the ultrasonic wave by the lens member 20 exactly matches the height position of the slit 10. It was set to become. For the ink chamber member 11 together with the lens member 20, as a material having an acoustic impedance close to the square root of the product of the acoustic impedance of the piezoelectric body 16 and the acoustic impedance of the ink, for example, epoxy resin in which alumina powder is dispersed is used. Was.

Next, a manufacturing process of the above-described recording head 1 will be described. First, prior to assembling the recording head 1, a plurality of extraction electrodes 13 are previously formed on the upper surface 12a of the base material 12, and the ink chamber member 11 is molded into a predetermined shape.
And a lens member 20 are provided. Lead electrode 13
Is formed by sputtering Ti / Au on the upper surface 12a of the base material 12 and etching it into a predetermined pattern.

The velocity of the ultrasonic wave propagating through the ink chamber member 11 and the lens member 20 is 3 × 10 ³ m /
s is mixed with an epoxy resin to adjust the mixing ratio to an epoxy resin and molded, and the density is 2.20 × 10 ³ k
g / m ³ and a sound speed of 2.95 × 10 ³ m / s. Also,
The lens member 20 was molded such that the bottom surface had a thickness of 45 μm.

The relative dielectric constant is 200 and the thickness is about 0.5 m.
m, a Ti / Au electrode is formed on both surfaces of a piezoelectric body 16 made of a lead titanate piezoelectric ceramic having a width of 5 mm in the sub-scanning direction by sputtering. At this time, an electrode having a thickness of 0.05 μm which will later become the individual electrode 14 is formed on one surface of the piezoelectric body 16, and an electrode for polarization processing is formed with a thickness of 0.2 μm on the other surface. .

Next, an electric field of 3 kV / mm is formed between the electrodes formed on both surfaces of the piezoelectric body 16, and the piezoelectric body 16 is polarized. And one electrode is etched,
A plurality of individual electrodes 1 having a width of 60 μm and an electrode pitch of 25 μm
4 are formed. Then, each individual electrode 14 is
The piezoelectric body 16 is laminated on the upper surface 12a of the base material 12 via an adhesive so as to be superimposed on the lead electrode 13 formed in advance thereon, and both electrodes are pressed and pressed.

As described above, the piezoelectric body 16 is polished together with the polarization electrodes formed on the upper surface of the piezoelectric body in a state where the piezoelectric body is adhered on the base material 12. At this time, the polishing is performed so that the thickness of the piezoelectric body 16 becomes 50 μm. Further, a common electrode 17 of Al is formed on the polished surface of the piezoelectric body 16.
It is formed to a thickness of 0.3 μm by sputtering. The width of the common electrode 17 in the sub-scanning direction is set to 2.0 mm.

The lens member 20 prepared in advance
Are laminated on the piezoelectric element 15 formed as described above, and are bonded via an adhesive. Further, the piezoelectric element 15
And the ink chamber member 11 so as to cover the
Is mounted on the substrate 12. At this time, the ink chamber member 11 is positioned such that the center of the slit 10 of the ink chamber member 11 coincides with the center of the lens member 20 in the sub-scanning direction, and the ink chamber member 11 is bonded onto the base material 12. Further, before the ink chamber member 11 is mounted on the base material 12, ink is supplied to the upper surface of the lens member 20 via a brush or the like, and the plurality of lens grooves 20a are wetted with the ink in advance.

Finally, a driving IC 19 for supplying a driving voltage to the piezoelectric element 15 is mounted on the upper surface 12a of the base 12, and the individual electrodes 14 and the common electrode 17 of the piezoelectric element 15 are connected via bonding wires 18. The bonding is performed, and the assembly of the recording head 1 is completed.

Here, the driving principle of the recording head 1 will be described with reference to FIG. The burst wave output from the signal processing unit (not shown) is formed as a sine wave having a relatively high frequency close to the resonance frequency determined by the thickness of the piezoelectric body 16 and the like, and the wave number calculated by the signal processing unit, that is, It has a burst width determined by this wave number.

In the present embodiment, the eight individual electrodes 14 adjacent to each other are grouped into one group.
, A burst wave having the same wave number is simultaneously applied to eject one ink droplet. At this time, among the burst waves having the same wave number, a 0-phase burst wave and a π-phase burst wave whose phases are shifted from each other by 180 ° are prepared, and the burst waves having different phases in the order of 0π0000π0 are provided in the arrangement direction of the eight electrodes. I did it. Thereby, the ultrasonic waves can be focused toward the center in the arrangement direction of the electrodes, and one ink droplet can be ejected from the center position of the eight electrodes. At this time, the focusing of the sound wave in the sub-scanning direction is caused by the action of the lens groove 20 a of the lens member 20.

