JP2005313561A - Recorder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a recorder of high-speed/high definition which is simply composed, easily constituted into a line, excellent in mass productivity as well as dot position accuracy. <P>SOLUTION: The recorder is equipped with a beam structure 1 arranged in the shape of two or more arrays capable of taking a bending movement, a means 8 feeding ink to the beam structure and a means conveying a recording medium, and forms an image by making the beam structure 1 bent according to an image signal and making the bent structure contact the recording medium 5, and then making the ink 4 transferred to the recording medium. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a recording apparatus that forms an image by transferring ink onto a recording medium.

Conventionally, a dot impact method, a hot-melt thermal transfer method, an electrophotographic method, and an ink jet method are known as commercially available printer recording methods. Among these, the serial ink jet head method has low dot position accuracy on the paper as a recording medium, does not provide high-definition character quality, and does not easily increase the printing speed to 10 ppm or more. The multi-nozzle line type ink jet head system has the disadvantages that it is easy to increase the speed but is difficult to process and the cost is increased.
Patent Documents 1 and 2 propose a configuration in which a line is simplified by using an electrostatic beam structure. In this case, it is necessary to seal the liquid. In addition, since the dry electrophotographic method usually uses a large toner of about 5 to 7 μm, it is difficult to obtain high image quality as in offset printing. Since the wet electrophotographic system uses toner of 1 μm or less, the image quality is comparable to that of offset printing, but there is a drawback that it is difficult to dry the toner on the paper. The thermal transfer system uses a line type thermal head, but this line type thermal head is expensive and expensive. On the other hand, Patent Documents 3, 4, and 5 describe the configuration of a dot impact type print head. In the case of the dot impact method, the line type can be made relatively easily, but the resolution is low because the mechanism is complicated.

JP2000-015808 JP2000-015809 Japanese Patent No. 2844717 JP2001-80095 JP 2000-141717 A

  SUMMARY OF THE INVENTION An object of the present invention is to provide a high-speed and high-definition recording apparatus that has a simple configuration, can be easily formed into a line, has excellent mass productivity, and has excellent dot position accuracy.

  In order to achieve the above object, a recording apparatus according to the present invention conveys a recording medium, a plurality of beam structures arranged in an array capable of bending motion, means for supplying ink to the beam structures, and a recording medium. And a beam structure is bent in accordance with an image signal and brought into contact with a recording medium, and ink is transferred onto the recording medium to form an image.

  As the form of the beam structure, a cantilever beam structure or a doubly supported beam structure can be assumed. In the case of a cantilever structure, the tip of the cantilever can be bent according to the image signal and brought into contact with the recording medium to transfer the ink onto the recording medium to form an image. Can be simplified and the writing unit can be downsized. In the case of a cantilever beam structure, it is preferable to provide an ink holding means on the beam structure because a buffer is provided in the ink adhesion amount, so that the adhesion amount is stable and the image reliability is increased. Alternatively, if a slit is provided at the tip of the beam structure so that ink is supplied and held by capillary force, it functions as an ink holding means and is the simplest and lowest cost as this holding means.

  In the case of a double-supported beam structure, an image may be formed by bending the beam structure at the center of the both-supported beam according to an image signal to contact the recording medium and transferring ink onto the recording medium. By holding both ends, the rigidity of the beam is increased, the response of the bending motion is improved, and high-speed printing can be performed by increasing the drive frequency. In the case of a double-supported beam structure, if an ink holding means is provided at the center of the beam structure, a buffer is provided for the amount of ink adhering to the beam structure, so the adhesion amount is stable and image reliability is improved. preferable.

  When the arrayed beam structure is alternately contacted with the recording medium for each adjacent structure according to the image signal and ink is transferred onto the recording medium to form an image, that is, the arrayed beam structure is alternated. When it is driven to, it will not receive the interference of the adjacent beam. If these beam structures are provided with slits to supply and hold ink, it functions as an ink holding means and is the simplest and lowest cost as a holding means.

  A plurality of beam structures may be provided in a direction opposite to the recording medium conveyance direction or in the recording medium conveyance direction. Even when a plurality of beam structures are provided in a direction opposite to the conveyance direction of the recording medium and when a wide recording medium is supported, the structure can be simply set.

  It is preferable to provide a plurality of beam structures in the recording medium conveyance direction because dots are stabilized and printing quality is improved. In addition, when the beam structures are arranged in a staggered manner, the resolution is increased and the image quality is improved. When a plurality of inks are provided and a plurality of beam structures are provided in the recording medium conveyance direction, a large size reduction can be achieved as a color recording apparatus by providing a plurality of beam structures for each color. Further, if ink fixing means for the recording medium is provided between the beam structures for each color, the ink can be immediately fixed on the recording medium, so that high-speed printing is possible.

  As the ink fixing means, when a roller-shaped member having an absorptivity only for the ink solvent is used as a means for contacting the recording medium, the configuration is simple and the apparatus configuration is not complicated. When the ink is composed of a resin, a color material, and an oily solvent, this means is most suitable as a fixing material when composed of a member having a polyorganosiloxane skeleton, and stable printing is possible.

  By defining the viscosity of the ink used in the recording apparatus of the present invention within the range of 0.001 Pa · s to 1 Pa · s, the ink management most suitable for the present invention can be performed. If the ink contains a resin and a pigment or a dye and an organic solvent, an ink having good storage stability can be provided, and the standing reliability of the apparatus is increased, which is preferable. It is preferable that the ink contains a water-holding member, a coloring material, and water, since bleeding in high-quality paper can be prevented, image quality and storage stability can be compatible, leaving reliability is high, and high image quality can be achieved.

  In the present invention, when the beam structure is composed of a member that bends and moves by self-contraction and expansion by an electric field, a magnetic field, or heat, it is preferable because it is most easily processed as a beam structure material and mass productivity is improved. It is preferable that the beam structure is made of an electric field responsive polymer material because this member is a polymer material and has the highest workability. Alternatively, it is preferable to form a unimorph or bimorph structure of a shape memory alloy and a silicon substrate on which a silicon oxide film is formed, because a metal is used, which is excellent in environmental resistance.

  In the present invention, it is preferable to configure the beam structure with an electrostatic actuator because an inexpensive material can be selected as the electrode material, leading to cost reduction.

