JP2011040562A - Device and method for drawing line - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a line drawing device and method, capable of stably forming a linear pattern with a uniform width by suppressing bulge and jaggy. <P>SOLUTION: The linear pattern is formed by sequentially discharging a liquid (16) containing a functional component and having the effect of curing by irradiation with active light beam toward a non-permeable medium (12) from an ink jet head (18), and mutually combining such landed droplets on the medium (12). In this case, the droplet shooting is controlled so that a following droplet to be further combined with a group of droplets landed on the medium (12) first is landed before the group reaches an equilibrated state. When the liquid on the medium (12) is cured by irradiation with active light beam (22), the irradiation with the active light beam (22) is performed so that the time T[s] between the landing of the final landed droplet constituting the linear pattern and the curing of the linear pattern satisfies T≤äπ/(6θ)}<SP>3</SP>, wherein θ[rad] is the contact angle of the liquid (16) to the medium (12). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a line drawing apparatus and a line drawing method, and more particularly to a line drawing technique suitable for forming a linear pattern on the surface of a non-permeable medium using an inkjet head.

  Patent Document 1 discloses a pattern forming system that draws a wiring pattern on a tape-shaped substrate by an inkjet head group while moving the tape-shaped substrate wound around a reel by a reel-to-reel method. Yes. According to the literature 1, the liquid (the dispersion containing conductive fine particles) discharged onto the tape-shaped substrate loses its fluidity, and after the liquid is temporarily dried, the tape-shaped substrate is wound up, There is a description to prevent deformation due to fluid flow.

  In Patent Document 2, for the purpose of forming a substantially circular film on a substrate by an inkjet method, droplets are ejected onto a substantially square region (for example, 3 × 3 pixels), and the effect of the surface tension of the droplets is applied. Thus, the droplets are integrated on the substrate. In this case, the droplets are ejected onto each pixel so that the droplets partially overlap each other while the droplets have fluidity on the substrate.

  In Patent Document 3, in a method of forming a functional film pattern by discharging a liquid containing a functional component such as conductive fine particles onto a substrate by an inkjet method, excessive wetting and spreading of droplets after landing on the substrate is disclosed. From the viewpoint of suppressing and preventing pattern defects, a configuration is disclosed in which the liquid is applied onto a substrate having a film formation surface with a contact angle with respect to the liquid of 30 [deg] or more and 60 [deg] or less.

  In addition, in relation to a technique for suppressing bulges (liquid puddles) and jagged edges (jagged edges) in ink jet drawing, Non-Patent Document 1 discloses that a substrate that gels a polymer that gels at a predetermined temperature is printed on a substrate. There is a description that no bulge was generated when the temperature was equal to or higher than the gelation temperature (transition temperature).

Japanese Patent No. 4161964 JP 2006-95381 A JP 2003-80694 A

J. Mater. Chem. “Geometric control of inkjetprinted features using gelating polymer”, 2007, 17, 677-683

  When a line is drawn by ejecting a liquid onto a substrate on which the liquid is not soaked (not penetrating), depending on the interval and amount of droplets deposited on the substrate, a part of the line has a bumpy shape. A bulge due to a puddle (bulge) may occur, or the contour of the line may not be smooth, and jagged irregularities (jaggy) may occur.

  Patent Document 1 describes fluidity removal by drying, but there is no description about the landing time interval of droplets, and the occurrence of periodic bulges and jaggies cannot be suppressed as it is. On the other hand, the technique of Patent Document 2 solves a problem in forming a circular or elliptical pattern. If the technical contents shown in Patent Document 2 are used as they are, a large bulge is generated during line drawing. I cannot suppress it.

  Further, in the pattern forming apparatus described in Patent Document 3, the dot pitch may vary due to the accuracy of the landing position (ejection direction) by the inkjet head, the accuracy of the droplet amount, and the accuracy of the transport position of the substrate. For this reason, with the method described in Patent Document 3, it is not always possible to suppress the occurrence of jaggies, and it is difficult to stably draw a line having a uniform width.

  Non-Patent Document 1 also does not describe the droplet landing time interval and cannot necessarily suppress the occurrence of periodic bulges and jaggies.

  The present invention has been made in view of such circumstances, and provides a line drawing apparatus and a line drawing method capable of suppressing the occurrence of bulges and jaggies and stably forming a linear pattern having a uniform width. For the purpose.

  In order to achieve the above object, the following invention modes are provided.

  (Invention 1): A line drawing apparatus according to Invention 1 includes a functional component and an inkjet head that ejects a liquid that has a function of curing when irradiated with actinic rays, and a droplet ejected from the inkjet head. A non-penetrable medium to be moved and a moving means for relatively moving the ink jet head, a control means for controlling droplet ejection from the ink jet head, and irradiating the liquid deposited on the medium with the actinic ray. Active light irradiation means for curing the liquid on the medium, and the control means sequentially discharges the droplets having a difference in landing time between the ink jet heads toward the medium. In forming a linear pattern by uniting the above, before the aggregate of droplets that have landed first reaches an equilibrium state on the medium, The droplet ejection is controlled so that the next droplet to be further united with the aggregate is landed, and when the contact angle of the liquid with respect to the medium is θ [rad], the active light irradiation means The time T [s] from the time of landing of the final landing droplet to the time when the linear pattern is cured is expressed by the following equation:

It is characterized by satisfying.

  According to the present invention, a group of droplets that have landed sequentially on a non-permeable medium are collected, and eventually reach an equilibrium state to form a linear pattern. At this time, the occurrence of jaggy is suppressed by landing the next droplet before the droplet group associated with the first landing is fully spread out (before reaching the equilibrium state) and coalescing with the aggregate. it can. Further, since the curing process is performed within a short time after the linear pattern is deposited, the occurrence of bulge can be suppressed. Thus, according to the present invention, it is possible to prevent the occurrence of bulges and jaggies and form a line segment with a uniform line width.

