JP6835506B2 - Liquid coating unit and liquid coating device - Google Patents

Description

The present invention relates to a liquid coating unit and a liquid coating device, and relates to a liquid coating unit and a liquid coating device for applying a liquid material to an object using a coating needle.

Printed electronics technology for forming minute circuits such as RFID tags by printing (coating) is rapidly developing. In printed electronics technology, the method using a coating needle is also one of the options in that fine coating can be performed using a material having a wide range of viscosities.

As a method of performing fine coating using a coating needle, there is a method of performing fine coating using a coating unit as described in Japanese Patent Application Laid-Open No. 2015-112576 (Patent Document 1). In the coating unit, the liquid material is housed in a liquid material container. The liquid material container is formed with two holes above and below the internal space accommodating the liquid material, which connect the internal space and the outside and allow the coating needle to be inserted.

The coating unit has a first state in which the tip of the coating needle is immersed in the liquid material in the liquid material container, that is, a state in which the coating needle is inserted only in the upper hole, and below the liquid material container. A second state in which the liquid material can be applied to the object by projecting, that is, a state in which the application needle is inserted into both the upper and lower holes is switchable. The coating unit can also coat a high-viscosity liquid material containing metal powder.

JP-A-2015-112576

However, when such a high-viscosity liquid material is continuously applied a plurality of times using a conventional coating unit, that is, when the number of times of switching the above states is continuously repeated, the liquid material container becomes On the outer peripheral surface (lower surface), a pool of liquid material is generated on the annular region located around the lower hole and below the lower hole.

For example, a part of the liquid material attached to the coating needle adheres to the annular region, and the liquid material wets and spreads on the annular region and below the lower hole surrounded by the annular region. Further, a part of the liquid material stored in the liquid material container flows out to the annular region of the liquid material container along the inner peripheral surface of the lower hole, and spreads wet. As a result, a pool of the liquid material is generated.

In the coating unit, such a pool of liquid material can serve as a source of liquid material for the coating needle. The coating needle is immersed in such a pool of liquid material, for example, when switching from the first state to the second state. Therefore, the amount of the liquid material adhering to the coating needle in the second state changes according to the amount of the pool of the liquid material. As a result, there is a problem that the amount of the liquid material to be applied to the object changes according to the number of times of application when it is applied continuously a plurality of times.

The present invention has been made to solve the above problems. A main object of the present invention is a liquid coating unit and a liquid coating apparatus in which a change in the coating amount when a high-viscosity liquid material is continuously applied a plurality of times is suppressed as compared with a conventional liquid coating unit and a liquid coating apparatus. Is to provide.

The liquid coating unit according to the present invention is a liquid coating unit for coating a liquid material on the surface of an object using a coating needle, and is a coating needle, a liquid material container for storing the liquid material, and a liquid material container. On the other hand, a drive unit for raising and lowering the coating needle is provided. The liquid material container is formed with a space for storing the liquid material and first and second holes for inserting the coating needle into the space. The first hole is formed below the space in the direction of gravity. The second hole is formed on the opposite side of the first hole with a space in between. The liquid material container includes a water-repellent layer formed so as to extend from at least the inner peripheral surface of the first hole to a part of the outer peripheral surface of the liquid material container surrounding the first first hole.

According to the present invention, a liquid coating unit and a liquid coating device in which a change in the coating amount when a high-viscosity liquid material is continuously applied a plurality of times is suppressed as compared with a conventional liquid coating unit and a liquid coating device. Can be provided.

It is a side view which shows the liquid coating unit which concerns on embodiment. It is a front view which shows the liquid coating unit which concerns on embodiment. It is a partial sectional view which shows the liquid material container of the liquid coating unit which concerns on embodiment. It is a partially enlarged view of the region IV in FIG. It is a top view when the liquid material container of the liquid coating unit which concerns on this Embodiment is seen from the bottom. It is a partial cross-sectional view which shows the liquid material container of the liquid coating unit which concerns on this embodiment. It is a perspective view which shows the whole structure of the liquid coating apparatus which concerns on this embodiment. It is a partial cross-sectional view which shows the modification of the liquid material container of the liquid coating unit which concerns on this embodiment. It is a partial cross-sectional view which shows the other modification of the liquid material container of the liquid coating unit which concerns on this embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings below, the same or corresponding parts are given the same reference number, and the explanation is not repeated.
[Construction of liquid coating unit]
With reference to FIGS. 1 to 6, the liquid coating unit 100 according to the present embodiment is for applying a liquid material to the surface of the substrate 140 (see FIG. 3) as an object by using the coating needle 1. Is. The liquid coating unit 100 mainly includes a coating needle 1, a servomotor 2, a base portion 3, a liquid material container 5, and a container holding portion 4.

The coating needle 1 has one end and the other end (needle tip 1E shown in FIGS. 3 and 6). The needle tip 1E of the coating needle 1 may have an arbitrary shape, but has, for example, a conical shape. The outer diameter of the portion having one end of the coating needle 1 (part 1B shown in FIGS. 3 and 6) is larger than the outer diameter of the portion having the other end of the coating needle 1 (part 1A shown in FIGS. 3 and 6). Is also big. One end of the coating needle 1 is connected to a driven member 7 (coating needle holder 11, coating needle holder accommodating portion 12, coating needle holder fixing portion 13, cam connecting portion 15, and bearing 16) described later.