As described above, when ink droplets are ejected as a group of eight individual electrodes 14, the ejection interval of ink droplets that can be ejected at the same time corresponds to eight electrodes. Therefore, in order to eject one line of ink droplets along the main scanning direction, the individual electrodes 14 that apply the same burst wave are used.
It is necessary to scan the groups in the main scanning direction while shifting them by one electrode, and to apply eight burst waves to the electrodes of each group.

Next, the operation of the recording head 1 will be described with reference to FIGS. FIG. 4 is a sectional view in the main scanning direction showing the state of the ink inside the print head 1 during the printing operation. FIG. 5 is a main scan showing the state of the ink inside the printing head 1 during the non-printing operation, ie, during the cleaning operation. FIG. 6 is a sectional view in the sub-scanning direction mainly showing a cleaning mechanism for cleaning the upper surface 1a of the recording head 1. FIG.

As shown in FIG. 4, during the recording operation, the ink contained in the ink tank 4 is supplied into the recording head 1 via the ink supply tube 6 and the ink supply holes 12b. At this time, in order to obtain good recording characteristics, it is important that the ink surface is always stably held at the upper end of the slit 10. In order to stably form the liquid surface of the ink at the upper end of the slit 10, the height position of the ink tank 4 connected to the recording head 1 via the supply tube 6 is adjusted, and the ink is moved into the head 1 by hydrostatic pressure. Supplied. That is, by always keeping the difference Δh between the height of the upper end of the slit 10 and the height of the liquid level of the ink in the ink tank 4 constant, the liquid level of the ink can be always formed on the upper end of the slit 10 stably.

An elevating mechanism 30 for adjusting the height position of the ink tank 4 so as to keep Δh constant includes a pair of rollers 31 and 32 which are vertically separated from each other, and includes a pair of rollers 31 and 32. Elevating belt 3 wound and stretched
4. A drive motor (not shown) for rotating one of the rollers in both forward and reverse directions so that the elevating belt 34 can run endlessly, and detecting the liquid level of the ink contained in the ink tank 4 to appropriately control the ink tank 4 It has an ink sensor 36 for detecting the height position. Ink sensor 3
Reference numeral 6 has a pair of electrodes having ends that come into contact with the ink, and detects that the electrodes are conductive through the ink to detect the ink liquid level.

The ink tank 4 is fixed to an elevating belt 34, and is moved vertically by the traveling of the elevating belt 34. At this time, when the ink sensor 36 detects the liquid level of the ink in the ink tank 4, the lifting mechanism 30
Is stopped, and the ink tank 4 is stopped at a predetermined height position. That is, if the end of the electrode of the ink sensor 36 is fixed at a predetermined height position in advance, and the ink tank is stopped when the ink sensor 36 detects the liquid level, the ink contained in the ink tank 4 is stored. The ink level can always be kept at the same level. As a result, Δh can always be kept constant.

When the ink is consumed according to the recording operation, the ink tank 4 is gradually raised so as to correct the drop of the ink level, and the ink level of the ink stored in the ink tank 4 is increased. Is always adjusted to the same height.

By the way, if the recording operation is continued with the ink surface being stably formed on the upper end of the slit 10 as described above, the time during which the slit 10 is exposed to the outside air becomes longer, and , The number of recording papers P passing through the slit increases, and ink adheres or paper dust or dust adheres to the vicinity of the slit. As described above, when paper dust or dust adheres to the vicinity of the slit, it is impossible to stably form the liquid surface of the ink on the upper end of the slit 10, and the ejection direction of the ink droplet becomes unstable, Will be unstable. Therefore, when the printing operation is performed continuously for a certain period of time, it is necessary to temporarily stop the printing operation and clean the print head upper surface 1a near the slit 10.

However, as described above, the recording head 1 remains in a state where the ink surface is formed at the upper end of the slit 10.
When cleaning the upper surface 1a of
A sponge or the like is used as a cleaning member.
When the sliding contact is made, the ink in the recording head 1 is undesirably sucked up through the slit 10, and the ink is wasted and the running cost is increased.

When the ink is sucked up by the sponge, the sucked-up ink is undesirably attached to the upper surface 1a of the recording head 1 by sliding contact of the sponge, and the attached ink and the ink in the head 1 are removed. As a result, the ink liquid level cannot be stably formed at the upper end of the slit 10, causing the above-described inconvenience and deteriorating the recording characteristics.