  When beam structures arranged in a plurality of arrays that can be bent are manufactured by laser cutting, precise processing can be performed in a short time, and the yield is improved.

According to the present invention, there are provided a plurality of beam structures arranged in an array capable of bending motion, means for supplying ink to the beam structures, and means for conveying a recording medium. Accordingly, the beam structure is bent and brought into contact with the recording medium to form an image by transferring the recording ink onto the recording medium, thereby forming a high-speed and high-definition image with a simple configuration. it can.
According to the present invention, an image is formed by bringing an array of beam structures into contact with a recording medium alternately for each adjacent structure in accordance with an image signal and transferring ink onto the recording medium. , It will not be interfered by the adjacent beam, and the printing will be stable and reliable.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows an example of a beam structure in the present invention. In FIG. 1 (a), the beam structure indicated by reference numeral 1 is provided with a slit 2 in a plate-like beam structure and is supplied with an ink supply means (ink ink) indicated by reference numeral 3 by a tube from an ink supply tank (not shown). The ink indicated by reference numeral 4 is supplied to the supply section), and the ink 4 is moved to the tip 1A of the beam by capillary action. This is the same principle as ink supply to the nib in a fountain pen. The beam structure 10 shown in FIG. 1 (b) supplies ink to the tip 10A by moving the ink in the tubular structure by capillary force. The beam structures 1 and 10 are supported at their base ends 1B and 10B on the base 11, respectively, and are cantilever beam structures. In FIG. 1A, the slit 2 is completely formed up to the tip 1A of the beam structure. However, as shown in FIG. 1C, the slit 2 may be formed up to the front of the tip 1A.

  FIG. 2 is a specific example in which the beam structure 1 shown in FIG. 1A is arranged in a plurality of arrays. In FIG. 2, a plurality of slits 2 are provided in one plate-like member 11 along the longitudinal direction of the plate-like member 11, and a plurality of beam structures 1 are arranged in an array. Each beam structure 1 can be bent individually by inputting (applying) an electric signal. This bending direction is the vertical direction in FIG.

  FIG. 3 shows the recording principle according to one embodiment of the invention. In FIG. 3A, the ink conveyed to the beam structure 1 from an ink supply means (not shown) is supplied to the tip 1A of the beam structure 1 by capillary force. The recording paper 5 as a recording member is arranged and delivered in a direction perpendicular to the arrangement direction B of the beam structure 1 at a position where the ink structure 4 can be contacted by bending the beam structure 1 during the conveyance. ing. Then, when an electrical signal is applied to an electrode to be described later, as shown in FIG. 3B, the beam structure 1 is bent and brought into contact with the recording paper 5 to deposit the ink 4 on the recording paper. Next, the applied electric signal is turned off or an electric signal having a reverse polarity is applied to return the beam structure 1 to the original position, that is, the position before bending as shown in FIG. An ink image is formed on the recording paper 5 by performing this series of operations in accordance with the image signal while moving the recording paper 5 in the transport direction indicated by the arrow A.

  As a specific example, the beam structures 1 are arranged in an array at a pitch that is an integral multiple of the image resolution. 2 (a) and 2 (b), a plurality of beam structures 1 are integrally formed using a member that deforms when an electric field is applied as a plate-like member 11, and the common electrode 6 is formed in the length of one side (back side). Each electrode 7 is formed in a direction and an individual electrode 7 corresponding to each pixel is formed on the surface (front surface). The individual beam structures 1 are not limited to this example, and the beam structures 1 may be formed in units of pixels and the beam structures 1 may be connected in an array.

  As shown in FIG. 4, the length L of each beam structure 1 may be the same as shown in FIG. 4 (a), or may be different as shown in FIG. 4 (b). Alternatively, as shown in FIG. 4C, it may be arranged obliquely.

  FIG. 5 shows the recording principle in a specific example of the present invention. Reference numeral 8 in the figure denotes an ink fountain as an ink supply means. FIG. 5A shows a plurality of cantilever beam structures 1 arranged in an array that can come into contact with the ink fountain 8, and the beam structure at a position that can come into contact with the beam structure 1. The positional relationship with the recording paper 5 being conveyed in the direction orthogonal to the row 1 is shown. An arrow A indicates the conveyance direction. In order to perform recording, first, as shown in FIG. 5 (b), the beam structure 1 is bent and deformed toward the ink fountain 8 and the tip 1A is brought into contact with the ink 4, and as shown in FIG. 5 (c). The ink 4 is attached to the tip 1A, which is a part of the beam structure 1, here. Thereafter, the beam structure 1 is bent and displaced in the direction opposite to that shown in FIG. 5B as shown in FIG. 5D, and the recording paper 5 is brought into contact with the recording paper 5 so that the ink 4 is applied onto the recording paper 5. Then, the bending deformation of the beam structure 1 is released as shown in FIG. An ink image is formed on the recording paper 5 by performing this series of operations according to the image signal.

  The arrangement direction B (see FIG. 2) of the beam structures 1 and the conveyance direction A of the recording paper 5 are perpendicular to each other, and the length L of the beam structure 1 is the same as the recording width, as shown in FIG. Such an arrangement of the recording head 9 is desirable. At this time, as shown in FIG. 7, the recording head 9 having the beam structure 1 arranges the arrayed beam structure 1 along the longitudinal direction thereof, and places the ink fountain 8 above the beam structure 1. The recording apparatus 100 is configured by arranging as shown in FIG. As shown in FIG. 8, the recording apparatus 100 includes an array-shaped beam structure 1 and a recording head 9 having an ink fountain 8, and a tip 1A of the beam structure 1 below the recording head 9 with a recording paper 5 interposed therebetween. A roller 101 that is disposed in a substantially opposing portion and whose position can move up and down toward the tip 1A, a plurality of conveying roller pairs 102, 103, and 104 disposed before and after the roller 101, a guide plate 105, It has. These conveyance roller pairs 102, 103, and 104 constitute a means for conveying the recording paper 5. When the length L of the beam structure 1 is narrower than the recording width, printing scanning by a shuttle method may be performed like a serial printer.

  Various beam structures will be described below. Various beam structures related to the cantilever beam structure are applied to the recording apparatus 100 shown in FIG. 8, and various beam structures related to the cantilever beam structure. The body is applied to the recording apparatus 200 shown in FIG.

