JP5764995B2 - Lead-free thin film actuator - Google Patents

Description

  The present invention relates to a lead-free thin film actuator that generates a large amount of displacement when an electric field is applied, a liquid discharge head using the same, and an inkjet printer.

Inkjet recording devices have a lot of advantages such as extremely low noise, high-speed printing, and the flexibility of ink and the ability to use inexpensive plain paper. Printers, facsimiles, copying machines, etc. It is widely deployed as an image recording apparatus or image forming apparatus.
A droplet discharge head used in an ink jet recording apparatus includes a nozzle that discharges ink droplets, and a liquid chamber (also referred to as a discharge chamber, a pressurized liquid chamber, a pressure chamber, or an ink flow path) that communicates with the nozzle. The pressure generating means is provided for each liquid chamber for discharging ink in the liquid chamber.
As one of the pressure generating means as described above, an electro-mechanical conversion element that converts electrical input such as a piezoelectric element into mechanical deformation is used to deform and displace the diaphragm that forms the wall surface of the discharge chamber. A piezo type that ejects ink droplets (see, for example, Patent Document 1).
Conventionally, PZT ceramics and the like have been used as actuators for ink jet heads and the like of ink jet printers (see, for example, Patent Documents 1 and 2). Materials are highly desired.

As typical PZT substitute materials studied so far, the following material systems can be cited.
(1) Material system mainly composed of barium titanate The disadvantage of this material is that it has a Curie point (corresponding to the temperature at which piezoelectricity disappears) at 125 ° C, making it difficult to use at high temperatures, especially thermal stability. , The upper temperature limit is 1/3 or less of the Curie point. That is, about 40 ° C. corresponds to the upper limit temperature. When driven in a non-resonant mode such as inkjet and at a high frequency of about 10 kHz, Joule heat is generated due to the dielectric loss of the material, and this upper limit temperature is easily reached, which is not suitable for practical use.
(2) Potassium niobate, sodium niobate, and their solid solutions, and alkaline niobate-based materials with lithium added as an additive. The Curie point of these materials can be expected to increase the actual use temperature, but the structure is around 150 ° C. Since there exists a depolarization temperature due to a phase transition, it is not suitable for practical use like the barium titanate material. In addition, since an alkali element is included as a constituent element, there is a problem in reliability related to long-term stable operation.
(3) A material that is described as a bismuth ferrite-based material BiFeO ₃ and includes a case where an iron element is substituted by In, Co, or the like as a trivalent element. Such a material has a high Curie point of about 550 ° C., but easily exhibits electrical conductivity due to a change in the valence of the iron element, and has the disadvantage that its piezoelectric use operates only at extremely low temperatures. Solid solutions with barium titanate have been studied for the purpose of low-temperature synthesis and raising the Curie point of barium titanate, but they have not been put into practical use.
(4) Bismuth layered structure The ferroelectric Curie point is as high as 700 ° C., and the mechanical quality factor is high, but the piezoelectricity is low, so it is limited to applications such as ceramic filters.
(5) Although the material mechanical quality factor having a tungsten bronze structure is high, since the piezoelectricity is low, only trial production of an ultrasonic motor is performed.
As described above, although a PZT alternative material has been studied, a material having a performance comparable to PZT has not yet been created.
However, substitution for PZT is possible when limited to specific applications. When PZT is used for an electro-mechanical conversion element, it is roughly divided into a form using its resonance state and a form using a non-resonance state. For example, it is used for an on-demand type inkjet head or the like. It is widely known that a thin film actuator that uses a non-resonant state is used. That is, it suffices if it gives mechanical displacement to the input electrical signal.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a lead-free thin film actuator (lead-free thin film electrostrictive actuator) that can be used in an actuator portion of an inkjet head.

In order to achieve the above object, the present invention is a lead-free thin film actuator using a composite oxide thin film mainly composed of barium titanate and bismuth nickel titanate ,
A principal component of the composite oxide thin film is represented by Formula 1, wherein x is in a range of 0 <x ≦ 0.1 .
(1-x) BaTiO ₃ —xBi (Ni _0.5 , Ti _0.5 ) O ₃ (Formula 1)

  According to the present invention, a lead-free thin film actuator having excellent piezoelectric characteristics that has a small remanent polarization and exhibits sufficient displacement for use as an actuator due to an electrostrictive effect when a voltage is applied, even though no lead component is used. Can be provided.