For this reason, in this embodiment, before the cleaning operation is performed, the ink tank 4 is lowered by a predetermined amount, and the liquid level of the ink filled up to the upper end of the slit 10 is lowered to a predetermined level. I did it. FIG.
3 shows a state in which the ink tank 4 is lowered and a part of the ink supplied into the recording head 1 is collected to the ink tank 4 side.

As described above, by recovering a part of the ink supplied into the recording head 1, the liquid level of the ink filled up to the upper end of the slit 10 is lowered, and in this state, a cleaning member such as a sponge is used. Even if the ink is slid on the head upper surface 1a, the ink is not sucked up by the sponge, thereby preventing the ink from being wasted. Also,
At least when the liquid level is lowered, even if ink is undesirably sucked up through the slit 10, it is possible to prevent a small amount of ink from being wasted and a large amount of ink from being wasted. It is possible to prevent the ink from undesirably adhering to the upper surface 1a of the recording head 1 due to the sliding contact.

In practice, the ink tank 4 is lowered,
When the ink in the recording head 1 starts to be sucked out through the supply tube 6 and the ink supply hole 12b, first, the slit 10 positioned above the ink supply hole 12b.
Air is sucked in from the end 10a, and the connection of the ink is divided at this portion. That is, in the present embodiment, since the length of the lens member 20 in the main scanning direction is sufficiently long with respect to the distance from the lens member 20 to the upper surface of the ink chamber member 11, the length of the lens member 20 is larger than the left end in the drawing. Slit end 10a up to a position close to ink supply hole 12b
Is extended, the capillary force of the ink accumulated on the lens member 20 exceeds the force for connecting the ink at the slit end portion 10a, and the ink is divided at this portion.

As described above, once the connection of the ink is cut off, the ink accumulated above the lens member 20 remains at that location without being recovered by its own surface tension. In other words, by setting the position of the ink supply hole 12b close to the slit end 10a, more specifically, by setting the positions of the two so that the slit end 10a comes above the ink supply hole 12b. State 5 can be maintained.

Thus, even if the ink is sucked up by the cleaning member through the slit 10, the ink is divided at the slit end 10a, so that the ink contained in the ink tank 4 is sucked up. It won't.

Since the ink can be left on the lens member 20 as described above, it is possible to prevent the ink that has entered the lens groove 20a from being collected. That is, since the depth and the width of the lens groove 20a are about several tens of μm, once the ink is collected from the lens groove 20a, the brush and the like are used to assemble the lens groove 20a as in the assembly of the head. Must be forcibly supplied. If the ink cannot be normally supplied into the lens groove 20a, air enters the lens groove 20a, and the ultrasonic waves are undesirably absorbed.
Transmission of ultrasonic waves is not performed normally, and ink droplets are not ejected.

Therefore, when ink is collected from the inside of the recording head 1, the lens member 20 is used as in this embodiment.
It is important to leave the ink in the lens groove 20a.
For this reason, in this embodiment, in order to leave ink on the lens member 20, the slit end 10a is
b.

As shown in FIG. 6, the upper surface 1 of the recording head 1
The cleaning mechanism 40 for cleaning a
A pair of rollers 41 and 42 separated from each other in the sub-scanning direction of the recording head 1, a belt 44 wound and stretched around the pair of rollers 41 and 42, and a recording head fixed to the belt 44. 1 has a cleaning unit 45 facing the upper surface 1a, and a drive motor (not shown) for rotating one of the rollers to move the belt 44 in the sub-scanning direction.

The cleaning unit 45 is a cleaning member that is disposed in contact with both ends of the head upper surface 1a in the sub-scanning direction while being moved to a closed position indicated by a solid line in the drawing facing the upper surface 1a of the recording head 1. It has a pair of sponges 46 and 48. This cleaning unit 4
5 is moved to a retracted position indicated by a broken line in the drawing during a normal recording operation in which the cleaning operation is not performed. At the end of the recording operation, it is moved to the closing position.

When the belt 44 runs and the cleaning unit 45 is moved in the sub-scanning direction, the pair of sponges 46 and 48 are brought into sliding contact with the upper surface 1a of the recording head 1, and the upper surface 1a near the slit 10 is moved. The paper dust and dust attached to the surface are cleaned. When the cleaning unit 45 is moved to the closing position, the upper surface 1a of the recording head 1 is closed by the cleaning unit 45, so that evaporation of the ink can be suppressed and dust can be prevented from adhering near the slit.