  According to experimental findings, if an aggregate (a lump) of landed droplets coalesced on a medium is left as it is for a long time, a part of the line shape swells, and then gradually swells due to a pressure difference due to surface tension. Grows into a big bulge. In this phenomenon, the time at which a part of the linear shape starts to swell after drawing is inversely proportional to the cube of the contact angle, and is about 1 second when the contact angle is 30 ° (π / 6 [rad]). Therefore, it is preferable to cure within 1 second after drawing at a contact angle of 30 ° (π / 6 [rad]). In addition, as actinic light, an ultraviolet-ray, visible light, infrared rays, or these appropriate combinations are possible.

  (Invention 2): The line drawing apparatus according to invention 2 is the line drawing apparatus according to invention 1, wherein the control means is configured such that the landing time interval t [s] of adjacent droplets on the medium is

  The droplet ejection is controlled so as to satisfy the above condition.

  According to experimental findings, the time required for the landing droplets to reach an equilibrium state is inversely proportional to the cube of the contact angle, and when the contact angle is 30 ° (π / 6 [rad]), the landing time difference between adjacent pixels ( The droplet ejection time interval) is preferably within 1 μs.

  (Invention 3): The line drawing apparatus according to Invention 3 is the line drawing apparatus according to Invention 1 or 2, wherein the control means converts the volume of the droplet before landing on the medium into a true sphere. When the diameter is d [μm], the dot pitch p of the droplets adjacent on the medium is given by

The droplet ejection is controlled so as to satisfy the following condition.

  By performing droplet ejection satisfying this condition, it is possible to suppress the occurrence of jaggy.

  (Invention 4): The line drawing apparatus according to the invention 4, in the line drawing apparatus according to any one of the inventions 1 to 3, includes, as the moving means, a medium conveying means for conveying the medium at a constant speed, The active light irradiating means is arranged on the downstream side of the ink jet head in the medium conveying direction by the medium conveying means.

  According to this aspect, the medium on which the drawing is performed by the ink jet head is transported to the position of the actinic light irradiation unit by the medium transport unit, and the curing process is performed.

(Invention 5): The line drawing apparatus according to invention 5 is the line drawing apparatus according to invention 4, comprising, as the moving means, a head moving means for moving the inkjet head in a direction parallel to the medium conveying direction, The head moving means has a distance d _H [between the inkjet head and the actinic light irradiation means in a direction parallel to the medium conveying direction, where v [m / s] is the constant speed by the medium conveying means. m] is the following formula

  The movable range of the inkjet head is limited to satisfy the above condition.

  According to this aspect, even if the ink jet head moves, curing can be performed within a time that satisfies the condition described in [Equation 1].

  (Invention 6): The line drawing apparatus according to the invention 6 is the line drawing apparatus according to the invention 4 or 5, wherein a light shielding member for preventing propagation of active light is provided between the inkjet head and the active light irradiation means. It is characterized by being.

  According to this aspect, it is possible to prevent the liquid in the nozzles of the inkjet head from being cured by actinic rays, and it is possible to prevent nozzle clogging (non-discharge) and ejection failure.

  (Invention 7): The line drawing apparatus according to the invention 7 is the line drawing apparatus according to any one of the inventions 1 to 3, wherein the active light irradiation means irradiates a laser beam toward the medium. The actinic light irradiation means is attached to the ink jet head, and these are integrally moved relative to the medium.

  According to this aspect, it is possible to irradiate laser light immediately after drawing by the ink jet head. Also, since laser light is highly linear and light is difficult to enter the nozzle of the ink jet head, the active light irradiating means is disposed near the ink jet head, and the laser light is irradiated as the active light irradiating means. Is preferred.

  (Invention 8): The line drawing apparatus according to Invention 8 is the line drawing apparatus according to Invention 7, wherein the active light irradiation means is attached under a relative positional relationship of the active light irradiation means with respect to the inkjet head. Only when the inkjet head is moved relative to the medium from the direction in which the inkjet head is present, droplet ejection from the inkjet head is performed.

  In the case of a configuration in which a unit combining an inkjet head and actinic light irradiation means is integrally scanned, in order to irradiate actinic rays within a short time after droplet ejection, the unit moves in the direction of movement when viewed from above the medium. It is preferable to move the unit in such a positional relationship that the inkjet head precedes and the actinic light irradiation means follows.

  That is, the ink jet head is relative to the medium from the direction in which the actinic light irradiation means is attached (rear side toward the head moving direction) to the direction in which the ink jet head is present (front side toward the head moving direction). By performing droplet ejection when moving, actinic rays can be irradiated to the position after droplet ejection.

  (Invention 9): The line drawing apparatus according to the invention 9 is the line drawing apparatus according to any one of the inventions 1 to 8, wherein the actinic ray is ultraviolet light.

  For example, an ultraviolet irradiation means such as a UV lamp or a UV laser can be applied to a functional liquid using a monomer that is polymerized and cured by ultraviolet irradiation (so-called UV curable monomer).

(Invention 10): The line drawing method according to Invention 10 comprises sequentially discharging a liquid containing a functional component and having a function of curing by irradiation with actinic rays from an inkjet head toward a non-permeable medium. A line drawing method for forming a linear pattern by adhering ejected droplet groups to the medium and combining the droplets having a difference in landing time on the medium. The droplet ejection from the inkjet head is controlled so as to land the next droplet to be further coalesced before the aggregate of droplet groups that have reached the equilibrium state on the medium,
When the liquid on the medium is cured by irradiating the liquid attached on the medium with the actinic ray, the linear pattern is formed when a contact angle of the liquid with respect to the medium is θ [rad]. The time T [s] from the time of landing of the final landing droplet to be cured until the linear pattern is cured is

  Irradiation with the actinic ray is performed so as to satisfy the above.

  According to the present invention, the droplet ejection control for landing the next droplet within the time until the liquid landed on the non-permeable medium reaches the equilibrium state, and the activity is performed within a short time after the linear pattern is drawn. By performing curing by irradiation with light rays, it is possible to suppress the occurrence of jaggies and bulges and to form a linear pattern with a uniform thickness (line width).