(Configuration of cantilever beam structures arranged in an array)
A polyvinylidene fluoride film (thickness 200 μm) patterned with a common electrode on the bottom and individual electrodes with a width of 170 μm on the top is slit by laser processing along the upper individual electrodes as shown in FIG. Form. The length L of the beam structure 1 was 30 mm.
-Ink: Oil-based ink consisting of 14 wt% pigment (carbon black), 1 wt% pigment dispersant, 85 wt% olefinic solvent-Ink supply member: Impregnated porous urethane foam with the above ink and fixed to aluminum In this way, the coated paper as the recording paper 5 is conveyed by the conveying roller pairs 102, 103, 104, and the gap C between the lower surface of the ink supply means (ink fountain 8) and the coated paper is adjusted to 30 μm by adjusting the position of the roller 101. The beam structure 1 was arranged in the middle.

Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure 1 at a frequency of 10 Hz and a voltage of 30 V, a dot row having a dot diameter of about 150 μm could be formed on the paper.

  The recording principle of another embodiment of the present invention will be described. FIG. 9 shows a dual-supported beam structure 20 whose both ends are supported by the bases 11A and 11B. The beam structure 20 has a central portion 20A bent in accordance with an image signal to come into contact with the ink fountain 8 and the recording paper 5, and the ink 4 is transferred onto the recording paper 5 to form an image. .

  FIG. 9A shows an ink fountain 8, a plurality of beam structures 20 arranged in an array that can contact the ink fountain 8, and a beam at a position that can contact the beam structure 20. A positional relationship with the recording paper 5 being conveyed in a direction perpendicular to the arrangement direction of the structures 1 is shown. In the central portion 20A of each beam structure 20, an ink hole 21 is formed as an ink holding means for holding the ink 4. In this embodiment, in order to perform recording, the beam structure 20 comes into contact with the ink 4 of the ink fountain 8 as shown in FIG. 9B, and as shown in FIG. The ink is adhered to the central portion 20A which is the portion. Thereafter, the beam structure 20 is brought into contact with the recording paper 5, the ink 4 is adhered onto the paper from the ink holes 21, and the bending deformation of the beam structure 20 is released as shown in FIG. 9 (e). An ink image is formed on the recording paper 5 by performing this series of operations according to the image signal.

  The beam structures 20 of this embodiment are arranged in an array at a pitch that is an integral multiple of the image resolution. FIG. 10 shows a specific example. FIG. 10 shows a configuration of a beam structure 20 that is integrally configured with a plate-like member 30 that is deformed up and down in FIG. 10 by applying an electric field. A common electrode 31 is formed on one surface (back surface) of the plate member 30 as shown in FIG. 10B, and an individual electrode corresponding to each pixel is formed on the opposite surface (front surface) as shown in FIG. 10A. 32 are formed.

  In the plate member 30, a plurality of slits 22 extending in a direction perpendicular to the arrangement direction B are formed at equal intervals, and ink holes 21 are formed between the slits 22. The individual beam structures 20 are not limited to this example, and may be configured such that beam structures are formed in units of pixels and the beam structures are connected in an array. When the arrangement direction B of the beam structures 20 and the conveyance direction A of the recording paper 5 are perpendicular to each other and the length of the beam structures 20 is the same as the recording width, the arrangement shown in FIG. 6 is desirable.

  FIG. 11 shows a recording apparatus 200 including a recording head 40 having the beam structure 20. The recording head 40 includes a both-end supported beam structure 20 and an ink fountain 8. The recording apparatus 200 is disposed below the recording head 40 at a position substantially opposite to the central portion 20A of the beam structure 20 with the recording paper 5 interposed therebetween, and a roller 101 that can move up and down toward the central portion 20A. A plurality of conveyance roller pairs 102, 103, and 104 that are arranged before and after the roller 101 and constitute conveyance means, and a guide plate 105 are provided.

(Structure of a beam structure with both ends arranged in an array)
Using a laminated PZT (thickness 1000 μm) with a stainless steel plate with a thickness of 100 μm, a common electrode at the bottom and a laminated PZT (thickness 1000 μm) with a width of 170 μm and a length of 30 mm along the upper individual electrode 32 by a dicing saw. As shown in FIG. 10, slit processing is performed, and lead wires are connected to the individual electrodes 32. Thereafter, the entire beam was coated with a polyamide resin to provide insulation. PZT represents lead zirconate titanate.

Ink: Water-based ink containing 1 wt% of dye. Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material. As shown in FIG. The coated paper was conveyed, and the gap C between the ink supply means (ink fountain 8) and the coated paper was adjusted to 30 μm by adjusting the position of the roller 101, and the beam structure 20 was arranged in the middle.

Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure 20 at a frequency of 10 Hz and a voltage of 50 V, a dot row having a dot diameter of about 150 μm could be formed on the paper.

  By the way, in the beam structures 1 and 20 arranged in a plurality of arrays capable of bending motion, if the adjacent beam structures are moved simultaneously, the beams may collide with each other. It is preferable to shift the voltage application time so as to move with a time difference alternately because there is no possibility of collision between adjacent beam structures. A plurality of beam structures 1, 10, and 20 may be provided in a direction opposite to the conveyance direction A of the recording paper 5. When the recording width is long, the beam structures 1, 10, 20 arranged in a plurality of arrays at once are manufactured in a plurality of arrays having a shorter length than the beam structures 1, 10, 20 are manufactured for the recording width. It is more productive to connect the two to make the recording width.

  A plurality of beam structures 1, 10, and 20 may be provided in the conveyance direction A of the recording paper 5. In the above invention, if the amount of ink adhering to the beam structures 1, 10 and 20 in one recording process is too large, the load on each beam structure may increase and the beam structure may not operate normally. is there. On the contrary, if the amount of adhering ink is small, the density of the ink dots on the recording paper 5 is insufficient, and the image density may be lowered. Therefore, by providing a plurality of the beam structures 1, 10, 20 in the array in the conveyance direction A of the recording paper 5, a plurality of beams can be obtained even with an ink amount that allows the vibration operation of the beam structure to operate normally. It is possible to prevent a decrease in density by repeatedly applying ink to the same dot position on the recording paper 5 in the structure. FIG. 12 shows one of the specific examples. In this example, the arrayed beam structures 1, 10, and 20 are arranged in the transport direction A of the recording paper 5 at intervals of 1/3 of the recording pitch (a ) (B) (c) are provided in order.

