JP7297959B2 - Inkjet head and inkjet printer - Google Patents

Description

TECHNICAL FIELD Embodiments of the present invention relate to inkjet heads and inkjet printers.

For example, in an inkjet head that pressurizes ink with a piezoelectric element to eject ink droplets from nozzles provided on a nozzle plate, the surface of the nozzle plate is imparted with ink repellency so that ink does not adhere. In order to impart ink repellency to the surface of the nozzle plate, an oil-repellent film is formed on the surface of the nozzle plate substrate by forming a film of a fluorine-based compound by a coating method or a vapor deposition method (Patent Document 1). .

For cleaning the inkjet head, a wiping blade is moved on the surface of the nozzle plate facing the recording medium to remove the ink.

JP 2007-106024 A

For example, cleaning with a wiping blade may deteriorate the ink repellency of the nozzle plate surface.

SUMMARY OF THE INVENTION An object of the present invention is to provide an inkjet head with little deterioration of ink repellency, and an inkjet printer equipped with such an inkjet head.

The inkjet head of the embodiment includes a nozzle plate provided with nozzles for ejecting ink toward a recording medium. The nozzle plate includes a nozzle plate substrate and an oil-repellent film provided on the surface of the nozzle plate substrate facing the recording medium.
The oil-repellent film contains a fluorine-based compound crosslinked between adjacent molecules in a direction parallel to the surface of the nozzle plate substrate facing the recording medium, and has a reflection spectrum of 0.7 to 1 in a reflection spectrum obtained by terahertz time domain spectroscopy. The frequency change before and after rubbing of the peak showing the maximum intensity in the frequency band of 0.4 THz is 0.2 THz or less.
Here, "change in frequency before and after rubbing" means change in frequency between the state of no rubbing and the state after rubbing 6000 times with a load of 13 gf with a rubber wiping blade.
The fluorine-based compound has a bonding site bonded to the nozzle plate substrate and a terminal perfluoroalkyl group. Adjacent fluorine-based compounds are cross-linked by mutually bonding bonding sites.
The fluorine compound further has a spacer linking group between the binding site and the terminal perfluoroalkyl group.
The spacer linking group is a perfluoropolyether group.
The terminal perfluoroalkyl group is a linear perfluoroalkyl group having 3 to 7 carbon atoms.

1 is a perspective view showing an inkjet head according to an embodiment; FIG. 2 is an exploded perspective view showing an actuator substrate, a frame, and a nozzle plate that constitute the inkjet head according to the embodiment; FIG. 1 is a schematic diagram showing an inkjet printer according to an embodiment; FIG. 1 is a perspective view showing a main part of an inkjet printer according to an embodiment; FIG. 4 is a schematic diagram showing the structure of an oil-repellent film included in the inkjet head according to the embodiment; FIG. FIG. 4 is a schematic diagram showing a surface bonding state when the oil-repellent film according to the embodiment is rubbed. FIG. 5 is a schematic diagram schematically showing a surface bonding state before rubbing an oil-repellent film according to a comparative example; FIG. 7B is a schematic diagram schematically showing a surface bonding state after rubbing the oil-repellent film shown in FIG. 7A; FIG. 5 is a diagram showing XPS spectra obtained on the surface of the oil-repellent film before and after rubbing the nozzle plate of the comparative example with a wiping blade once. FIG. 4 shows XPS spectra obtained on the surface of the oil-repellent film before and after rubbing the nozzle plate of the example with a wiping blade 6000 times. The graph which shows an example of the time waveform of the oscillating electric field of a terahertz pulse wave. 5 is a graph showing reflection spectra obtained for an oil-repellent film before and after rubbing a nozzle plate of a comparative example with a wiping blade 6000 times. 5 is a graph showing reflection spectra obtained for an oil-repellent film before and after rubbing the nozzle plate of the example with a wiping blade 6000 times. FIG. 5 is a diagram showing the relationship between the number of times the nozzle plate is rubbed with a wiping blade and the speed at which the nozzle plate repels ink, obtained for the nozzle plates of Examples and Comparative Examples.

Hereinafter, embodiments will be described with reference to the drawings.
FIG. 1 is a perspective view showing an on-demand type inkjet head 1 used by being mounted on a head carriage of an inkjet printer, according to an embodiment. In the following description, an orthogonal coordinate system consisting of X-, Y-, and Z-axes is used. For the sake of convenience, the direction indicated by the arrow in the drawing is the positive direction. The X-axis direction corresponds to the print width direction. The Y-axis direction corresponds to the direction in which the recording medium is conveyed. The positive direction of the Z axis is the direction facing the recording medium.

Schematically described with reference to FIG. 1, the ink jet head 1 includes an ink manifold 10, an actuator substrate 20, a frame 40 and a nozzle plate 50. As shown in FIG.