The present invention is not limited to the above-described embodiment, but can be variously modified within the scope of the present invention. For example, in the above-described embodiment, an example in which a sponge is used as the cleaning member has been described, but a brush or the like may be used instead of the sponge.

[0049]

As described above, since the recording head of the present invention has the above-described structure and operation, the head upper surface can be cleaned well without undesirably wasting ink. Stable recording characteristics can be obtained.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a recording head and its peripheral members according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view in which the recording head of FIG. 1 is partially exploded.

3 is an operation explanatory diagram for explaining the principle of ejecting ink droplets in the recording head of FIG. 1;

FIG. 4 is a schematic diagram illustrating a state of a recording head during a recording operation.

FIG. 5 is a schematic diagram illustrating a state of a recording head during a non-recording operation.

FIG. 6 is a diagram for explaining an operation of a cleaning mechanism of the recording head.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Recording head, 1a ... Upper surface, 2 ... Platen roller, 4 ... Ink tank, 6 ... Supply tube, 10 ... Slit, 11 ... Ink chamber member, 12 ... Base material, 12b ... Ink supply hole, 13 ... Leader electrode, 14: Individual electrode, 15: Piezoelectric element, 16: Piezoelectric body, 17: Common electrode, 18: Bonding wire, 19: Drive IC, 20: Lens member, 20a: Lens groove, 30: Lifting mechanism, 40: Cleaning mechanism, P: Recording paper.

Claims (6)