(Configuration of cantilever beam structures arranged in an array)
A P (VDF-TrEF) copolymer film (thickness 40 μm) patterned with a common electrode at the bottom and an individual electrode with a width of 80 μm at the top is processed by laser processing along the upper individual electrode, as shown in FIG. Slit processing is performed at 20mm, and lead wires are formed on individual electrodes. Two of these beam structures were arranged with an interval of 5 mm. P (VDF-TrEF) is an abbreviation for Poly (vinylidene Fluoride-trifluoroethykene) Copolymer, and indicates a vinylidene fluoride-trifluoroethylene copolymer.
Ink: Oil-based ink consisting of 15% by weight of pigment (carbon black) and 85% by weight of olefin solvent. Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material. The recording paper 5 (coated paper) is conveyed by 104, the gap between the ink fountain 8 serving as the ink supply means and the recording paper 5 is adjusted to 500 μm by adjusting the position of the roller 101, and the beam structure is arranged in the middle. .
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 5 Hz and a voltage of 300 V, a dot row having a dot diameter of about 200 μm could be formed on the paper.

  In order to increase the resolution, if the width of the beam structure is shortened, the ink conveying force is lowered, and the image density is lowered as described above. Therefore, the resolution can be increased by using a beam structure having a width that can maintain an ink adhesion amount with a sufficient image density and providing a plurality of low-resolution array beam structures in a staggered manner.

(Configuration of cantilever beam structures arranged in an array)
A P (VDF-TrEF) copolymer film (thickness 40 μm) patterned with a common electrode on the bottom and an individual electrode with a width of 170 μm on the top is slit along the upper individual electrode by laser processing as shown in FIG. Lead wires are formed on individual electrodes. Two of these beam structures are used and arranged with a shift of about 40 μm.
・ Ink: Oil-based ink consisting of 30% by weight of rosin-modified phenolic resin, 15% by weight of pigment (carbon black), and 55% by weight of olefinic solvent. The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown, and the gap between the ink fountain 8 serving as the ink supply means and the recording paper 5 is adjusted to 100 μm by adjusting the position of the roller 101. The beam structure was placed.
Implementation Results In such a configuration, when the recording paper 5 is conveyed while applying a pulse to the beam structure at a frequency of 5 Hz and a voltage of 300 V, a dot row having a dot diameter of about 150 μm is formed on the paper with twice the image resolution. did it.

A configuration in the case of having a plurality of colors of ink will be described.
In this case, when the plurality of arrayed beam structures are provided for each color in the recording apparatuses 100 and 200, a color recording apparatus is configured. For each color, process colors such as yellow, cyan, magenta, and black, and complementary colors such as blue, green, and red, and inks with different densities in each color are mounted on multiple array beam structures to achieve natural image quality. Can be obtained. In FIG. 16A, reference numerals 1Y, 1M, 1C, and 1K denote beam structures that supply yellow, cyan, magenta, and black inks, respectively. These beam structures are arranged at intervals in the conveyance direction A of the recording paper 5.

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of an acrylic resin elastomer sheet having a thickness of 50 μm, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG.
-Ink: Oil based ink consisting of 15 wt% pigment and 85 wt% olefin solvent for each color of Y, M, C, K. Impregnated porous urethane foam material with the above ink and fixed to aluminum material Fig. 16 The recording apparatus 100 shown in FIG. 8 is provided with the structure shown in FIG. Was adjusted to 100 μm, and the beam structure was disposed in the middle.
Implementation results The beam structures 1Y, 1M, 1C, and 1K are arranged in the transport direction A at intervals of 30 mm for each color of Y, M, C, and K, and pulses are applied at a frequency of 10 Hz and a voltage of 1 kV. When the recording paper was conveyed while being applied to the recording medium, a dot row of each color having a dot diameter of about 150 μm could be formed on the paper.

  In the recording apparatus provided with the arrayed beam structure for each of a plurality of colors, when the ink adhered on the recording paper 5 passes through the arrayed beam structure of the next color without being dried, the colors are mixed, and There is a possibility that tailing occurs in the image dots, leading to degradation of image quality. Therefore, an ink fixing means is provided at a position after recording with one array-like beam structure. That is, an ink fixing unit for the recording paper 5 is provided between the arrayed beam structures 1Y, 1M, 1C, and 1K for each color.

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of a polyurethane resin elastomer sheet having a thickness of 50 μm, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG.
-Ink: Water-based ink of 1 wt% of each color dye- Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material Array beam structures 1Y, 1M, 1C, 1K having ink fixing means are shown in FIG. And the recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, 104, and the gap between the ink fountain 8 serving as the ink supply means and the recording paper 5 is set to the position of the roller 101. The beam structures 1Y, 1M, 1C, and 1K were respectively arranged in the middle of the adjustment.

As the ink fixing means, those having a function of drying ink are effective. For example, a plurality of heating elements 70Y, 70M, 70C, and 70K may be disposed as shown in FIG. In this embodiment, a rod-like halogen lamp set so that the surface of the recording paper 5 is 50 ° C. is used as a heating element.
As shown in FIG. 16 (a), beam structures 1Y, 1M, 1C, and 1K are arranged for each color in the transport direction A of the recording paper 5 at intervals of 100 mm, and pulses are applied at a frequency of 10 Hz and a voltage of 1 kV. When the recording paper 5 was conveyed while being applied to the structure, a dot row having a dot diameter of about 150 μm could be formed on the recording paper. Further, when the external line lamp was turned on, the ink 4 was immediately dried, and thus no abnormal image due to color mixing occurred.

  As the ink fixing means, instead of each heating element, as shown in FIG. 16B, roller-like members 71Y, 71M, 71C, 71K having ink solvent absorbability may be provided so as to contact the recording paper 5. . As the ink fixing means, the simplest configuration is that the roller-like members 71Y, 71M, 71C, 71K are simply provided at positions after image dot recording with the ink 4. At this time, if these rollers are members having ink solvent absorbability, the ink solvent adhering to the recording paper 5 due to contact with the rollers is absorbed by the roller-like member, and the ink is immediately fixed on the paper. Also, if the ink solvent is saturated in the roller-like member while recording many times, the ink can be fixed by evaporating the saturated ink solvent by means such as periodically heating the roller in the device. The durability of the means will also be improved.