The actuator substrate 20 has a rectangular shape whose longitudinal direction is the X-axis direction. Examples of materials for the actuator substrate 20 include alumina (Al ₂ O ₃ ), silicon nitride (Si ₃ N ₄ ), silicon carbide (SiC), aluminum nitride (AlN), and lead zirconate titanate (PZT: Pb(Zr, Ti)O ₃ ) and the like.

The actuator substrate 20 is superimposed on the ink manifold 10 so as to close the open end of the ink manifold 10 . The ink manifold 10 is connected to the ink cartridges via an ink supply pipe 11 and an ink return pipe 12 .

A frame 40 is attached on the actuator substrate 20 . A nozzle plate 50 is mounted on the frame 40 . A plurality of nozzles N are provided on the nozzle plate 50 at predetermined intervals along the X-axis direction so as to form two rows along the Y-axis.

FIG. 2 is an exploded perspective view of the actuator substrate 20, the frame 40 and the nozzle plate 50 that constitute the inkjet head 1 according to the embodiment. The inkjet head 1 is of a so-called shear mode shared wall side shooter type.

A plurality of ink supply ports 21 are provided in the actuator substrate 20 at intervals along the X-axis direction so as to form a row in the central portion in the Y-axis direction. Also, in the actuator substrate 20, a plurality of ink discharge ports 22 are spaced apart along the X-axis direction so as to form columns in the Y-axis plus direction and the Y-axis minus direction with respect to the columns of the ink supply ports 21. It is set open.

A plurality of actuators 30 are provided between the central row of ink supply ports 21 and one row of ink discharge ports 22 . These actuators 30 form a row extending in the X-axis direction. A plurality of actuators 30 are also provided between the row of the central ink supply ports 21 and the row of the other ink discharge ports 22 . These actuators 30 also form a row extending in the X-axis direction.

Each row of actuators 30 is composed of a first piezoelectric body and a second piezoelectric body laminated on the actuator substrate 20 . Examples of materials for the first and second piezoelectric bodies include lead zirconate titanate (PZT), lithium niobate (LiNbO ₃ ), and lithium tantalate (LiTaO ₃ ). The first and second piezoelectric bodies are polarized in opposite directions along the thickness direction.

A plurality of grooves extending in the Y-axis direction and arranged in the X-axis direction are provided in the laminate composed of the first and second piezoelectric bodies. These grooves are open on the side of the second piezoelectric body and have a depth greater than the thickness of the second piezoelectric body. Hereinafter, a portion of this laminate sandwiched between adjacent grooves will be referred to as a channel wall. These channel walls each extend in the Y-axis direction and are aligned in the X-axis direction. A groove between two adjacent channel walls is an ink channel through which ink flows.

Electrodes are formed on the sidewalls and bottom of the ink channel. These electrodes are connected to a wiring pattern 31 extending along the Y-axis direction.

A protective film (not shown) is formed on the surface of the actuator substrate 20 including the electrodes and the wiring pattern 31 except for the connection portion with the flexible printed circuit board, which will be described later. The protective film includes, for example, multiple layers of inorganic insulating films and organic insulating films.

Frame 40 has an opening. This opening is smaller than the actuator substrate 20 and larger than the area of the actuator substrate 20 where the ink supply port 21, the actuator 30, and the ink discharge port 22 are provided. The frame 40 is made of ceramics, for example. The frame 40 is bonded to the actuator substrate 20 with an adhesive, for example.

The nozzle plate 50 includes a nozzle plate substrate and an oil-repellent film provided on its medium facing surface (ejection surface for ejecting ink from the nozzles N). The nozzle plate substrate is made of, for example, a resin film such as a polyimide film. The oil-repellent film will be detailed later.

Nozzle plate 50 is larger than the opening of frame 40 . The nozzle plate 50 is joined to the frame 40 by, for example, an adhesive.

A plurality of nozzles N are provided on the nozzle plate 50 . These nozzles N form two columns corresponding to the ink channels. The diameter of the nozzle N increases in the direction of the ink channel from the surface facing the recording medium. The dimension of the nozzle N is set to a predetermined value according to the ink ejection amount. The nozzle N can be formed, for example, by performing laser processing using an excimer laser.

The actuator substrate 20, frame 40 and nozzle plate 50 are integrated as shown in FIG. 1 to form a hollow structure. A region surrounded by the actuator substrate 20, the frame 40 and the nozzle plate 50 is an ink circulation chamber. Ink is supplied from the ink manifold 10 through the ink supply port 21 to the ink circulation chamber, passes through the ink channels, and surplus ink is circulated back to the ink manifold 10 through the ink outlet 22 . A portion of the ink is ejected from the nozzle N and used for printing while flowing through the ink channel.

A flexible printed board 60 is connected to the wiring pattern 31 at a position on the actuator board 20 and outside the frame 40 . A drive circuit 61 for driving the actuator 30 is mounted on the flexible printed circuit board 60 .

The operation of the actuator 30 will be described below. Here, the operation will be described focusing on the central ink channel among the three adjacent ink channels. Let A, B and C be the electrodes corresponding to three adjacent ink channels. When no electric field is applied perpendicular to the channel wall, the channel wall is in an upright state.