A flow for producing a (1-x) BaTiO ₃ —xBi (Ni _0.5 , Ti _0.5 ) O ₃ thin film by the CSD method is shown. Using AFM, showing the crystal _{(1-x) BaTiO 3 -xBi} (Ni 0.5, Ti 0.5) O 3 (x = 0.1) surface morphology observation of the thin film. The relative permittivity and dielectric loss frequency dependence of the crystalline (1-x) BaTiO ₃ —xBi (Ni _0.5 , Ti _0.5 ) O ₃ (x = 0.1) thin film are shown. Crystalline _{(1-x) BaTiO 3 -xBi} (Ni 0.5, Ti 0.5) O 3 (x = 0.1) shows the P-E hysteresis curve of the thin film. The electrostrictive characteristics of a crystalline (1-x) BaTiO ₃ —xBi (Ni _0.5 , Ti _0.5 ) O ₃ (x = 0.1) thin film are shown. The temperature dependence of the dielectric properties of the crystalline (1-x) (Ba _0.95 Sr _0.05 ) TiO ₃ -xBi (Ni _0.5 , Ti _0.5 ) O ₃ (x = 0.1) film is shown. Show. Crystals showing a _{(1-x) (Ba 0.95} Sr 0.05) TiO 3 -xBi (Ni 0.5, Ti 0.5) O 3 (x = 0.1) P-E hysteresis curve of the film. 1 shows a liquid discharge head (inkjet head) equipped with a lead-free thin film actuator according to the present invention. FIG. 9 is a perspective explanatory view of an ink jet recording apparatus using the liquid discharge head of FIG. 8. FIG. 9 is an explanatory side view of an ink jet recording apparatus using the liquid discharge head of FIG. 8.

  Examples of the present invention will be described below with reference to the accompanying drawings, but the present invention is not limited to the examples.

In this example, the complex oxide thin film according to the present invention was formed by the CSD method according to the experimental flow shown in FIG. Details of the starting materials used are shown in Table 1.
(1) Preparation of substrate for thin film formation In this example, in order to obtain a thin film electrostrictive actuator, a substrate on which each member was previously formed in the following steps was used as a substrate on which a thin film was formed.
A SiO ₂ film was disposed as a vibration plate on a Si substrate, and a Pt film as a first electrode film was formed thereon with a thickness of 100 nm by sputtering as a lower electrode. At this time, in order to improve the adhesion with the underlying SiO ₂ film, an adhesion film such as Ti, Ta, TiN, TaN, TiO ₂ , Ta ₂ O ₅ is preferably disposed between the diaphragm and the lower electrode. In this example, a 10 nm Ti film was formed by sputtering.
(2) Formation of Thin Film by CSD Method A target lead-free complex oxide thin film is deposited on a substrate by a sol-gel method which is a kind of CSD method (Chemical Solution Deposition).