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of a 50 μm thick silicone resin elastomer sheet, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG.
・ Ink: Oil-based ink consisting of 5% by weight of rosin-modified phenolic resin, 15% by weight of pigment (carbon black) and 80% by weight of olefinic solvent. Means: Rubber roller wrapped with chloroprene rubber (hardness 50 degrees) (length: printing width, roller diameter 40 mm)
The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown in FIG. 8, and includes the ink supply means and the ink fixing means, and the gap between the ink fountain 8 and the recording paper 5 serving as the ink supply means. The position of the roller 101 was adjusted to 500 μm, and the beam structure was disposed in the middle.
Implementation Results In such a configuration, when paper was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 1 kV, a dot row having a dot diameter of about 150 μm could be formed on the paper. Further, when the printed material was rubbed with a finger, no ink adhered to the finger.

  In the ink absorption type ink fixing means as in Example 7, a member having a polyorganosiloxane skeleton is suitable as a member that absorbs the ink solvent and does not adhere to the roller.

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of a 50 μm thick silicone resin elastomer sheet, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG.
・ Ink: Oil-based ink consisting of 5% by weight of rosin-modified phenolic resin, 15% by weight of pigment (carbon black) and 80% by weight of olefinic solvent. Means: Rubber roller wound with silicone rubber (hardness 50 degrees) (length: printing width, roller diameter 40 mm)
The recording paper 5 (coated paper) is transported by the transport rollers 102, 103, and 104 shown in FIG. 8, and includes the ink supply means and the ink fixing means. The gap between the ink fountain 8 serving as the ink supply means and the recording paper 5 is provided. The position of the roller 101 was adjusted to 100 μm, and the beam structure was disposed in the middle.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 1 kV, a dot row having a dot diameter of about 150 μm could be formed on the recording paper. Further, when the printed material was rubbed with a finger, no ink adhered to the finger.

  In the cantilever structure, an ink holding member may be provided at the tip. For example, a specific example is shown in FIG. In this example, the ink is water-soluble, and a hydrophilic portion 35 is formed at the tip 1A of the beam structure 1 that is a cantilever structure. As this forming method, it is suitable to roughen the tip 1A or coat a hydrophilic resin. When the ink is oily, an oleophilic part is formed at the tip 1 </ b> A of the beam structure 1. As this forming method, it is suitable to roughen the tip 1A or coat with a lipophilic resin.

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of a 50 μm thick silicone resin elastomer sheet, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG. Thereafter, the tip of the beam structure was roughened.
・ Ink: Oil-based ink consisting of 5% by weight of rosin-modified phenolic resin, 15% by weight of pigment (carbon black) and 80% by weight of olefinic solvent. ・ Ink supply member: impregnated with the above ink in porous urethane foam and fixed to aluminum The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown, and the ink supply means is provided, and the gap between the ink fountain 8 serving as the ink supply means and the recording paper 5 is adjusted to adjust the position of the roller 101. The beam structure was placed in the middle.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 1 kV, a dot row having a dot diameter of about 150 μm could be formed on the recording paper. Furthermore, the variation in dot diameter was within ± 10 μm. Conventionally, it was about ± 20 μm, so the variation was halved.

  In the cantilever beam structure, a slit may be provided at the tip of the beam structure to hold the ink. For example, as shown in FIGS. 1 (a) and 13 (a), by providing the slit 2, the ink 4 can be held in the slit by capillary force. In this case, if the slit 2 is lengthened, a large amount of holding can be obtained, the role of an ink buffer can be obtained, and the amount of adhesion at each time can be stabilized. Further, the ink holding means is not limited to the slit 2, and a fine hole 21A may be formed at the tip 1A as shown in FIG. 13 (b).

(Configuration of cantilever beam structures arranged in an array)
A P (VDF-TrEF) copolymer film (thickness 40 μm) patterned with a common electrode at the bottom and individual electrodes with a width of 170 μm at the top is subjected to laser processing along the upper individual electrode with a beam length of 20 mm as shown in FIG. Slit processing was applied. Further, as shown in FIG. 13A, the slits 2 were formed for each beam with a width of 20 μm and a length of 15 mm. A lead wire was formed on the individual electrode for each beam, and two beam structures were arranged with an interval of 5 mm.
-Ink: Oil-based ink consisting of 15 wt% pigment (carbon black) and 85 wt% olefin solvent-Ink supply member: A porous urethane foam material impregnated with ink is attached to the base of the beam structure, and each beam is subjected to capillary force Ink can be supplied to the tip.

The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown in FIG. 8, and the ink supply means is provided, and the gap between the leading end of the slit beam structure and the recording paper 5 is set at the position of the roller 101. Was adjusted to be 100 μm.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 300 V, a dot row having a dot diameter of about 150 μm could be formed on the recording paper. Further, the dot diameter variation during continuous printing was suppressed to within ± 10 μm.

  In the double-supported beam structure, an ink holding member may be provided at the center of the beam structure. When the ink is water-soluble, a hydrophilic portion is formed in the central portion 20A of the beam structure 20 that is a double-supported beam structure. As a forming method, it is suitable to roughen the central portion 20A or coat a hydrophilic resin. When the ink is oily, an oleophilic part 45 is formed in the central part 20A of the beam structure 20, as shown in FIG. As a forming method, it is suitable to roughen the center portion or coat a lipophilic resin.

(Structure of a beam structure with both ends arranged in an array)
A P (VDF-TrEF) copolymer film (thickness 40 μm) patterned with a common electrode at the bottom and an individual electrode with a width of 80 μm at the top is laser processed along the upper individual electrode at a beam length of 20 mm as shown in FIG. Slit processing was performed, and further, a polyvinyl alcohol resin was coated on the center of the beam, and then lead wires were formed on the individual electrodes. Two of these beam structures were arranged with an interval of 5 mm.
-Ink: Water-based ink consisting of 1 wt% of dye-Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material. Recording paper 5 (coated paper) is fed by conveyance rollers 102, 103, 104 shown in FIG. The ink supply means was provided, the position of the roller 101 between the ink supply means and the paper was adjusted to a gap of 100 μm, and the beam structure was placed in the middle.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 300 V, a dot row having a dot diameter of about 150 μm could be formed on the recording paper. Furthermore, the variation in dot diameter was within ± 10 μm. Conventionally, it was about ± 20 μm, so the variation was halved.