For example, a voltage pulse is applied to the central electrode B with a potential higher than that of the adjacent electrodes A and C to generate an electric field perpendicular to the channel walls. Thus, the channel walls are driven in a shear mode and the pair of channel walls sandwiching the central ink channel are deformed to expand the volume of the central ink channel.

Next, a voltage pulse with a potential higher than that of the central electrode B is applied to the adjacent electrodes A and C to generate an electric field perpendicular to the channel wall. Thus, the channel walls are driven in shear mode and the pair of channel walls sandwiching the central ink channel are deformed to reduce the volume of the central ink channel. By this operation, pressure is applied to the ink in the central ink channel, and the ink is ejected from the nozzle N corresponding to this ink channel and landed on the recording medium.

For example, all the nozzles are divided into three groups, and the driving operation described above is performed in three cycles by time-division control to print on a recording medium.

FIG. 3 shows a schematic diagram of the inkjet printer 100. As shown in FIG. The inkjet printer 100 shown in FIG. 3 includes a housing in which a paper output tray 118 is provided. Cassettes 101a and 101b, paper feed rollers 102 and 103, transport roller pairs 104 and 105, registration roller pair 106, transport belt 107, fan 119, negative pressure chamber 111, transport roller pairs 112, 113 and 114, Inkjet heads 115C, 115M, 115Y and 115Bk, ink cartridges 116C, 116M, 116Y and 116Bk, and tubes 117C, 117M, 117Y and 117Bk are installed.

The cassettes 101a and 101b accommodate recording media P of different sizes. The paper feed roller 102 or 103 takes out the recording medium P corresponding to the size of the selected recording medium from the cassette 101a or 101b and conveys it to the conveying roller pairs 104 and 105 and the registration roller pair .

The transport belt 107 is tensioned by a driving roller 108 and two driven rollers 109 . Holes are provided at predetermined intervals on the surface of the transport belt 107 . A negative pressure chamber 111 connected to a fan 119 is installed inside the transport belt 107 to attract the recording medium P to the transport belt 107 . Conveying roller pairs 112 , 113 and 114 are installed downstream of the conveying belt 107 in the conveying direction. A heater for heating the print layer formed on the recording medium P can be installed on the transport path from the transport belt 107 to the discharge tray 118 .

Four inkjet heads for ejecting ink onto the recording medium P according to image data are arranged above the transport belt 107 . Specifically, an inkjet head 115C that ejects cyan (C) ink, an inkjet head 115M that ejects magenta (M) ink, an inkjet head 115Y that ejects yellow (Y) ink, and an inkjet head 115Y that ejects black (Bk) ink. The inkjet heads 115Bk are arranged in this order from the upstream side. Each of the inkjet heads 115C, 115M, 115Y and 115Bk is the inkjet head 1 described with reference to FIGS.

Above the inkjet heads 115C, 115M, 115Y and 115Bk are cyan (C) ink cartridges 116C, magenta (M) ink cartridges 116M, yellow (Y) ink cartridges 116Y and black ink cartridges 116C and 116M, respectively. (Bk) An ink cartridge 116Bk is installed. These cartridges 116C, 116M, 116Y and 116Bk are connected to inkjet heads 115C, 115M, 115Y and 115Bk by tubes 117C, 117M, 117Y and 117Bk, respectively.

Next, the image forming operation of this inkjet printer 100 will be described.
First, an image processing means (not shown) starts image processing for recording, generates an image signal corresponding to the image data, and generates a control signal for controlling the operation of various rollers, the negative pressure chamber 111, and the like. do.

The paper feeding rollers 102 or 103 take out the recording medium P of the selected size one by one from the cassette 101a or 101b under the control of the image processing means, and convey them to the conveying roller pairs 104 and 105 and the registration roller pair 106. do. The registration roller pair 106 corrects the skew of the recording medium P and conveys the recording medium P at a predetermined timing.

The negative pressure chamber 111 sucks air through holes in the conveyor belt 107 . Accordingly, the recording medium P is conveyed to positions below the inkjet heads 115C, 115M, 115Y and 115Bk in sequence as the conveying belt 107 moves while being attracted to the conveying belt 107 .

The inkjet heads 115C, 115M, 115Y and 115Bk eject ink in synchronization with the timing at which the recording medium P is conveyed under the control of the image processing means. Thus, a color image is formed at a desired position on the recording medium P. FIG.

Thereafter, conveying roller pairs 112 , 113 and 114 discharge the recording medium P on which the image is formed to a paper discharge tray 118 . When a heater is installed in the transport path from the transport belt 107 to the discharge tray 118, the print layer formed on the recording medium P may be heated by the heater. Heating by the heater can improve the adhesion of the print layer to the recording medium P, especially when the recording medium P is impermeable.

FIG. 4 shows a perspective view of the essential parts of the inkjet printer 100. As shown in FIG. FIG. 4 depicts the inkjet head 1, the medium holding mechanism 110, the head moving mechanism 120, the blade moving mechanism 130, and the wiping blade 140 described above.