In a mixed solution of 2-methoxyethanol (EGMME), which is a preparation solvent for the precursor solution, and methanol, Ba (OEt) ₂ , Ti (O ⁱ Pr) ₄ , Bi ( O ⁱ Am) ₃ and Ni (acac) ₂ are added to prepare a raw material mixed solution.
Here, a solution in which EGMME and methanol were mixed at a volume ratio of 6: 4 was used as a solvent. Further, each of x in the formula of (1-x) BaTiO ₃ -xBi (Ni _0.5 , Ti _0.5 ) O ₃ as the target substance is 0.1, 0.2, 0.3. Raw materials were added and mixed. For comparison, a sample with x = 0 was also produced as a reference sample.
Next, a reflux treatment is performed so that the raw material mixed solution obtained in the above step is dissolved. Here, the reaction was performed by refluxing for 18 hours in a temperature range of 85 to 95 ° C. Thereafter, the obtained solution is adjusted to a concentration suitable for film formation by spin coating. In this example, the concentration was adjusted to 0.3M. These steps were performed in an inert atmosphere.
Thin Film Formation Step A precursor solution is formed on the first electrode film by spin coating on the Pt / Ti / SiO ₂ / Si substrate obtained in the preparation step of the thin film formation substrate (rotation speed: 2500 rpm, 30 seconds), and after drying at 120 ° C. for 1 minute, a thermal decomposition treatment was performed.
The thermal decomposition treatment conditions can be estimated by TG-DTA measurement of a dried gel prepared from the precursor solution. In this example, the treatment was performed at 400 ° C. for 10 minutes.
Since the film after pyrolysis is amorphous, it is necessary to perform crystallization treatment in order to make the electrostrictive characteristics appear. For example, it can be performed by heat treatment at 700 to 750 ° C. In this example, treatment was performed at 750 ° C. for 10 minutes.
The film thickness that can be deposited by performing the above series of operations once was 50 nm. However, when used as an actuator, the generated force deforms the diaphragm, and the amount of deformation eliminates ink in the ink chamber, so that a film thickness of approximately 0.5 to 2 microns is required. Therefore, the spin coating, drying, thermal decomposition, and crystallization are repeated for the desired film thickness.
In this example, this operation was performed 10 times to form a film of about 0.5 microns.
(3) Post-processing process On the thin film obtained by the pre-process, Pt film which is a 2nd electrode film was formed with the thickness of 100 nm as a top electrode by sputtering method.
The upper electrode is patterned by dry etching to form an individual electrode of the actuator. Subsequently, by dry etching, a (1-x) BaTiO ₃ —xBi (Ni _0.5 , Ti _0.5 ) O ₃ film (hereinafter simply referred to as “BT-BiNiT film”) is used. (Showing the value of x in the chemical formula).

Since the lead-free thin film electrostrictive actuator of this example obtained by the above steps was evaluated, it will be described in detail below.
FIG. 2 shows the results of surface morphology observation of the produced BT-BiNiT thin film (x = 0.1) using an atomic force microscope (AFM). Grain size increased and surface roughness increased with increasing amount of bismuth titanate nickelate. Specifically, at x = 0.1, the grain size was 100 nm, and the RMS (root mean square roughness) was 3.6 nm.
FIG. 3 shows the frequency dependence of the dielectric constant and dielectric loss of the produced BT-BiNiT thin film (x = 0.1). According to the results, it can be seen that this sample has a high relative dielectric constant and a small dielectric loss within the measurement frequency range. Since the strain is proportional to the charge density stored in the electrostrictive material, it is preferable that the relative dielectric constant is high.
As described above, in this example, the bismuth titanate titanate addition amount was changed to x = 0.1 to 0.3, but the relative dielectric constant and the bismuth titanate titanate addition amount were examined. In this relationship, the relative dielectric constant showed an extreme value at x = 0.1. Accordingly, the range of the addition amount x of bismuth nickel titanate is preferably 0 <x ≦ 0.1.
FIG. 4 shows a PE hysteresis curve at room temperature and 1 kHz for the produced BT-BiNiT thin film (x = 0.1). It shows a slim loop with a small remanent polarization, which is also different from the conventional piezoelectric material in this respect. Here, since the residual polarization is small, it can be said that the present invention is an electro-mechanical conversion element in which the amount of change in polarization with respect to an increase in electric field, that is, the change in volume is large and a large displacement is obtained with a small electric field.
5, the BT-BINIT films prepared (x = 0.1), shows the results of measurement of the piezoelectric constant _{d 33} with AFM. This was because the thin film showed distortion with respect to the electric input, and its proportionality constant was 24 pm / V.
The present invention is for the main use of the thin film electrostrictive actuator used in the liquid discharge head of an ink jet printer, using the d ₃₁ direction of deformation in applications according. However, it can be said that this material can be used as an electro-mechanical conversion element, that is, an electrostrictive element, because extending in the vertical direction indicates simultaneously shrinking in the horizontal direction. Further, the value of the d _33, a composite oxide thin film of the present invention, it can be said to have sufficient displacement range for use as a thin film actuator.
Here, d ₃₁ is a piezoelectric constant conventionally used in estimating the amount of displacement of lateral vibration. The subscript 31 indicates that the polarization axis is 3, and when the electric field is applied in the same direction as the polarization axis, the direction orthogonal to the electric field is 1 and is a proportional constant for the amount of distortion generated.