The side view which shows the structure of the line drawing apparatus which concerns on 1st Embodiment of this invention. Plan view of the line drawing apparatus shown in FIG. Sectional drawing which shows the three-dimensional structure of the droplet discharge element in a recording head The block diagram which shows the control system of the line drawing apparatus concerning this example The figure which shows typically the procedure when drawing the linear pattern L on a board | substrate. The figure which shows typically the time-dependent change of the droplet which was ejected on the substrate Diagram showing stability of line width due to difference in printing frequency A graph showing the wetting and spreading behavior of droplets depending on the contact angle Diagram comparing the presence or absence of bulge generation due to the difference in the time to perform the curing process after drawing the linear pattern A graph examining the relationship between the elapsed time after printing and the bulge width The top view for demonstrating the restriction | limiting of the movement range of the recording head in the line drawing apparatus of this example The figure which shows typically the procedure of the scanning control when drawing the pattern L by relatively scanning the recording head which has many nozzles, and a board | substrate. The side view which shows the structure of the line drawing apparatus which concerns on 2nd Embodiment of this invention. Plan view of the line drawing apparatus shown in FIG. Schematic diagram showing the positional relationship between the recording head and the UV laser irradiation device and the direction of head movement during droplet ejection Schematic diagram showing the positional relationship between the recording head and the UV laser irradiation device and the direction of head movement during droplet ejection

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

<First Embodiment>
[Configuration of line drawing device]
FIG. 1 is a side view showing the configuration of the line drawing apparatus according to the first embodiment of the present invention, and FIG. 2 is a plan view thereof. As shown in these drawings, the line drawing apparatus 10 according to the present embodiment corresponds to a belt 14 (“moving means”, “medium conveying means”) that conveys a substrate 12 (corresponding to “non-permeable medium”). ) And an ink jet head (hereinafter referred to as “recording head”) that ejects a functional liquid (here, a liquid having a function of being cured by ultraviolet rays, hereinafter referred to as “UV ink”) 16 toward the substrate 12. ) 18 and a UV light irradiation device 20 (corresponding to “activation light irradiation means”).

  The substrate 12 is a drawing medium to which the UV ink 16 discharged from the recording head 18 is attached. As the substrate 12, a non-permeable medium represented by a resin or a low-permeable medium having a sufficiently long penetration time is used. In the present specification, these are collectively referred to as “non-permeable medium”. For example, the substrate 12 can be made of various materials such as polyimide, PET (polyethylene terephthalate), glass epoxy, silicon, glass, and metal.

  The belt 14 is an endless belt wound between rollers (not shown), and is driven by a motor (not shown). The substrate 12 held on the belt 14 is transported in the right direction (+ y direction; sub-scanning direction) in FIGS. At the time of drawing, the conveyance speed of the substrate 12 is controlled to be constant. In this example, the belt 14 is employed as the transport means for the substrate 12, but the means for holding and transporting the substrate 12 is not limited to the belt 14. For example, by placing the substrate 12 on a flat plate and moving the substrate 12 together with the plate, or if the flexibility of the substrate 12 permits, the substrate 12 is wound around the drum (cylinder) and the tram is rotated. A form such as moving the substrate 12 is also possible.

  The UV ink 16 is not limited to a color ink suitable for graphic printing, but is used for manufacturing a resist ink (heat resistant coating material) for printed wiring, a dispersion liquid in which conductive fine particles are dispersed in a dispersion medium, and a color filter. There can be various forms, such as ink.

  The recording head 18 has a direction (x-axis direction; main scanning direction) orthogonal to the transport direction (+ y direction) of the substrate 12 in a plane parallel to the surface of the substrate 12 and a direction (y-axis) parallel to the transport direction of the substrate 12. Direction). Although a detailed configuration of a driving mechanism (x-direction moving unit, y-direction moving unit) for moving the recording head 18 is not illustrated, a known unit such as a ball screw or a linear rail can be applied. By moving the recording head 18 in the x-axis direction and in the y-axis direction at the same time, the recording head 18 can be moved in any direction (oblique direction) in the xy plane.

  In addition, a mechanism (rotating unit) that rotates the recording head 18 in the xy plane and a mechanism (z direction moving unit) that moves the recording head 18 in the normal direction (z-axis direction) of the substrate 12 may be provided.

  At the time of drawing, the head position in the z direction is adjusted so that the clearance between the belt 14 and the recording head 18 (that is, the clearance between the substrate 12 surface on the belt 14 and the recording head 18) becomes a predetermined value. The recording head 18 is scanned in the x-axis direction and the y-axis direction while maintaining the above clearance. By moving the recording head 18 in the ± x direction and the ± y direction, the drawing position on the substrate 12 can be changed, and a droplet can be landed at an arbitrary position in the drawing region of the substrate 12. .

  In this example, the UV ink 16 is transferred from the nozzle (reference numeral 32 in FIG. 3) of the recording head 18 while the recording head 18 is moved in the x-axis direction and the y-axis direction while the substrate 12 is conveyed by the belt 14 at a constant speed. By discharging, a straight line in an arbitrary direction can be drawn on the surface of the substrate 12.

  When the recording head 18 is moved in the same direction as the transport direction of the substrate 12 (the + y direction in FIGS. 1 and 2), the maximum value is set as the transport speed of the substrate 12. That is, the recording head 18 can move in the + y direction with the conveyance speed of the substrate 12 as the upper limit.

  The UV light irradiation device 20 is disposed on the downstream side of the recording head 18 in the conveyance direction of the substrate 12. The substrate 12 on which droplets have been ejected (drawn) by the recording head 18 is transported in the y direction by belt transport and sent to the position of the UV light irradiation device 20. When the substrate 12 passes under the UV light irradiation device 20, the UV light irradiation device 20 irradiates the drawing surface of the substrate 12 with ultraviolet rays 22. Thereby, the UV ink on the substrate 12 is cured (solidified).

  When the UV light irradiated from the UV light irradiation device 20 is reflected by the substrate 12 or the belt 14 and the reflected light reaches the ejection surface (nozzle surface) 18A of the recording head 18, the ink in the nozzle is cured. This can cause nozzle clogging (undischarge). In order to cope with such a problem, it is preferable to install a light shielding plate 24 (corresponding to a “light shielding member”) for blocking the UV light between the UV light irradiation device 20 and the recording head 18.