  In the double-supported beam structure, as shown in FIG. 14A, a slit 46 is provided in the central portion 20A of the beam structure 20 in place of the ink hole 21 shown in FIG. Also good. Thus, by providing the slit 46 in the central portion 20A of the beam structure 20, the ink 4 can be held in the slit 46 by capillary force. In this case, if the slit 46 is made long, the holding amount can be increased, the role of the ink buffer can be taken, and the adhesion amount at each time is stabilized.

(Structure of a beam structure with both ends arranged in an array)
A P (VDF-TrEF) copolymer film (thickness 40 μm) patterned with a common electrode at the lower part and an individual electrode with a width of 170 pitch on the upper part along the upper individual electrode by laser processing, as shown in FIG. 10, the beam length L: 20 mm In addition, a slit having a width of 20 μm and a length of 1 mm was processed instead of the ink hole 21 at the center of the beam to form lead wires on the individual electrodes. Two of these beam structures were arranged with an interval of 5 mm.

Ink: Oil-based ink consisting of 15% by weight of pigment (carbon black) and 85% by weight of olefin solvent. Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material. The recording paper 5 (coated paper) is conveyed by 104, provided with the above ink supply means, the position of the roller 101 is adjusted to set the gap between the ink supply means and the recording paper 5 to 100 μm, and the beam structure 20 in the middle. Arranged.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 300 V, a dot row having a dot diameter of about 150 μm could be formed on the recording paper. Further, the dot diameter variation during continuous printing was suppressed to within ± 10 μm.

  Next, the viscosity of the ink 4 in the present invention will be described. The viscosity of the ink 4 is in the range of 0.1 Pa · s to 10 Pa · s. This is advantageous in that the higher the ink viscosity is, the more difficult it is to spread when adhering to the recording paper 5, so that the occurrence of bleeding can be suppressed. However, if the viscosity of the ink 4 is too high, it is difficult for the ink 4 to separate from the ink fountain 8, which may lead to malfunction of the beam structure. As a result of intensive studies on the relationship between the various beam structures described in the embodiments and the ink viscosity, the present inventors have found that the ink 4 has a viscosity of 0.1 Pa · s to 10 Pa · s. It has been found that such a problem does not occur.

(Configuration of cantilever beam structures arranged in an array)
A P (VDF-TrEF) copolymer film (thickness 40 μm) patterned with a common electrode at the bottom and an individual electrode with a width of 80 μm at the top is processed by laser processing along the upper individual electrode with a beam length of 20 mm as shown in FIG. Slits are formed and lead wires are formed on individual electrodes. Two of these beam structures were arranged with an interval of 5 mm.
Ink: 1-30 wt% of rosin-modified phenolic resin, 15 wt% of pigment (carbon black), 45-55 wt% of olefin solvent (viscosity at 25 ° C. measured with L-type viscometer) is 0.003 Pa. Trial production of oil-based ink of s to 1 Pa · s, ink supply member: porous urethane foam material impregnated with the above ink and fixed to aluminum material Recording paper 5 (coated paper) by conveying rollers 102, 103, and 104 shown in FIG. The ink supply means is provided, the position of the roller 101 is adjusted, the gap between the ink supply means and the recording paper 5 is set to 100 μm, and the beam structure 20 is disposed in the middle.
Implementation Result In such a configuration, when the recording paper 5 is conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 300 V, the viscosity of the ink 4 is approximately 0.001 Pa · s to 1 Pa · s. Within the range, the dot diameter could be formed on the recording paper 5.

  When the viscosity of the ink 4 is in the range of 0.001 Pa · s to 1 Pa · s, the ink 4 may contain a resin, a pigment, and an organic solvent. In the case of non-coated paper, the water-soluble ink does not penetrate uniformly into the recording paper 5, the roundness and size of image dots vary, and the image quality depends on the paper type. On the other hand, an ink containing a resin, a pigment, and an organic solvent can suppress the penetration of the resin into the recording paper 5 and can improve the water resistance by using a pigment. Furthermore, when the ink is adhered to each beam structure, the ink containing the resin, the pigment, and the organic solvent has high cohesive strength of the ink, so that the ink tends to be on the hemisphere on the beam structure, This is advantageous for making the dot diameter uniform.

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of a 50 μm thick silicone resin elastomer sheet, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG.
・ Ink: Oil-based ink consisting of 30% by weight of alkyd resin, 15% by weight of pigment (carbon black), 55% by weight of paraffinic solvent. ・ Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material. The recording paper 5 (coated paper) is conveyed by rollers 102, 103, and 104, provided with the ink supply means, and the position of the roller 101 is adjusted so that the gap between the ink supply means and the recording paper 5 is 30 μm. The beam structure was placed.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 30 V, a dot row having a dot diameter of about 150 μm could be formed on the recording paper.

  When the viscosity of the ink 4 is in the range of 0.001 Pa · s to 1 Pa · s, the ink 4 may contain a water retaining member, a coloring material, and water. Oil-based inks have the advantage that they are difficult to dry while being left in the recording apparatus, but they have the disadvantage that they cause significant bleeding on recording paper such as high-quality paper due to low surface tension. Therefore, in order to increase the surface tension, water was used as the ink solvent, and in order to prevent drying during storage of the apparatus, a water retention member was added to the ink, and drying was prevented by capturing moisture in the air.

  Each of the beam structures 1, 10, and 20 is composed of a member that bends and moves by self-contraction / expansion. As a bending method of the beam structure, a method of bending the beam by electrostatic force or magnetic force with the force of an electrostatic field or a magnetic field can be considered. There is a risk of malfunction due to crosstalk. On the other hand, it is preferable that the beam itself bends due to self-contraction / expansion because the structure is simple and the crosstalk is strong. As the material that contracts and expands itself, a material that utilizes thermal contraction and expansion, a material that utilizes the piezoelectric effect, and the like are suitable.