An element having a small ionic radius can be substituted at the Ba site, and Sr and Ca are elements that can be substituted. Further, Zr and Hf are elements that can be substituted for Ni and Ti sites. These are used to control the temperature dependence of dielectric properties.
Here, the Ba site is set to 0 so that (1-x) (Ba _0.95 Sr _0.05 ) TiO ₃ -xBi (Ni _0.5 , Ti _0.5 ) O ₃ (x = 0.1). The film substituted with Sr of .05 will be described.
Sr (OEt) ₂ was used as a starting material for Sr, and was added to the mixed solvent so as to be stoichiometric in the step of preparing the precursor solution. Other conditions are the same as those in Example 1.
FIG. 6 shows the temperature dependence of the dielectric constant and dielectric loss. Pure BaTiO ₃ has a Curie point at 125 ° C., but this sample shows a clear dielectric constant anomaly, rises slowly from −150 ° C. to 0 ° C., and is almost flat within a measurement temperature range of 0 ° C. or higher. The relative dielectric constant is shown.
That is, it can be seen that an electromechanical conversion element having no Curie point in this temperature range and having little temperature fluctuation is obtained.
FIG. 7 shows a PE hysteresis curve measured at room temperature and 1 kHz for the sample obtained in this example. This shows that the residual polarization is further reduced by the addition of Sr.

FIG. 8 shows a liquid discharge head in which a plurality of lead-free thin film actuators of the present invention are arranged. Already in Example 1, a piezoelectric substrate comprising a diaphragm (30), an adhesion layer (41), a lower electrode (42), and a complex oxide thin film (laminated body) of the present invention on a Si substrate (pressure chamber substrate) (20). Each member is formed in the order of an element (electro-mechanical conversion element) (40) and an upper electrode (43). Accordingly, an etching process for forming the pressure chamber (21) is performed on the surface opposite to the surface on which the piezoelectric element is formed, and then the nozzle plate (10) having the nozzle holes (11) is joined to form a liquid discharge head. In the above configuration, by adopting the composite oxide thin film of the present invention, the discharge performance is comparable to that of a conventional product using PZT or the like, although a piezoelectric material not using lead is used.
In the figure, descriptions of liquid supply means, flow paths, fluid resistance, etc. are omitted.