  In the ink jet recording head 18, if the ink is not ejected for a long time, the ink solvent in the nozzles evaporates and becomes highly viscous, resulting in ejection failure and undischarge. In order to deal with such a problem, it is also referred to as preliminary discharge (“purge”, “empty discharge”, “spitting”), or “dummy discharge” outside the drawing area before or during drawing on the substrate 12. ) Is desirable. For this reason, it is preferable that the line drawing apparatus 10 is provided with preliminary ejection regions (also referred to as “purge zones”) 26 and 27 outside the drawing region.

  From the viewpoint of shortening the time from the start of preliminary discharge to the start of drawing on the substrate 12, the preliminary discharge regions 26 and 27 are desirably installed near the substrate 12. Since it is particularly preferable to start printing on the substrate 12 within 1 second after the preliminary discharge, it is desirable to provide the preliminary discharge regions 26 and 27 on both sides of the belt 14 as shown in FIG. With such a configuration, the recording head 18 is moved to the preliminary ejection regions 26 and 27 before the drawing on the substrate 12 is started or, if necessary, during the drawing, and preliminary ejection is performed here.

  FIG. 3 is a cross-sectional view showing a three-dimensional configuration of one channel of droplet ejection elements 30 (ink chamber units corresponding to one nozzle 32) serving as a recording element unit in the recording head 18.

  A pressure chamber 34 provided corresponding to the nozzle 32 communicates with a common flow path 38 via a supply port 36. The common channel 38 communicates with a tank (not shown) that is a liquid supply source, and the liquid supplied from the tank is supplied to the pressure chamber 34 via the common channel 38.

  A piezoelectric element 44 having individual electrodes 42 is joined to a pressure plate (vibrating plate that also serves as a common electrode) 40 constituting a part of the pressure chamber 34 (the top surface in FIG. 3). In addition, as a material of the piezoelectric element 44, for example, a piezoelectric body such as lead zirconate titanate (PZT) or barium titanate can be used.

  When a drive signal is applied between the individual electrode 42 and the common electrode, the piezoelectric element 44 is deformed and the volume of the pressure chamber 34 changes. Ink is ejected from the nozzle 32 by the pressure change accompanying this volume change. When the displacement of the piezoelectric element 44 is restored after ink ejection, new ink is refilled into the pressure chamber 34 from the common flow path 38 through the supply port 36.

  In the present embodiment, the piezoelectric element 44 is applied as the ink discharge force generating means. However, instead of such a discharge method (piezo jet method), a heater is provided in the pressure chamber 34, and a film formed by heating the heater is used. It is also possible to apply a thermal method in which ink is ejected using the boiling pressure.

  Further, the number of nozzles 32 in the recording head 18 and the arrangement form thereof are not particularly limited in the practice of the present invention, and may be configured with only one nozzle, or may be configured with a plurality of nozzles arranged one-dimensionally or two-dimensionally. Also good.

  FIG. 4 is a block diagram showing a control system of the line drawing apparatus 10.

  The line drawing apparatus 10 includes a communication interface 50, a system controller 52, a program storage unit 54, a memory 56, a motor driver 58, a UV light source driver 60, a droplet ejection control unit 62, a buffer memory 64, and a head driver 66.

  The communication interface 50 is an interface unit that receives droplet ejection data sent from the host computer 70. As the communication interface 50, a serial interface such as USB (Universal Serial Bus), IEEE 1394, Ethernet (registered trademark), a wireless network, or a parallel interface such as Centronics can be applied. Note that a buffer memory for speeding up communication may be mounted in this portion.

  The system controller 52 includes a central processing unit (CPU) and its peripheral circuits, and is a control unit that controls each unit of the line drawing apparatus 10 and an arithmetic processing unit that performs various types of arithmetic processing. The system controller 52 performs communication control with the host computer 70, read / write control of the memory 56, and the like, and generates a control signal for controlling light emission of the motor 72 and the UV light source 74 of the transport drive system and the head scanning system.

  The program storage unit 54 stores programs and various data necessary for controlling the line drawing apparatus 10. The system controller 52 appropriately reads out various control programs stored in the program storage unit 54 and executes the programs.

  The memory 56 is a storage means used as a temporary storage area for data and a work area when the system controller 52 performs various calculations. As the memory 56, a magnetic medium such as a hard disk can be used in addition to a memory made of a semiconductor element.

  A motor 72 indicates various motors provided in the apparatus. In addition to the motor that supplies power to the drive mechanism of the belt 14 described in FIGS. 1 and 2, the motor that supplies power to the moving mechanism of the recording head 18. Is included. The motor driver 58 drives the motor 72 in accordance with a control signal from the system controller 52.

  The UV light source 74 is included in the UV light irradiation apparatus 20 described with reference to FIGS. 1 and 2, and is configured by a UV lamp, a laser diode, or the like. The light source driver 60 turns the UV light source 74 on (light emission) / off (light extinction) and adjusts the light emission amount according to a control signal from the system controller 52.

  The droplet ejection data sent from the host computer 70 is taken into the line drawing apparatus 10 via the communication interface 50 and temporarily stored in the memory 56. The droplet ejection control unit 62 has a signal processing function for performing various processing and correction processing for generating a discharge control signal from the droplet ejection data in the memory 56 in accordance with the control of the system controller 52. A control unit that supplies a discharge control signal (discharge data) to the head driver 66. The droplet ejection control unit 62 performs necessary signal processing, and controls the ejection amount and ejection timing of the liquid from the recording head 18 via the head driver 66 based on the droplet ejection data.

  The droplet ejection control unit 62 includes a buffer memory 64, and droplet ejection data, parameters, and other data are temporarily stored in the buffer memory 64 when droplet ejection data is processed in the droplet ejection control unit 62. Note that the buffer memory 64 can also be used as the memory 56. In addition, an aspect in which the droplet ejection control unit 62 and the system controller 52 are integrated and configured with one processor is also possible. The combination of the system controller 52 and the droplet ejection control unit 62 in this example corresponds to a “control unit”.