(Structure of a beam structure with both ends arranged in an array)
A common electrode is formed in the lower part, and a laminated PZT (thickness: 1000 μm) having a length of 170 μm and a width of 30 mm is formed on the upper part along the upper individual electrode with a dicing saw, as shown in FIG. After that, the entire beam was coated with polyamide resin to give insulation.-Ink: Oil-based ink containing 10 wt% of pigment-Ink supply member: Porous urethane foam material was impregnated with the above ink and fixed to aluminum material Figure 11 The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown in the figure, provided with the ink supply means, and the position of the roller 101 is adjusted so that the gap between the ink supply means and the recording paper 5 is 30 μm. The beam structure was placed in the middle.
Implementation Results According to such a configuration, when paper was conveyed while applying a pulse to the beam structure at a frequency of 10 Hz and a voltage of 100 V, a dot row having a dot diameter of about 150 μm could be formed on the paper.

  As a member that bends and moves by self-shrinkage and expansion used for the beam structures 1, 10, and 20, an electric field responsive polymer material can be given. An electric field responsive polymer material is a material in which the length and volume of the material itself change greatly when an electric field is applied. As a particularly suitable material, a fluorine-based ferroelectric polymer material such as polyvinylidene fluoride (PVDF) or vinylidene fluoride-trifluoroethylene copolymer (P (VDF-TrFE)) is suitable. When an electric field is applied, these materials expand and contract due to the piezoelectric effect and deform. In addition, dielectric elastomers such as silicone resins and acrylic resins are one of the suitable materials, and deformation called Maxwell stress has the property of contracting in the direction of the electric field in a strong electric field and expanding in the direction perpendicular to the electric field. Deforms by force. Since these materials are high polymers, they can be easily manufactured in sheet form, and since the materials are soft, as shown in FIG. Suitable for

(Configuration of cantilever beam structures arranged in an array)
Gold electrodes were formed on both surfaces of a 50 μm thick silicone resin elastomer sheet, and then the arrayed beam structure was processed with a cutter knife at a pitch of 170 μm and a length of 10 mm as shown in FIG.

・ Ink: Oil-based ink consisting of 5% by weight of rosin-modified phenolic resin, 15% by weight of pigment (carbon black) and 80% by weight of olefinic solvent ・ Ink supply member: Impregnated porous ink with the above ink and fixed to aluminum The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown, provided with the ink supply means, and the position of the roller 101 is adjusted so that the gap between the ink supply means and the recording paper 5 is 500 μm. The beam structure was placed in the middle.
Implementation Results In such a configuration, when the recording paper 5 was conveyed while applying a pulse to the beam structure at a frequency of 5 Hz and a voltage of 1 kV, a dot row having a dot diameter of about 150 μm could be formed on the recording paper.

  The member that bends and moves by self-contraction / expansion used for the beam structures 1, 10, and 20 may have a unimorph or bimorph structure of a shape memory alloy and a silicon substrate on which a silicon oxide film is formed. As the shape memory alloy, a Ti—Ni binary alloy thin film or a Ti—Ni—Pd ternary alloy thin film is suitable. After forming a silicon oxide film on a silicon substrate, these alloys are sputter-deposited on the silicon substrate to form a unimorph structure or a bimorph structure. And it cuts into the shape of a some array-like beam structure with a dicing saw.

  The beam structure processed in this manner is warped (bent) at room temperature due to the difference in thermal shrinkage between the silicon substrate and the shape memory alloy. And if it heats in this state, a shape memory alloy will change into a phase, stress will be relieved, and it will change to a straight state. In other words, according to the image signal, the beam structure can be heated and cooled to adhere ink to the recording paper 5 while bending the beam structure.

(Configuration of cantilever beam structures arranged in an array)
A silicon oxide film having a thickness of 1 μm was formed on a silicon substrate having a thickness of 500 μm, and a Ti—Ni shape memory alloy was formed by 2 μm thereon by sputtering deposition. Thereafter, a beam structure having a plurality of beams was processed with a diamond abrasive dicing saw into a shape as shown in FIG. Further, a thermal element was formed on the beam structure by screen printing, and aluminum electrodes were deposited on both ends of the thermal element.

-Ink: Water-based ink containing 1 wt% of dye-Ink supply member: Porous urethane foam material is impregnated with the above ink and fixed to aluminum material. Recording paper 5 (coated paper) is fed by conveyance rollers 102, 103, 104 shown in FIG. The ink supply means was provided, the position of the roller 101 was adjusted, the gap between the ink supply means and the recording paper 5 was set to 100 μm, and the beam structure was arranged in the middle. The thermal element formed on the beam structure was driven at a driving frequency of 5 Hz, and the voltage was set so that the surface temperature of the thermal element was 150 ° C. A thermal element was driven according to the image signal, and a dot row of 100 μm size could be formed on plain paper.

  The beam structure may be composed of an electrostatic actuator. As shown in FIG. 15, a plurality of arrayed beam structures 60 are used as individual electrodes, and a grounded counter electrode 61 is provided at a position facing the individual electrodes, thereby forming a parallel electrode. When a drive voltage is applied to the individual electrodes in accordance with the image signal, the individual electrodes are bent by the electrostatic force acting between the parallel electrodes and come into contact with the recording paper.

(Configuration of cantilever beam structures arranged in an array)
As shown in FIG. 15, a grounded common electrode of nickel foil with an insulating coating on the top, an individual electrode with a width of 80 μm formed on a nickel foil with a thickness of 50 μm at the bottom, and lead wires are provided on the individual electrodes. Formed. The distance between the lower electrode and the upper electrode was set to 100 μm. ・ Ink: Oil-based ink consisting of 15 wt% of pigment (carbon black) and 85 wt% of olefin solvent. ・ Ink supply member: Porous urethane foam material impregnated with the above ink into aluminum material Fixing The recording paper 5 (coated paper) is conveyed by the conveying rollers 102, 103, and 104 shown in FIG. 8 and includes the ink supply means. The position of the roller 101 is adjusted so that the gap between the ink supply means and the recording paper 5 is increased. The beam structure 60 was arranged in the middle of 50 μm. Then, it was driven at a driving frequency of 10 Hz and a voltage of 50 V, and a dot row of 100 μm size could be formed on plain paper.