The medium holding mechanism 110 holds a recording medium P, such as a recording sheet, facing the inkjet head 1 . The medium holding mechanism 110 also functions as a recording paper moving mechanism for moving the recording medium. Media holding mechanism 110 includes transport belt 107, drive roller 108, driven roller 109, vacuum chamber 111, and fan 119 of FIG. During printing, the medium holding mechanism 110 moves the recording medium P in a direction parallel to the printing surface of the recording medium P while facing the inkjet head 1 . In the meantime, the inkjet head 1 prints on the recording medium P by ejecting ink droplets from the nozzles.

The head moving mechanism 120 moves the inkjet head 1 to the printing position during printing. Further, the head moving mechanism 120 moves the inkjet head 1 to the cleaning position during cleaning.

The wiping blade 140 wipes the recording medium facing surface of the nozzle plate of the inkjet head 1 to remove the ink from this recording medium facing surface.

Blade moving mechanism 130 moves wiping blade 140 . Specifically, after the head moving mechanism 120 moves the inkjet head 1 to the cleaning position, the blade moving mechanism 130 presses the wiping blade 140 against the recording medium facing surface of the nozzle plate 50 and moves thereon. Let As a result, ink adhering to the surface of the nozzle plate 50 facing the recording medium is removed.
Note that the wiping blade 140 and the blade moving mechanism 130 may be omitted.

In the above-described inkjet head 1, the medium facing surface of the nozzle plate 50 is given oil repellency. In order to impart oil repellency, an oil repellent film containing a fluorine-based compound is provided on the medium facing surface of the nozzle plate substrate.

The oil-repellent film according to the embodiment contains a fluorine-based compound crosslinked between adjacent molecules in a direction parallel to the medium facing surface of the nozzle plate substrate, and has a structure in which the surface bonding state does not change due to rubbing.
Alternatively, the oil-repellent film according to the embodiment contains a fluorine-based compound crosslinked between adjacent molecules in a direction parallel to the medium facing surface of the nozzle plate substrate, and has a reflection spectrum obtained by terahertz time-domain spectroscopy with 0.0. The frequency change before and after rubbing of the peak showing the maximum intensity in the frequency band of 7 to 1.4 THz is 0.2 THz or less.
Such an oil-repellent film is less likely to deteriorate in ink repellency. The reason will be explained below.

FIG. 5 schematically shows the structure of the oil-repellent film 52 bonded to the medium facing surface of the nozzle plate substrate 51 according to the embodiment.

The fluorine-based compound used in the embodiment has a bonding site bonded to the nozzle plate substrate and a terminal perfluoroalkyl group. For example, this fluorine-based compound is a linear molecule having a binding site at one end and a perfluoroalkyl group at the other end.

The bonding site is, for example, a site bonded to the nozzle plate substrate by reaction with a functional group present on the surface of the nozzle plate substrate. Binding sites include, for example, reactive functional groups. In this case, the binding site is bound to the nozzle plate substrate by reacting the reactive functional group with the functional group present on the surface of the nozzle plate substrate. Reactive functional groups are, for example, epoxy groups, amino groups, methacryl groups, unsaturated hydrocarbon groups such as vinyl groups, or mercapto groups. Functional groups present on the surface of the nozzle plate substrate are, for example, hydroxyl groups, ester bonds, amino groups, or thiol groups. Alternatively, the binding site is an alkoxysilane group. In this case, a silanol group produced by hydrolysis of the alkoxysilane group reacts with a functional group such as a hydroxyl group present on the surface of the nozzle plate substrate, thereby bonding the binding site to the nozzle plate substrate.

Adjacent fluorine-based compounds on the nozzle plate substrate are bonded to each other at their bonding sites. According to one example, the bonding site further includes one or more silicon atoms between the reactive functional group and the terminal perfluoroalkyl group, and adjacent fluorine-based compounds on the nozzle plate substrate are siloxane bonded at the bonding site. They are connected to each other by (Si--O--Si).

A terminal perfluoroalkyl group is, for example, a linear perfluoroalkyl group. The number of carbon atoms in the terminal perfluoroalkyl group can be selected, for example, within the range of 3 to 7 (C3 to C7). It is preferred that the terminal perfluoroalkyl groups stand upright along the direction perpendicular to the nozzle plate substrate.

This fluorine-based compound may further have a spacer linking group between the bonding site with the nozzle plate substrate and the terminal perfluoroalkyl group. The presence of such a spacer linking group is advantageous in that the terminal perfluoroalkyl group adopts a structure that stands upright along the direction perpendicular to the nozzle plate substrate. Spacer linking groups are, for example, perfluoropolyether groups.

Examples of such fluorine compounds include compounds represented by the following general formulas (1) and (2).

In general formula (1), p is a natural number of 1 to 50, and n is a natural number of 1 to 10.

In general formula (2), p is a natural number from 1 to 50.