  The head driver 66 drives the piezoelectric element 44 (see FIG. 3) of the recording head 18 based on the ejection data given from the droplet ejection control unit 62. The head driver 66 may include a feedback control system for keeping the driving conditions of the head constant.

  Although not shown, the line drawing apparatus 10 includes a supply system for supplying a liquid to the recording head 18 and a maintenance unit that performs maintenance (nozzle suction, nozzle surface wiping, etc.) of the recording head 18. Yes.

[Droplet discharge conditions]
FIG. 5 is a diagram schematically showing a procedure for drawing a linear pattern L on the substrate 12 by scanning the recording head 18 in the x direction. Here, for convenience of explanation, the recording head 18 will be described as having only one nozzle.

  As shown in FIG. 5, while the recording head 18 is scanned in the x direction, UV ink is sequentially ejected from the nozzles 32, and the landing droplets 80 are united on the substrate 12 to form a straight line on the substrate 12. The pattern L is drawn. Hereinafter, conditions for preventing the occurrence of jaggies and bulges in such line drawing will be examined.

[Liquid ejection condition 1 (dot pitch p)]
FIG. 6 is a diagram (cross-sectional view and plan view) schematically showing the change with time of the droplets deposited on the surface of the substrate 12. As shown in FIG. _6A , the droplets D1 _eqm ejected from the recording head 18 and landed on the surface of the substrate 12 are each substantially circular at the beginning of landing and are in contact with adjacent droplets. Then, as shown in FIG. 6B, each droplet D spreads out and a pattern L is formed.

  When the liquid droplets are united to form a final linear pattern L, the outline of the pattern L is ideally a smooth straight line, and the combined shape is generally roughly It becomes a semi-cylindrical shape (a partial cylindrical shape obtained by cutting a circular cylinder by a plane parallel to the axis). For this reason, when attention is paid to the portions of the individual landing droplets in the line segment except for both ends of the line segment of the pattern L, the semi-spherical shape immediately after the landing (FIG. 6 (a)) shows that after the wetting and spreading, It can be considered that the shape has changed to a cylindrical shape (FIG. 6B).

  Here, it is assumed that the substrate 12 is a medium in which the droplet D does not permeate (does not penetrate), and the volume of the droplet is preserved before and after landing on the substrate 12 (assuming 1). Further, it is assumed that the contact angle θ [rad] of the droplet D with respect to the substrate 12 is constant (assuming 2).

At this time, the ratio (spreading rate) β _eqm of the diameter d _eqm [μm] of the droplet D1 _eqm when landed on the substrate 12 and the diameter d [μm] of the droplet D before landing is expressed by the following equation (1). It is represented by Here, the diameter d is a diameter when the droplet D before landing is converted into a true sphere.

When the width of the pattern L is w [μm], the cross-sectional area S1 [μm ² ] when the liquid D2 _eqm in FIG. 6B is cut by a plane passing through the center of the liquid D2 _eqm and parallel to the zy plane is as follows: (2)

Therefore, when the distance (nozzle pitch) between the centers of adjacent droplets on the substrate 12 is p [μm], the volume Va [μm ³ ] of the liquid D2 _eqm is expressed by the following equation (3).

On the other hand, since the diameter of the droplet before landing is d, the volume Vb [μm ³ ] of the droplet D before landing is expressed by the following equation (4).

  According to assumption 1, the volume of the droplet D is unchanged before and after landing. When Va = Vb is solved for the line width w, the following equation (5) is obtained.

Here, in order to prevent jaggies from occurring, w ≧ d _eqm = β _eqmd from the viewpoint that the line width w needs to be wider than the landing diameter d, and therefore the equation ( When 5) is solved, the conditional expression (6) of the dot pitch p is obtained.

  By controlling the dot pitch p so as to satisfy the condition of the above expression (6), it is possible to prevent the contour of the pattern L from being jagged (jaggy).

[Liquid ejection condition 2 (time interval of droplet ejection)]
Next, the time interval of droplet ejection will be described. FIG. 7 shows that the contact angle θ = 30 [°], the landing diameter d _eqm = 55 [μm], and the dot pitch 20 [μm] under the conditions satisfying the above formula (6), the droplet D per second. This shows the stability of the line width w when a line is drawn by changing the number of times the ink is ejected (printing frequency). 7A shows a drawing result when the printing frequency is 10 Hz, FIG. 7B shows a drawing result when 1 kHz, and FIG. 7C shows a case when 10 kHz.

  From this result, it is possible to suppress the occurrence of bulges by performing high-frequency printing with a printing frequency of 1 kHz or more at a contact angle of about 30 °.

  A similar experiment was conducted with the contact angle condition changed further. Under the condition where the contact angle was small, the occurrence of bulges was suppressed even under a lower printing frequency. On the contrary, when the contact angle is large, the occurrence of bulges was suppressed by setting the printing frequency to a higher condition. From this finding, it is considered that the occurrence of bulge has an effect on the time taken for wetting and spreading determined by the contact angle.

  FIG. 8 is a graph comparing the behavior of droplet wetting and spreading due to the difference in contact angle. The time to reach equilibrium due to wetting and spreading was examined for each of the contact angle 30 ° and the contact angle 75 °. The horizontal axis in FIG. 8 is time (however, the scale is logarithmic), and the vertical axis is the ratio between the impact diameter immediately after impact and the final impact diameter (“landing diameter / final impact diameter”). That is, the vertical axis is obtained by normalizing the landing diameter with the final landing diameter.

  Under the condition of a contact angle of 75 °, the time until it almost expands to the vicinity of the final landing diameter is t1 (about 0.2 [ms]), whereas under the condition of a contact angle of 30 °, it reaches to the vicinity of the final landing diameter. The time until it is almost fully spread is t2 (about 2 [ms]). That is, the time until the contact angle of 30 ° reaches equilibrium is about 10 times longer than the contact angle of 75 °.