  The beam structures 1, 10, 20, and 60 are preferably manufactured by laser cutting. As the type of laser, it is preferable to perform processing using a cutting laser such as a YAG laser, a CO2 laser, or an excimer laser.

It is a perspective view which shows one form of the cantilever structure used for the recording apparatus of this invention. It is an expansion perspective view which shows the structure of the beam structure arranged in the array form. It is a schematic diagram which shows the outline of operation | movement of a cantilever structure. It is a perspective view which shows the various forms of the beam structure arranged in the array form. It is a schematic diagram which shows the recording principle and operation | movement by a cantilever structure. It is a figure which shows the relationship between the recording head which has a beam structure, and a recording medium. FIG. 7 is an internal perspective view illustrating a schematic configuration of the recording head illustrated in FIG. 6. 1 is a cross-sectional view showing a schematic configuration of a recording apparatus to which a cantilever beam structure according to an embodiment of the present invention is applied. It is a schematic diagram which shows a structure, recording principle, and operation | movement of a both-ends support beam structure. It is a perspective view which shows one form which arranged the double-supported beam structure in the array form. 1 is a cross-sectional view illustrating a schematic configuration of a recording apparatus to which a doubly supported beam structure according to an embodiment of the present invention is applied. It is a figure which shows the various forms which have arrange | positioned the beam structure in the conveyance direction of a recording medium. It is an enlarged view which shows the various forms of the ink holding means provided in the cantilever structure. It is an enlarged view which shows various forms of the ink holding means provided in the both-end-supported beam structure. It is a perspective view which shows one form of the beam structure which has an electrostatic actuator. It is a perspective view which shows the structure of the beam structure provided facing several ink colors, and various forms of an ink adhering means.

Explanation of symbols

1, 10, 60 Beam structure (cantilever structure)
1A, 10A Cantilever tip 1 (Y, M, C, K) Beam structure corresponding to multiple colors 2, 46 Slit 3, 8 Ink supply means 4 Ink 5 Recording medium,
20 Beam structure (both-end beam structure)
20A Center part of both-end supported beam structure 21A, 35 Ink holding means 24, 45 Ink holding means 101, 102, 103 Conveying means 61 Electrostatic actuator 70 (Y, M, C, K) Ink fixing means 71 (Y, M , C, K) Ink fixing means (roller-like member)
100, 200 Recording device A Recording medium conveyance direction

Claims (23)

A plurality of beam structures arranged in an array capable of bending motion, means for supplying ink to the beam structures, and means for conveying a recording medium,
A recording apparatus that forms an image by bending the beam structure in accordance with an image signal, bringing the beam structure into contact with the recording medium, and transferring the ink onto the recording medium. The recording apparatus according to claim 1,
The beam structure is a cantilever structure, the tip of the cantilever is bent according to an image signal, the beam structure is brought into contact with the recording medium, and the ink is transferred onto the recording medium. A recording apparatus for forming an image. The recording apparatus according to claim 1,
The beam structure is a doubly-supported beam structure, and the central portion of the both-end supported beam is bent according to an image signal to contact the recording medium, and the ink is transferred onto the recording medium. And a recording apparatus for forming an image. A plurality of beam structures arranged in an array capable of bending motion; means for supplying ink to the beam structures; and means for transporting a recording medium; and the beam structures according to an image signal A recording apparatus for forming an image by bending the ink and bringing it into contact with a recording medium and transferring the ink onto the recording paper,
According to an image signal, the arrayed beam structure is alternately brought into contact with the recording medium for each adjacent structure to form an image by transferring the ink onto the recording medium. Recording device. The recording apparatus according to claim 1,
A recording apparatus comprising a plurality of the beam structures in a direction opposite to a conveying direction of the recording medium The recording apparatus according to claim 1,
A recording apparatus comprising a plurality of the beam structures in the conveying direction of the recording medium The recording apparatus according to claim 6, wherein
The recording apparatus, wherein the plurality of beam structures are arranged in a staggered manner. The recording apparatus according to claim 6, wherein
A recording apparatus having a plurality of colors of the ink and provided with the plurality of beam structures for each color. The recording apparatus according to claim 8, wherein
A recording apparatus comprising ink fixing means for the recording medium between the beam structures for each color. The recording apparatus according to claim 9, wherein
The recording apparatus according to claim 1, wherein the ink fixing means is means for bringing a roller-shaped member having ink solvent absorbability into contact with the recording medium. The recording apparatus according to claim 10.
The recording apparatus, wherein the ink fixing means comprises a member having a polyorganosiloxane skeleton. The recording apparatus according to claim 2, wherein
An ink holding unit is provided in the beam structure. The recording apparatus according to claim 2, wherein
A recording apparatus characterized in that a slit is provided in the beam structure to supply and hold the ink by capillary force. The recording apparatus according to claim 3, wherein
An ink holding means is provided at the center of the beam structure. The recording apparatus according to claim 4.
A recording apparatus, wherein a slit is provided in the beam structure to supply and hold the ink. The recording apparatus according to claim 1,
A recording apparatus wherein the viscosity of the ink is in the range of 0.001 Pa · s to 1 Pa · s. The recording apparatus according to claim 16, wherein
The recording apparatus according to claim 1, wherein the ink contains a resin, a pigment, and an organic solvent. The recording apparatus according to claim 16, wherein
The recording apparatus, wherein the ink contains a water retention member, a coloring material, and water. The recording apparatus according to claim 1,
The recording apparatus according to claim 1, wherein the beam structure is configured by a member that bends and moves by self-contraction and expansion by an electric field, a magnetic field, or heat. The recording device according to claim 19, wherein
A recording apparatus, wherein the beam structure is made of an electric field responsive polymer material. The recording device according to claim 19, wherein
The recording apparatus, wherein the beam structure is formed of a unimorph or bimorph structure of a shape memory alloy and a silicon substrate on which a silicon oxide film is formed. The recording apparatus according to claim 1,
The recording apparatus, wherein the beam structure is constituted by an electrostatic actuator. The recording apparatus according to claim 1,
The recording apparatus according to claim 1, wherein the plurality of beam structures arranged in an array capable of bending motion are manufactured by laser cutting.

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