FIG. 5 schematically shows the structure of the oil-repellent film 52 bonded to the medium facing surface of the nozzle plate substrate 51 according to the embodiment.

This structure is obtained, for example, as follows. Here, as an example, hydroxyl groups are present on the medium facing surface of the nozzle plate substrate 51, and the fluorine-based compound includes an alkoxysilane group at the binding site.

Hydrolysis of the alkoxysilane group of the fluorine-based compound produces a silanol group. This silanol group and a hydroxyl group existing on the medium facing surface of the nozzle plate substrate 51 cause dehydration condensation. In this way, the nozzle plate substrate 51 and the fluorine-based compound are bonded through the siloxy groups (Si—O—) of the silicon atoms contained in the bonding sites 53 . Adjacent fluorine-based compounds are bonded to each other by siloxane bonds (Si--O--Si) at the silicon atoms of the bonding sites 53. As shown in FIG.
As a result, the joint portion 53 forms a horizontal bridge structure with respect to the medium facing surface of the nozzle plate substrate 51 .

A terminal perfluoroalkyl group 55 is bonded to the silicon atom of the bonding site 53 via a perfluoropolyether group as a spacer linking group 54 . The spacer linking group 54 has the function of making the terminal perfluoroalkyl group 55 stand upright along the direction perpendicular to the nozzle plate substrate 51, as described above. The terminal perfluoroalkyl group 55 mainly exerts ink repellency. Also, when _the terminal perfluoroalkyl group 55 _has 3 carbon atoms (C3), for example, it is expressed as CF ₃ —CF ₂ —CF ₂ —. higher than base.

In the structure shown in FIG. 5, the terminal perfluoroalkyl group 55 stands upright along the direction perpendicular to the nozzle plate substrate 51 . In such a structure, even if cleaning by the wiping blade 140 is repeated, the terminal perfluoroalkyl groups 55 only sway in the lateral direction and do not disappear from the surface of the oil-repellent film 52 .

This is believed to be due to the reasons explained below with reference to FIGS. 6 and 7A and 7B. FIG. 6 is a schematic diagram schematically showing a surface bonding state when the oil-repellent film according to the embodiment is rubbed. FIG. 7A is a schematic diagram schematically showing a surface bonding state before rubbing an oil-repellent film according to a comparative example. FIG. 7B is a schematic diagram schematically showing the state of surface bonding after rubbing the oil-repellent film shown in FIG. 7A.
6, 7A and 7B, the upper side of the paper represents the surface side of the oil-repellent film, and the lower side of the paper represents the nozzle plate substrate 51 side.
Here, the surface bonding state represents the type and proportion of chemical bonds present on the surface of the oil-repellent film, that is, the type and proportion of functional groups present on the surface of the oil-repellent film.

In the structure shown in FIG. 6, perfluoroalkyl groups are present near the surface of the oil-repellent film 52 . A film made of a fluorine-based compound containing a perfluoroalkyl group is relatively soft, and rubbing such a film may cause a conformational change of the perfluoroalkyl group. However, a perfluoroalkyl group can undergo a conformational change that rotates about an axis parallel to its length, as indicated by arrow AR1 in FIG. In addition, even if other conformational changes occur, functional groups with excellent oil repellency existing on the outermost surface of the oil-repellent film 52, that is, CF ₃ groups and CF ₂ groups, will not be significantly reduced. . In this way, the oil-repellent film 52 having the structure shown in FIG. 6 has a structure in which the surface bonding state does not change due to abrasion.

On the other hand, in the structure shown in FIG. 7A, the outermost surface of the oil-repellent film has functional groups with excellent oil repellency, such as CF ₂ O groups. However, when such an oil-repellent film is rubbed, the heterocyclic portion rotates in the direction indicated by arrow AR2 in FIG. 7A. That is, the conformation changes as shown in FIG. 7B. Note that once the conformation changes, this state is more stable, so the surface binding state will not return to the structure shown in FIG. 7A no matter how many times the oil-repellent film is rubbed. In the structure shown in FIG. 7B, functional groups with excellent oil repellency, that is, CF ₂ O groups, present on the outermost surface of the oil-repellent film are smaller than in the structure shown in FIG. 7A. Thus, the oil-repellent film having the structure shown in FIG. 7A has a structure in which the surface bonding state changes due to rubbing.
For the reasons described above, the oil-repellent film according to the embodiment does not deteriorate in ink repellency due to abrasion.

The surface binding state described above can be examined, for example, by the following method. That is, the element bonding state of the oil-repellent film formed on the surface of the nozzle plate facing the recording medium can be analyzed by, for example, X-ray photoelectron spectroscopy (XPS).

The principle of XPS is as follows. When a substance is irradiated with soft X-rays of several keV, electrons in atomic orbitals absorb light energy and are ejected as photoelectrons. The following relationship exists between the binding energy E _b of bound electrons and the kinetic energy E _k of photoelectrons.