  As described above, the time required for the liquid droplet to completely spread out due to the difference in the contact angle (the time required to reach the equilibrium state) varies greatly. Based on empirical knowledge based on experiments, it is considered that the time required to completely spread the wetting is inversely proportional to the third power of the contact angle. Therefore, from the viewpoint of suppressing the bulge, it is desirable that adjacent droplets are landed one after another until the landed droplet group is completely wetted (within the time until equilibrium is reached). For this reason, it is desirable to increase the printing frequency (shorten the droplet ejection time interval) as the contact angle is larger.

  According to experiments, when the contact angle is 30 °, the landing time difference (droplet ejection time interval) is preferably within 1 μs. Therefore, when the contact angle is generalized as a parameter, the following [Equation 12] is satisfied.

  That is, by performing high-frequency printing (droplet ejection) that realizes landing time intervals that satisfy the condition of [Equation 12] according to the contact angle, an equilibrium state is created in a state where the landing droplet groups are gathered on the substrate. As a result, it is possible to suppress the occurrence of periodic small bulges and jaggies in which landing droplet groups are generated as small aggregates on the substrate during low-frequency printing.

[Time interval until the curing process is performed after droplet ejection]
FIG. 9A shows lines obtained when a curing process is performed by irradiating UV light from the UV light irradiation device 20 approximately two minutes after drawing a linear pattern on the substrate 12 by the recording head 18. It is an example of a shape pattern. FIG. 9B shows a line obtained when a curing process is performed by irradiating UV light from the UV light irradiation device 20 about 1 second after drawing a linear pattern on the substrate 12 by the recording head 18. It is an example of a shape pattern.

  In any case, the droplet ejection condition satisfies the condition of the above-described formula (6). Here, the contact angle is 30 °, the dot pitch is 5 μm, and the printing frequency is 4 kHz. FIGS. 9A and 9B are diagrams in which a linear pattern in which a line segment having a length of about 1 cm is drawn is divided into four.

  As is clear from comparison between FIGS. 9A and 9B, when a curing process is performed about 2 minutes after printing, a large liquid pool (bulge 84) grows in the line segment. On the other hand (FIG. 9A), no bulge is generated when the curing process is performed about 1 second after printing. Thus, the occurrence of bulge can be suppressed by performing the curing process immediately after droplet ejection and losing the fluidity of the liquid on the substrate 12.

  FIG. 10 is a graph in which the relationship between the passage of time after printing and the bulge width is examined. Note that the “bulge width” here refers to the width in the thickness direction of the line of the linear pattern L, as indicated by wb in FIG.

  In FIG. 10, the horizontal axis represents the elapsed time (unit [second]) after printing, and the vertical axis represents the bulge part width (unit [μm]). Note that FIG. 10 shows droplets deposited under the same conditions as FIG. As shown in FIG. 10, it can be seen that the bulge begins to grow 1.5 seconds after printing and gradually expands with time.

  Since the bulge grows because the ink after droplet ejection has fluidity on the substrate 12, it is preferable to cure the ink by irradiating UV light within 1 second.

  From the above knowledge, there are restrictions on the distance between the droplet ejection position of the recording head 18 and the UV irradiation position of the UV light irradiation apparatus 20 in the line drawing apparatus 10 according to this embodiment, and the transport speed of the substrate 12. It is done.

That is, as shown in FIG. 11, the movable range of the recording head 18 in the y-axis direction is the position where the recording head 18 is farthest from the UV light irradiation device 20 in the substrate transport direction (the position of the broken line indicated by reference numeral 86 ) the distance _d H [m] to UV light irradiation apparatus 20 from and to within distance of the conveying speed v of the substrate 12 [m / s] × 1 sec ([s]).

[Equation 13]
d _H [m] <1 [s] × v [m / s]
In order to satisfy these conditions, the movable range of the recording head 18 is restricted (restricted), and the installation position of the UV light irradiation device 20 and the conveyance speed of the substrate 12 (linear velocity of the belt 14) are controlled.

  When a line perpendicular to the substrate transport speed direction (a line parallel to the x direction in FIG. 11) is drawn on the substrate 12 transported at a constant speed v [m / s] by the belt 14, the recording head is used. 18 is also moved at the same speed as the substrate transport speed (the relative speed in the y direction is set to 0).

  When a line parallel to the substrate conveyance speed direction is drawn, the moving speed of the recording head 18 is determined from the conditions of the printing frequency and the dot pitch. When drawing an oblique line that obliquely intersects the substrate conveyance speed direction, the speed of the recording head 18 is determined so that the recording head 18 moves relative to the substrate 12 in the direction of the oblique line.

Regardless of whether a line perpendicular to the substrate conveyance speed direction, a parallel line, or an oblique line that intersects diagonally is drawn, the maximum separation distance d _H [m] and the substrate conveyance speed as shown in FIG. By satisfying the condition of [Equation 13] for v [m / s], it can be cured before bulge generation.

  Also, according to experiments, the time when a part of the line shape starts to swell after drawing is inversely proportional to the third power of the contact angle. Therefore, when the time until curing is defined using the contact angle as a parameter, the time at which part of the linear shape starts to swell after drawing is inversely proportional to the cube of the contact angle. The condition of [Expression 14] is satisfied.

  Then, when generalizing the same viewpoint as [Equation 13] by applying the condition [Equation 14], the following [Equation 15] is obtained.

  That is, the occurrence and growth of bulges can be suppressed by performing immediate curing after printing that satisfies the condition of [Equation 15] according to the contact angle.

<Mode using multi-nozzle head>
In FIG. 5, the case where line drawing is performed with one nozzle has been described as an example. However, the recording head 18 may have a plurality of nozzles as a configuration. For example, as shown in FIG. 12, a recording head 18 ′ (line head) in which a plurality of nozzles 32 are arranged in a line at a constant nozzle interval Np can be used.

  FIG. 12 is a diagram schematically showing a scanning control procedure when the pattern L is drawn by relatively scanning the recording head 18 ′ and the substrate 12 in the y direction. In FIG. 12, the conveyance direction of the substrate 12 is the y direction (sub-scanning direction), and the direction parallel to the surface of the substrate 12 and perpendicular to the y direction (main scanning direction) is the x direction. Also, the direction perpendicular to the xy plane is the z direction, the direction in which the linear pattern L is formed (pattern formation direction, printing direction) is the U direction, the direction parallel to the substrate 12 and perpendicular to the U direction is the V direction. To do.