Next, an ink jet printer will be described with reference to FIGS. 9 and 10 as an example of an ink jet recording apparatus on which the liquid discharge head manufactured in Example 3 is mounted. FIG. 9 is an explanatory perspective view of the recording apparatus, and FIG. 10 is an explanatory side view of a mechanism portion of the recording apparatus.
The ink jet printer includes a carriage that is movable in the main scanning direction inside the recording apparatus main body 81, a recording head that includes the ink jet head (liquid ejection head) that is mounted on the carriage, and that supplies ink to the recording head. A printing mechanism 82 composed of a cartridge or the like is accommodated. A paper feed cassette (or a paper feed tray) 84 in which a large number of sheets 83 can be stacked from the front side can be detachably attached to the lower part of the apparatus main body 81. Further, the manual feed tray 85 for manually feeding the paper 83 can be opened, the paper 83 fed from the paper feed cassette 84 or the manual feed tray 85 is taken in, and a required image is displayed by the printing mechanism unit 82. After recording, the paper is discharged to a paper discharge tray 86 mounted on the rear side.
The printing mechanism 82 holds a carriage 93 slidably in the main scanning direction by a main guide rod 91 and a sub guide rod 92 which are guide members horizontally mounted on left and right side plates (not shown). In this carriage 93, a head 94 comprising an inkjet head according to the present invention for ejecting ink droplets of each color is arranged in a direction intersecting the main scanning direction, and a plurality of ink ejection ports (nozzles) are arranged. Is attached facing down. In addition, each ink cartridge 95 for supplying ink of each color to the head 94 is replaceably mounted on the carriage 93.
The ink cartridge 95 has an air port that communicates with the atmosphere upward, a supply port that supplies ink to the inkjet head below, and a porous body filled with ink inside. The ink supplied to the inkjet head is maintained at a slight negative pressure by the capillary force of the porous body. Further, although the heads 94 of the respective colors are used here as the recording heads, a single head having nozzles for ejecting ink droplets of the respective colors may be used.
Here, the carriage 93 is slidably fitted to the main guide rod 91 on the rear side (downstream side in the paper conveyance direction), and is slidably mounted on the sub guide rod 92 on the front side (upstream side in the paper conveyance direction). doing. In order to move and scan the carriage 93 in the main scanning direction, a timing belt 100 is stretched between a driving pulley 98 and a driven pulley 99 that are rotationally driven by a main scanning motor 97, and the timing belt 100 is moved to the carriage 93. It is fixed to. The carriage 93 is reciprocated by forward and reverse rotations of the main scanning motor 97.
On the other hand, in order to transport the paper 83 set in the paper feed cassette 84 to the lower side of the head 94, the paper feed roller 101, the friction pad 102, the guide member 103 for guiding the paper 83, the transport roller 104, the transport roller 105, the tip Each member of the roller 106 is provided.
Here, the paper feed roller 101 and the friction pad 102 separate and supply the paper 83, and the transport roller 104 that is rotationally driven by the sub-scanning motor 107 through the gear train, and the transport roller 105 that is pressed against the peripheral surface thereof. Then, the fed paper 83 is reversed and conveyed. Further, the leading end roller 106 serves to define the feed angle of the paper 83 from the transport roller 104.
A printing receiving member 109 is provided as a paper guide member that guides the paper 83 sent from the transport roller 104 below the recording head 94 in accordance with the movement range of the carriage 93 in the main scanning direction. On the downstream side of the printing receiving member 109 in the sheet conveyance direction, a conveyance roller 111 and a spur 112 that are rotationally driven to send out the sheet 83 in the sheet discharge direction are provided. Further, a paper discharge roller 113 and a spur 114 for sending the paper 83 to the paper discharge tray 86, and guide members 115 and 116 for forming a paper discharge path are provided.
At the time of recording, the recording head 94 is driven according to the image signal while moving the carriage 93, thereby ejecting ink onto the stopped sheet 83 to record one line. Record the line. Upon receiving a recording end signal or a signal that the trailing edge of the paper 83 has reached the recording area, the recording operation is terminated and the paper 83 is discharged.
Further, a recovery device 117 for recovering defective ejection of the head 94 is disposed at a position outside the recording area on the right end side in the movement direction of the carriage 93. The recovery device 117 includes a cap unit, a suction unit, and a cleaning unit. The carriage 93 is moved to the recovery device 117 side during printing standby and the head 94 is capped by the capping means, and the ejection port portion is kept in a wet state to prevent ejection failure due to ink drying. Further, by ejecting ink that is not related to recording during recording or the like, the ink viscosity of all the ejection ports is made constant and stable ejection performance is maintained.
When a discharge failure occurs, the discharge port (nozzle) of the head 94 is sealed with a capping unit, and bubbles and the like are sucked out from the discharge port with the suction unit through the tube. Is removed by the cleaning means to recover the ejection failure. Further, the sucked ink is discharged to a waste ink reservoir (not shown) installed at the lower part of the main body and absorbed and held by an ink absorber inside the waste ink reservoir.
Thus, since this inkjet recording apparatus is equipped with the inkjet head having the lead-free thin film actuator of the present invention, it has ink droplet ejection characteristics equivalent to those of conventional products using PZT or the like.

International Publication No. 2003/098714 JP 2000-127392 A

Claims (5)

It is a lead-free thin film actuator using a complex oxide thin film mainly composed of barium titanate and bismuth nickel titanate ,
A lead-free thin film actuator, wherein a main component of the composite oxide thin film is represented by Formula 1, wherein x is in a range of 0 <x ≦ 0.1.
(1-x) BaTiO ₃ —xBi (Ni _0.5 , Ti _0.5 ) O ₃ (Formula 1) 2. The lead-free thin film actuator according to claim 1, wherein the composite oxide thin film includes at least one subcomponent selected from strontium, calcium, zirconium, and hafnium. 3. The lead-free thin film actuator according to claim 1, wherein the actuator is formed on a silicon substrate, wherein the vibration plate, the first electrode film, the composite oxide thin film, and the second electrode film are arranged in this order on the silicon substrate. A liquid discharge head using a lead-free thin film actuator according to any one of claims 1 to 3. An inkjet printer comprising the liquid ejection head according to claim 4 .