E _b = hν−E _k −ψ _sp
where hν is the incident X-ray energy and _ψsp is the work function of the spectrometer.
Therefore, if the X-ray energy is constant (that is, has a single wavelength), the electron binding energy _Eb can be obtained based on the photoelectron kinetic energy _Ek . Since the electron binding energy _Eb is unique to each element, elemental analysis can be performed. In addition, since the shift in binding energy reflects the chemical bonding state and valence state (oxidation number, etc.) of the element, the chemical bonding state of the constituent elements can be investigated.

As shown in FIG. 5, when the terminal perfluoroalkyl group 55 has a structure that stands upright along the direction perpendicular to the nozzle plate substrate 51, the CF ₃ groups are present on the outermost surface of the oil-repellent film 52. There are two CF ₂ groups on the nozzle plate substrate 51 side.

When the oil-repellent film 52 is analyzed by an X-ray photoelectron spectroscopy (XPS) method, a CF ₂ group peak and a CF ₃ group peak are detected.

The analysis of the surface bonding state of the oil-repellent film by the XPS method involves destruction of the sample. In order to investigate changes in the surface bonding state of the oil-repellent film formed on the surface facing the recording medium of the nozzle plate without destroying the sample, for example, Terahertz Time-Domain Spectroscopy (THz-TDS) method is used. It is possible to analyze by According to this method, it is possible to non-destructively analyze the change in surface bonding state of the same oil-repellent film before and after rubbing.

Specifically, for both the unrubbed oil-repellent film and the rubbed oil-repellent film, terahertz time-domain spectroscopy is used to obtain reflection spectra. Then, by comparing these reflection spectra, changes in the surface bonding state of the oil-repellent film are confirmed.
Acquisition of reflectance spectra using terahertz time domain spectroscopy is described below.

First, a beam splitter splits a light pulse emitted by a femtosecond laser into pump light and probe light.
The pump light is guided to the terahertz wave generation element. The terahertz wave generation element generates a terahertz pulse wave. This terahertz pulse wave is guided to the sample, and the terahertz pulse wave reflected by this sample is guided to the detection element.
On the other hand, the probe light is guided to the detection element mentioned above. A movable mirror is installed on the optical path that guides the probe light. The time waveform of the oscillating electric field of the terahertz pulse wave is measured while changing the timing at which the probe light reaches the detection element by moving this movable mirror.

FIG. 10 is a graph showing an example of the temporal waveform of the oscillating electric field of the terahertz pulse wave thus obtained. In the figure, the horizontal axis represents time, and the vertical axis represents the strength of the oscillating electric field of the terahertz pulse wave.

In the temporal waveform of the oscillating electric field of the terahertz pulse wave, the peak that appears first reflects the state near the outermost surface of the sample. Also, the second peak that appears reflects the state in the vicinity of the second interface when the outermost surface of the sample is defined as the first interface. Therefore, here, of the temporal waveform of the oscillating electric field of the terahertz pulse wave, the portion including the first and second peaks is used for analysis. That is, the reflection spectrum is obtained by Fourier transforming the region R shown in FIG.
For example, TAS7500SP (Advantest) can be used to acquire the reflection spectrum.

The reflection spectrum obtained for the oil-repellent film before rubbing and the reflection spectrum obtained for the oil-repellent film after rubbing are compared in the following manner.
First, for each of these reflectance spectra, the peak exhibiting the maximum intensity in the frequency band from 0.7 to 1.4 THz is identified. A reflection spectrum obtained from an oil-repellent film in which most of the groups existing on the outermost surface are perfluoroalkyl groups has a peak in the frequency band of 0.7 to 1.4 THz.

Next, the difference between the frequency of the peak specified in the reflection spectrum obtained for the oil-repellent film before rubbing and the frequency of the peak specified for the reflection spectrum obtained for the oil-repellent film after rubbing is determined. If the absolute value of this difference, that is, the change in frequency is 0.2 THz or less, it is determined that the surface bonding state of the oil-repellent film did not change before and after rubbing.
The change in frequency of the peak showing the maximum intensity before and after rubbing is preferably 0.2 THz or less, more preferably 0.1 THz or less. If the change in the frequency of the peak showing the maximum intensity in the frequency band of 0.7 to 1.4 THz in the reflection spectrum before and after rubbing is too great, there is a risk that the ink repellency will be greatly deteriorated due to rubbing. Such a significant change in frequency suggests that rotation similar to that described above occurred within the oil-repellent film.

Examples are described below.

Comparative Example First, Cytop (registered trademark: A type) manufactured by Asahi Glass Co., Ltd. represented by the following chemical formula was prepared as a material for an oil-repellent film in a comparative example. This oil-repellent film material is a fluorine-based compound and has terminal groups containing alkoxysilane groups at both ends of a polymer main chain represented by the following chemical formula.

The above oil-repellent film material was applied to the surface of the nozzle plate substrate, and both terminal groups of the fluorine-based compound were allowed to react with the hydroxyl groups on the surface of the nozzle plate substrate. Thus, a nozzle plate was produced by bonding the fluorine-based compound to the surface of the nozzle plate substrate.