  As shown in FIG. 12, at least two or more nozzles 32 are used when one linear pattern L is formed. The recording head 18 ′ has an angle formed by a straight line (nozzle line NL) connecting the centers of the nozzles 32 with respect to the printing direction (U direction) by a rotation mechanism that rotates in the xy plane, φ [°] (0 ° <φ <90 °). The recording head 18 and the substrate 12 are relatively scanned in the sub-scanning direction (y direction) while the angle between the nozzle line NL and the U axis is maintained at φ [°], and droplets are sequentially ejected from each nozzle 32. As a result, a linear (for example, straight) pattern L extending in the U direction is drawn. Note that a mode is also possible in which the nozzle line NL of the recording head 18 ′ is installed in parallel with the x direction, and the substrate 12 side is rotated in the xy plane so as to be inclined by an angle φ with respect to the x direction.

  In the case of the form of FIG. 12, the droplet ejection is controlled so as to satisfy the condition of [Equation 12] for the landing time difference of the landing droplets 80 arranged in the U direction on the substrate 12. According to the form of FIG. 12, the landing time interval (printing frequency on the substrate 12) can be controlled by the combination of the ejection frequency of the recording head 18 'and the conveyance speed of the substrate 12.

Second Embodiment
FIG. 13 is a side view showing the configuration of the line drawing apparatus 110 according to the second embodiment of the present invention, and FIG. 14 is a plan view thereof. In these drawings, elements that are the same as or similar to those described in FIGS. 1 and 2 are given the same reference numerals, and descriptions thereof are omitted.

  In the line drawing apparatus 110 according to the second embodiment shown in FIGS. 13 and 14, a support plate 114 is used as a transport unit for the substrate 12. The support plate 114 can be moved in the x direction and the y direction perpendicular thereto by a moving mechanism (for example, an xy table) (not shown). The support plate 114 may be provided with a mechanism for rotating in the xy plane.

  A UV laser irradiation device 120 is attached to the recording head 18. The recording head 18 and the UV laser irradiation device 120 can be moved integrally, and can be moved in the x and y directions by a head moving mechanism (not shown). A mechanism for rotating the recording head 18 and the UV laser irradiation device 120 in the xy plane may be provided.

  As the UV light irradiation means installed in the vicinity of the recording head 18, a laser having a small beam divergence angle is suitable.

  As shown in FIG. 14, the UV laser irradiation device 120 includes a first UV laser irradiation device 120A disposed in the x direction when viewed from the recording head 18 and a second UV laser irradiation device 120A disposed in the y direction when viewed from the recording head 18. It is comprised as a unit which combined with the UV laser irradiation apparatus 120B.

  In FIG. 14, it is possible to attach the UV laser irradiation device so as to surround all four surfaces around the recording head 18, but it is not always necessary to attach the UV laser irradiation device to the entire circumference of the four surfaces. What is necessary is just to install a UV laser irradiation apparatus in one direction.

  In FIG. 14, one UV laser irradiation device (120A, 120) is provided in each of the x direction and the y direction, and UV laser irradiation is performed on the opposite side of the first UV laser irradiation device 120A across the recording head 18. No apparatus is attached, and no UV laser irradiation apparatus is attached to the opposite side of the second UV laser irradiation apparatus 120B across the recording head 18.

  Due to the positional relationship between the recording head 18 and the UV laser irradiation devices (120A, 120B), the recording head 18 moves relative to the substrate 12 in the directions of the white arrows 123 and 124 in the drawing. At this time, printing (droplet ejection) is performed. Alternatively, droplets are ejected from the recording head 18 when the substrate 12 moves relative to the recording head 18 in the directions of the white arrows 133 and 134 in the drawing.

  FIG. 15 is a schematic diagram showing the positional relationship between the recording head 18 and the UV laser irradiation devices (120A, 120B) and the moving direction of the recording head 18 during droplet ejection. As shown in the drawing, droplet ejection is performed when the recording head 18 is moved in the direction of the arrow 123 or 124. Thereby, it is possible to cure the droplets on the substrate 12 by irradiating the first UV laser irradiation device 120A or the second UV laser irradiation device 120B immediately after the recording head 18 ejects droplets.

  FIG. 16 shows a case where only one UV laser irradiation apparatus is attached. Also in this case, as in FIG. 15, in the arrangement relationship between the recording head 18 and the UV laser irradiation device 120A (or 120B), the recording head 18 is on the leading side in the moving direction, and the UV laser irradiation device 120A (or 120B) is It is assumed that printing (droplet ejection) is performed only when the unit moves in the moving direction (outlined arrows 123 and 124) on the rear side in the moving direction.

  In conjunction with droplet ejection control by the recording head 18, the laser irradiation timing, irradiation time, etc. of the UV laser irradiation devices (120A, 120B) are controlled. In this case, the irradiation duration time is determined from the viewpoint of irradiating the UV ink landed on the substrate 12 with an ultraviolet ray having an energy amount necessary for polymerization (curing). For example, it is preferable that the UV laser is irradiated for at least 3 seconds after the discharge signal enters one of the discharge nozzles with the recording head 18.

<Examples of UV ink>
As a functional liquid used for wiring drawing, a dispersion liquid in which conductive fine particles are dispersed in a dispersion medium can be used. As the conductive fine particles, for example, silver nanoparticles are used, and as the dispersion medium, for example, water or tetradecane is used. The conductive fine particles are not limited to silver but may be gold, copper, palladium, nickel, or the like.

  Further, the UV curable monomer in the liquid can be cured and polymerized by containing the UV curable monomer in the liquid and irradiating the landing liquid with ultraviolet rays.

  The UV curable monomer has a function of causing polymerization or a crosslinking reaction by an initiating species such as a radical generated from a polymerization initiator or the like, and curing a composition containing these.