[Claims] 1. A storage container having an upper surface formed with a slit extending along a horizontal plane separated by a predetermined distance below a recording medium, and storing a recording liquid such that the liquid surface is held by the slit. A recording liquid supply / recovery unit for supplying a recording liquid to the storage container and holding the liquid surface in the slit, collecting the recording liquid from the storage container, and lowering the liquid surface held in the slit, A sound wave generator that is provided in the storage container and generates a sound wave based on an image signal propagated through the recording liquid toward the slit; and focuses the sound wave generated by the sound wave generator on the center of the slit. And a sound wave converging means for discharging a recording liquid from the slit toward the recording medium. When cleaning the upper surface on which the slit is formed, the recording liquid supply / recovery means It is recovered part of the recording liquid supplied to the accommodation container, a recording head, characterized in that to lower the liquid level held at the slit. 2. A storage container having an upper surface formed with a slit extending along a horizontal plane separated from the recording medium by a predetermined distance below the recording medium, and storing the recording liquid so that the liquid surface is held by the slit. A tank connected to the storage container through a pipe and storing a recording liquid to be supplied to the storage container, a first position for supplying the recording liquid from the tank to the storage container and holding the liquid surface at the slit; Raising and lowering the tank relative to the storage container between a second position for collecting a part of the recording liquid from the storage container to the tank and lowering the liquid surface held by the slit; Elevating means for causing, a sound wave generating means provided at the bottom of the storage container and generating a sound wave based on an image signal propagated in the recording liquid toward the slit, and a sound wave generated by the sound wave generating means Pickpocket A focusing means for focusing on the center of the recording medium and discharging the recording liquid from the slit toward the recording medium; and a cleaning means for cleaning foreign substances adhering near the slit by sliding a cleaning member on the upper surface of the container. The cleaning means, wherein the tank is lowered to the second position by the elevating means, and a part of the recording liquid supplied to the storage container is collected in the tank, and is held by the slit. And a cleaning member slidably contacting the upper surface of the container while the liquid level is lowered to clean the upper surface. 3. An upper surface formed with a slit extending in a first direction transverse to a direction in which the recording medium is conveyed along a horizontal plane separated by a predetermined distance below a recording medium conveyed in a substantially horizontal direction. A storage container that stores the recording liquid such that the liquid surface is held by the slit, and a recording liquid that is provided adjacent to the storage container, communicates with the storage container through a supply pipe, and supplies the recording liquid to the storage container. A storage tank, a first position for supplying the recording liquid from the tank to the storage container via the supply pipe and holding the liquid level at the slit, and a storage tank to the tank via the supply pipe. Lifting means for raising and lowering the tank relative to the storage container between a second position for collecting a part of the recording liquid and lowering the liquid surface held by the slit; The first part on the bottom of the container And a sound wave generator that generates a sound wave propagating in the recording liquid toward the slit based on an image signal, and is provided on the sound wave generating means. A plurality of grooves that are exposed and extend in the first direction, and the sound waves generated by the sound wave generating means are directed toward the center of the slit by the action of the grooves in a direction orthogonal to the first direction. A focusing means for focusing in the direction 2 and discharging a recording liquid from the slit toward the recording medium; and a cleaning means for cleaning foreign substances adhering in the vicinity of the slit by sliding a cleaning member on the upper surface of the storage container. A second position at which the tank is lowered by the lifting / lowering means is set to a height at which a recording liquid is not recovered from the plurality of grooves of the sound wave focusing means; In the cleaning means, the tank is lowered to the second position by the elevating means, a part of the recording liquid supplied to the storage container is collected in the tank, and the liquid surface held by the slit is lowered. In this state, a cleaning member slides on an upper surface of the storage container to clean the upper surface. 4. The height position of the tank is adjusted by detecting the level of the liquid level of the recording liquid stored in the tank and operating the lifting / lowering means. 3. The recording head according to 3. 5. An upper surface having a slit formed in a first direction transverse to a conveying direction of the recording medium along a horizontal plane separated by a predetermined distance below the recording medium conveyed in a substantially horizontal direction. A storage container that stores the recording liquid such that the liquid surface is held by the slit, and a recording liquid that is provided adjacent to the storage container, communicates with the storage container through a supply pipe, and supplies the recording liquid to the storage container. A storage tank, a first position for supplying the recording liquid from the tank to the storage container via the supply pipe and holding the liquid level at the slit, and a storage tank to the tank via the supply pipe. Lifting means for raising and lowering the tank relative to the storage container between a second position for collecting a part of the recording liquid and lowering the liquid surface held by the slit; The first part on the bottom of the container And a sound wave generator that generates a sound wave propagating in the recording liquid toward the slit based on an image signal, and is provided on the sound wave generating means. A plurality of grooves extending in the first direction on the exposed upper surface;
The sound wave generated by the sound wave generating means is focused by the action of the groove toward the center of the slit in a second direction orthogonal to the first direction, and the recording liquid is directed from the slit toward a recording medium. A second means for ejecting a sound wave focusing means, and a cleaning means for cleaning foreign matter attached near the slit by sliding a cleaning member on the upper surface of the storage container, wherein the elevating means lowers the tank. The position is such that the recording liquid filled between the upper surface of the sound wave focusing means and the upper surface of the storage container is separated from the recording liquid stored in the tank by the air flowing through the slit. The cleaning unit is set at a height, and the storage container is moved down to the second position by the elevating unit to separate the recording liquid. Recording head is characterized in that the upper surface is brought into sliding contact with the cleaning member and to clean the upper surface. 6. An upper surface formed with a slit extending in a first direction transverse to a conveying direction of the recording medium along a horizontal plane separated by a predetermined distance below a recording medium conveyed in a substantially horizontal direction, A storage container for storing the recording liquid such that the liquid surface is held by the slit; and a storage tube provided adjacent to the storage container and connected to a supply pipe connected to a hole formed at the bottom of the storage container. A tank communicating with the container and storing the recording liquid to be supplied to the storage container; a first position for supplying the recording liquid from the tank to the storage container via the supply pipe and holding the liquid surface at the slit; And a second position for recovering a part of the recording liquid from the storage container to the tank via the supply pipe and lowering the liquid surface held by the slit, and the storage container Raise and lower relative to Elevating means, a sound wave which extends along the first direction at a position on the bottom of the storage container and which is separated from the hole to which the supply pipe is connected, and which propagates in the recording liquid toward the slit. And a plurality of grooves extending in the first direction on the upper surface exposed to the recording liquid, the plurality of grooves being provided on the sound wave generating means and being provided on the sound wave generating means.
The sound wave generated by the sound wave generating means is focused by the action of the groove toward the center of the slit in a second direction orthogonal to the first direction, and the recording liquid is directed from the slit toward a recording medium. A sound wave focusing means for discharging, and a cleaning means for cleaning foreign matter adhered in the vicinity of the slit by sliding a cleaning member on the upper surface of the container, wherein a hole formed at the bottom of the container is A second position where the tank is lowered by the lifting / lowering means is formed at a position facing one end of a slit formed on the upper surface of the storage container, and is located between the upper surface of the sound wave focusing means and the upper surface of the storage container. The recording liquid filled into the slit is separated from the recording liquid stored in the tank by air flowing into the hole through one end of the slit. Wherein the cleaning means slides a cleaning member on the upper surface of the storage container to clean the upper surface in a state where the tank is lowered to the second position by the elevating means and the recording liquid is divided. A recording head characterized by the above-mentioned.