Hydroxyl groups are present on the medium facing surface of the nozzle plate substrate. Both terminal groups of the fluorine-based compound are bonded to hydroxyl groups to form binding sites. Between the two binding sites is a fluoropolymer backbone. In this fluorine-based compound, the CF ₂ O group in the main chain of the polymer mainly exhibits ink repellency.

However, it has been found that the ink repellency deteriorates when the wiping blade 140 rubs the oil-repellent film formed on the medium facing surface of the nozzle plate substrate in this way.

FIG. 8 shows the X-ray photoelectron spectroscopy (XPS) spectra obtained for the surface of the oil-repellent film before cleaning the nozzle plate of the comparative example with a wiping blade (before rubbing) and after cleaning once (after rubbing once). show. In FIG. 8, the horizontal axis is the binding energy, and the vertical axis is the intensity of emitted photoelectrons.

The results in FIG. 8 can be interpreted as follows. An XPS spectrum obtained before wiping the nozzle plate with a wiping blade indicates that many CF ₂ O groups are present on the surface of the oil-repellent film. On the other hand, the XPS spectrum obtained after wiping the nozzle plate with a wiping blade once shows that the CF ₂ O groups were significantly reduced from the surface of the oil-repellent film.

As explained with reference to FIGS. 7A and 7B, this phenomenon can be explained as follows. That is, it is thought that as a result of rubbing the nozzle plate with the wiping blade 140, the CF ₂ O groups rotated around the polymer main chain (conformation change) and moved from the surface of the oil-repellent film to the inside of the oil-repellent film.

Example An evaporation source containing a fluorine-based compound represented by the following chemical formula was prepared. This evaporation source and the nozzle plate substrate were installed in a vacuum deposition apparatus, and a fluorine-based compound was deposited on the surface of the nozzle plate substrate facing the recording medium by a vacuum deposition method. As described above, an oil-repellent film was formed on the surface of the nozzle plate substrate facing the recording medium.

The nozzle plate was rubbed with a wiping blade under varying loads. After that, the surface of the oil-repellent film was analyzed by the XPS method.

FIG. 9 shows the X-ray photoelectron spectroscopy (XPS) spectra obtained for the surface of the oil-repellent film before cleaning the nozzle plate of Example with a wiping blade (before rubbing) and after cleaning 6000 times (after rubbing 6000 times). show. In FIG. 9, the horizontal axis is the binding energy, and the vertical axis is the intensity of emitted photoelectrons.

The results in FIG. 9 can be interpreted as follows. That is, the obtained XPS spectrum shows that the ratio of CF ₃ groups existing on the surface of the oil-repellent film is almost maintained before and after the nozzle plate is rubbed with the wiping blade.

Next, in the nozzle plates of Examples and Comparative Examples, reflection spectra of the oil-repellent films before and after rubbing with a wiping blade were measured by terahertz time domain spectroscopy. Here, the reflection spectrum was obtained by Fourier transforming a region R including the first and second peaks in the temporal waveform of the oscillating electric field of the terahertz pulse wave shown in FIG. Terahertz time domain spectroscopy was measured using TAS7500SP (Advantest).

The results are shown in FIGS. 11 and 12. FIG. FIG. 11 is a graph showing reflection spectra obtained for the oil-repellent film before and after rubbing the nozzle plate of the comparative example with a wiping blade 6000 times. FIG. 12 is a graph showing reflection spectra obtained for the oil-repellent film before and after rubbing the nozzle plate of the example with a wiping blade 6000 times. In the figure, the horizontal axis represents frequency, and the vertical axis represents reflectance. Also, P1 to P4 indicate peak frequencies showing maximum intensity in the frequency band of 0.7 to 1.4 THz for each reflection spectrum. Here, a rubber wiping blade was used and the load was 13 gf.

Regarding the reflection spectrum of the oil-repellent film before rubbing the nozzle plate of the comparative example, the peak showing the maximum intensity in the frequency band of 0.7 to 1.4 THz was 1.05 THz. Further, regarding the reflection spectrum of the oil-repellent film after rubbing the nozzle plate of the comparative example 6000 times, the peak showing the maximum intensity in the frequency band of 0.7 to 1.4 THz was 1.36 THz. That is, the frequency changed greatly.

Regarding the reflection spectrum of the oil-repellent film before rubbing the nozzle plate of the example, the peak showing the maximum intensity in the frequency band of 0.7 to 1.4 THz was 1.11 THz. Further, regarding the reflection spectrum of the oil-repellent film after rubbing the nozzle plate of the example 6000 times, the peak showing the maximum intensity in the frequency band of 0.7 to 1.4 THz was 1.13 THz. That is, there was almost no change in frequency.
In other words, the nozzle plate of the example showed no change in its surface bonding state before and after abrasion.

Next, the relationship between the number of times of rubbing with the wiping blade and the speed at which the nozzle plate repels ink was examined for the nozzle plates of Examples and Comparative Examples.