  As the UV curable monomer, a polymerizable or crosslinkable material that causes a known polymerization or crosslinking reaction such as a radical polymerization reaction or a dimerization reaction can be applied. For example, an addition polymerizable compound having at least one ethylenically unsaturated double bond, a polymer compound having a maleimide group in the side chain, a cinnamyl group having a photodimerizable unsaturated double bond adjacent to the aromatic nucleus, Examples thereof include a polymer compound having a cinnamylidene group or a chalcone group in the side chain. Among these, an addition polymerizable compound having at least one ethylenically unsaturated double bond is more preferable, and from a compound (monofunctional or polyfunctional compound) having at least one terminal ethylenically unsaturated bond, more preferably two or more. It is particularly preferred that it is selected. Specifically, it can be appropriately selected from those widely known in the industrial field according to the present invention. For example, monomers, prepolymers (that is, dimers, trimers, and oligomers) and mixtures thereof, and those Those having a chemical form such as a copolymer of

  A UV curable monomer may be used individually by 1 type, and may be used in combination of 2 or more type.

  As the UV curable monomer that can be used in the practice of the present invention, it is particularly preferable to use various known radical polymerizable monomers that cause a polymerization reaction with an initiation species generated from a radical initiator.

  Examples of the radical polymerizable monomer include (meth) acrylates, (meth) acrylamides, aromatic vinyls, vinyl ethers, and compounds having an internal double bond (such as maleic acid). Here, “(meth) acrylate” refers to both and / or “acrylate” and “methacrylate”, and “(meth) acryl” refers to both and / or “acryl” and “methacryl”.

<Application example of device>
The line drawing apparatus of the embodiment described above is a linear image such as a wiring drawing apparatus for an electronic circuit board, a manufacturing apparatus for various devices, a resist printing apparatus using a resin liquid as a functional liquid for ejection, and a fine structure forming apparatus. The present invention can be applied to various apparatuses that can form a pattern.

  DESCRIPTION OF SYMBOLS 10 ... Line drawing apparatus, 12 ... Board | substrate, 14 ... Belt, 16 ... UV ink, 18 ... Recording head (inkjet head), 20 ... UV light irradiation apparatus, 24 ... Light-shielding plate, 32 ... Nozzle, 52 ... System controller, 62 ... droplet ejection control unit, 72 ... motor, 80 ... landing droplet, 84 ... bulge, 110 ... line drawing device, 120 ... UV laser irradiation device

Claims (10)

An inkjet head that discharges a liquid that contains a functional component and has a function of being cured by irradiation with actinic rays;
A non-penetrable medium for attaching droplets ejected from the ink jet head and a moving means for relatively moving the ink jet head;
Control means for controlling droplet ejection from the inkjet head;
Actinic light irradiation means for irradiating the liquid applied on the medium with the actinic ray to cure the liquid on the medium;
The control means discharges sequentially from the ink jet head toward the medium, so that the droplets having a difference in landing time are united on the medium to form a linear pattern first. Before the liquid droplet group is in an equilibrium state on the medium, the droplet ejection is controlled so as to land the next droplet to be further merged with the aggregate,
When the contact angle of the liquid with respect to the medium is θ [rad], the actinic light irradiation means is a time T [until the linear pattern is cured from the time of landing of the final landing droplet constituting the linear pattern. s] is
A line drawing apparatus characterized by satisfying the above. The line drawing apparatus according to claim 1,
The control means is configured so that the landing time interval t [s] between adjacent droplets on the medium is expressed by the following equation.
A line drawing apparatus which controls droplet ejection so as to satisfy The line drawing apparatus according to claim 1 or 2,
When the diameter when the volume of the droplet before landing on the medium is converted into a true sphere is d [μm], the control means has a dot pitch p of the adjacent droplet on the medium expressed by the following equation:
A line drawing apparatus that controls droplet ejection so as to satisfy the above condition. The line drawing apparatus according to any one of claims 1 to 3,
As the moving means, a medium conveying means for conveying the medium at a constant speed,
The line drawing apparatus, wherein the actinic light irradiation means is disposed downstream of the ink jet head in a medium conveying direction by the medium conveying means. The line drawing apparatus according to claim 4,
As the moving means, a head moving means for moving the inkjet head in a direction parallel to the medium conveying direction,
The head moving means has a distance d _H [between the inkjet head and the actinic light irradiation means in a direction parallel to the medium conveying direction, where v [m / s] is the constant speed by the medium conveying means. m] is the following formula
A line drawing apparatus, wherein a movable range of the inkjet head is limited so as to satisfy The line drawing apparatus according to claim 4 or 5,
A line drawing apparatus, wherein a light shielding member for preventing propagation of actinic rays is provided between the inkjet head and the actinic light irradiation means. The line drawing apparatus according to any one of claims 1 to 3,
The active light irradiation means irradiates a laser beam toward the medium,
The active light irradiation means is attached to the ink jet head, and these are integrally configured to move relative to the medium. The line drawing apparatus according to claim 7,
Relative to the medium from the direction in which the actinic light irradiation means is attached under the relative positional relationship of the actinic light irradiation means with respect to the ink jet head, the ink jet head is directed relative to the medium. A line drawing apparatus for ejecting droplets from the ink jet head only when the ink is moved. The line drawing apparatus according to any one of claims 1 to 8,
The line drawing apparatus, wherein the actinic ray is ultraviolet light A liquid containing a functional component and having a function of being cured by irradiation with actinic rays is sequentially ejected from an ink jet head toward a non-permeable medium, and the ejected liquid droplets are adhered to the medium. A line drawing method for forming a linear pattern by uniting droplets having landing time differences on the medium,
Droplet ejection from the inkjet head so as to land the next droplet that further coalesces with the aggregate before the aggregate of droplets that have landed on the medium reaches an equilibrium state on the medium. Control
When the liquid on the medium is cured by irradiating the liquid attached on the medium with the actinic ray, the linear pattern is formed when a contact angle of the liquid with respect to the medium is θ [rad]. The time T [s] from the time of landing of the final landing droplet to be cured until the linear pattern is cured is
Irradiating with the actinic ray so as to satisfy