The ink repelling speed was measured as follows. A nozzle plate with an oil-repellent film having a width of 15 mm was prepared as a sample. The nozzle plate was erected and held near the upper end, and almost the entire nozzle plate was immersed in the ink. Next, the nozzle plate was pulled up from the ink by a length of 45 mm, and the time required for the ink to run out from the lifted portion was measured.

The length of the oil-repellent film immersed in the ink is L (= 45 mm), the time required for the ink to disappear from the pulled up portion is T [seconds], and the ink repelling speed Rr [mm/second] is as follows. Define.

Rr [mm/sec] = L/T = 45/T
The nozzle plate coated with the oil-repellent film was rubbed a predetermined number of times with a wiping blade under a load of 13 gf. After that, the ink repelling speed Rr was measured by the same method as above.

FIG. 13 shows the relationship between the number of times the nozzle plate is rubbed with the wiping blade and the speed at which the nozzle plate repels ink, which is obtained for the nozzle plates of Examples and Comparative Examples. In FIG. 13, the horizontal axis is the number of times of rubbing by the wiping blade, and the vertical axis is the speed at which the nozzle plate repels ink.

The following can be understood from FIG. The nozzle plate of the comparative example deteriorated in ink repellency when the number of times of rubbing with the wiping blade was less than 1000 times. On the other hand, the nozzle plate of the example was prevented from deteriorating in ink repellency even after being rubbed with the wiping blade as many times as 6000 times.

As described above, the ink-jet heads of Examples showed little deterioration in ink repellency even when the surface of the nozzle plate facing the recording medium was rubbed with a wiping blade.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.
The following is an additional description of the invention described in the original claims.
[1]
a nozzle plate provided with nozzles for ejecting ink toward a recording medium;
The nozzle plate includes a nozzle plate substrate and an oil-repellent film provided on a surface of the nozzle plate substrate facing the recording medium,
The oil-repellent film includes a fluorine-based compound crosslinked between adjacent molecules in a direction parallel to the surface, and has a structure in which the surface bonding state does not change due to rubbing.
[2]
a nozzle plate provided with nozzles for ejecting ink toward a recording medium;
The nozzle plate includes a nozzle plate substrate and an oil-repellent film provided on a surface of the nozzle plate substrate facing the recording medium,
The oil-repellent film contains a fluorine-based compound crosslinked between adjacent molecules in a direction parallel to the surface, and has a maximum in a frequency band of 0.7 to 1.4 THz in a reflection spectrum obtained by terahertz time domain spectroscopy. An inkjet head in which the change in frequency of the intensity peak before and after rubbing is 0.2 THz or less.
[3]
Item 1 or 2, wherein the fluorine-based compound has a bonding site bonded to the nozzle plate substrate and a terminal perfluoroalkyl group, and the adjacent fluorine-based compounds have the bonding sites bonded to each other. The described inkjet head.
[4]
Item 4. The inkjet head according to Item 3, wherein the fluorine-based compound further has a spacer linking group between the binding site and the terminal perfluoroalkyl group.
[5]
The inkjet head according to any one of Items 1 to 4;
a medium holding mechanism that holds the recording medium facing the inkjet head;
a wiping blade for scraping said surface to remove said ink from said surface.

DESCRIPTION OF SYMBOLS 1... Inkjet head, 30... Actuator, 50... Nozzle plate, N... Nozzle, 52... Oil-repellent film, 53... Binding site, 54... Spacer linking group, 55... Terminal perfluoroalkyl group, 100... Inkjet printer, 115Bk... Inkjet Head 115C... Inkjet head 115M...Inkjet head 115Y...Inkjet head 120...Head moving mechanism 130...Blade moving mechanism 140...Wiping blade.

Claims (2)

a nozzle plate provided with nozzles for ejecting ink toward a recording medium;
The nozzle plate includes a nozzle plate substrate and an oil-repellent film provided on a surface of the nozzle plate substrate facing the recording medium,
The oil-repellent film contains a fluorine-based compound crosslinked between adjacent molecules in a direction parallel to the surface, and has a maximum in a frequency band of 0.7 to 1.4 THz in a reflection spectrum obtained by terahertz time domain spectroscopy. The frequency change before and after rubbing of the peak indicating the intensity is 0.2 THz or less,
The fluorine-based compound has a bonding site bonded to the nozzle plate substrate and a terminal perfluoroalkyl group, and the adjacent fluorine-based compounds are crosslinked by mutual bonding of the bonding sites,
The fluorine-based compound further has a spacer linking group between the binding site and the terminal perfluoroalkyl group,
the spacer linking group is a perfluoropolyether group;
The inkjet head , wherein the terminal perfluoroalkyl group is a linear perfluoroalkyl group having 3 to 7 carbon atoms . The inkjet head according to claim 1 ;
a medium holding mechanism that holds the recording medium facing the inkjet head;
a wiping blade for scraping said surface to remove said ink from said surface.

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