The coating needle 1 is provided by the servomotor 2 so as to be movable along the gravity direction together with the driven member 7. In the liquid coating unit 100, the needle tip 1E of the coating needle 1 is housed in the liquid material container 5, which will be described later, by driving the servomotor 2, and the needle tip 1E of the coating needle 1 is a substrate. It is possible to change the second state in which the surface of 140 can be contacted. The direction of gravity is, for example, a direction along the axial direction of the coating needle 1, for example, the direction of gravity (Z-axis direction in FIG. 1). 1 and 2 show the liquid coating unit 100 in the first state.

Specifically, the liquid coating unit 100 is provided by the cam member 6 and the driven member 7 so that the rotational motion of the servomotor 2 can be converted into the motion (vertical motion) of the coating needle 1 in the direction of gravity. The servomotor 2 has a rotating portion 21 that is rotatably provided about an axis extending in the direction of gravity. A cam member 6 is connected to the rotating portion 21. The cam member 6 is rotatable about the rotation axis of the servomotor 2. The upper surface of the cam member 6 (the surface on the servomotor 2 side) is the cam surface 6A. The cam surface 6A is in contact with the outer peripheral surface of the outer ring of the bearing 16 of the driven member 7.

The base portion 3 holds the coating needle 1, the driven member 7, the servomotor 2, and the container holding portion 4. The base portion 3 includes a guide portion 33 that guides the movement of the driven member in the direction of gravity and restricts the movement in a direction other than the direction of gravity. The container holding portion 4 is connected to the lowermost portion of the base portion 3.

The container holding unit 4 holds the liquid material container 5. The container holding portion 4 includes, for example, a magnet, and holds the liquid material container 5 by the magnetic force generated by the magnet.

A space 50 for storing the liquid material L (see FIG. 3) is formed inside the liquid material container 5. As shown in FIGS. 3 and 6, a first hole 51 connecting the lower end of the space 50 and the outside is formed at the bottom of the liquid material container 5. A second hole 52 connecting the upper end of the space 50 and the outside is formed in the upper part of the liquid material container 5. The shape of the first hole 51 and the second hole 52 may be any shape, but is, for example, a circular shape. The first hole 51 and the second hole 52 are provided so as to overlap each other in the direction of gravity. The hole shaft of the first hole 51 and the hole shaft of the second hole 52 are provided so as to overlap each other in the direction of gravity, for example. The inner peripheral surface of the first hole 51 is formed so as to extend along the direction of gravity, for example. The space 50 is formed inside, for example, a third hole 53 connected to the first hole 51 and the second hole 52. FIG. 3 shows the coating needle 1 and the liquid material container 5 of the liquid coating unit 100 in the first state. FIG. 6 shows the coating needle 1 and the liquid material container 5 of the liquid coating unit 100 in the second state.

As shown in FIGS. 3 and 4, the liquid material container 5 has a wall portion 54 formed so as to surround the circumference of the first hole 51 on the outer peripheral surface thereof, and the liquid material container 5 projects downward from the wall portion 54. Includes the convex portion 55 and the like. When the liquid material container 5 is viewed in a plan view from below in the direction of gravity, each of the wall portion 54 and the convex portion 55 is provided in an annular shape around the hole axis of the first hole 51, for example. In FIG. 4, the liquid material L is not shown.

As shown in FIGS. 3 and 4, the inner peripheral end portion of the wall portion 54 in the plan view is connected to the lower end portion of the first hole 51. The outer peripheral end of the wall portion 54 in the above plan view is connected to the upper end (root portion) of the convex portion 55. The wall portion 54 has a first surface 54A and a second surface 54B as lower surfaces facing the surface of the substrate 140 as an object. The first surface 54A is formed so as to extend in a direction intersecting the gravity direction and the horizontal direction, for example. The second surface 54B is formed so as to extend along the horizontal direction, for example. The inner peripheral portion of the wall portion 54 connected to the lower end of the first hole 51 has, for example, a first surface 54A. The outer peripheral portion of the wall portion 54 connected to the convex portion 55 has, for example, a second surface 54B. The smaller angle of the angle formed by the first surface 54A of the wall portion 54 with respect to the hole axis of the first hole 51 is, for example, more than 0 degrees and less than 90 degrees, for example, 30 degrees or more and 60 degrees or less. The width of the first surface 54A in the radial direction about the hole axis of the first hole 51 is, for example, 0.05 mm or more and 1 mm or less, for example, about 0.2 mm. The width of the second surface 54B in the radial direction is, for example, 0.05 mm or more and 1 mm or less, for example, about 0.2 mm.

As shown in FIGS. 3 and 4, the inner peripheral end portion of the convex portion 55 in the plan view is connected to the outer peripheral end portion of the wall portion 54. The convex portion 55 is formed so as to surround the periphery of the wall portion 54. The convex portion 55 has, for example, a top surface 55T extending in the horizontal direction and a side surface 55S extending in the direction of gravity. The inner peripheral end of the top surface 55T is connected to the lower end of the side surface 55S. The top surface 55T is, for example, the lowermost surface on the outer peripheral surface of the liquid material container 5. The side surface 55S is closer to the hole axis of the first hole 51 than, for example, another side surface connected to the top surface 55T. The upper end of the side surface 55S is connected to the outer peripheral end of the second surface of the wall portion 54. That is, the first surface 54A, the second surface 54B, the side surface 55S and the top surface 55T of the convex portion 55 of the wall portion 54 are sequentially connected in the radial direction with the hole axis of the first hole 51 as the central axis. Each of the first surface 54A, the second surface 54B, the side surface 55S and the top surface 55T of the convex portion 55 of the wall portion 54 may be a curved surface, but is, for example, a flat surface. The height of the convex portion 55 with respect to the second surface 54B of the wall portion 54 is, for example, 0.05 mm or more and 1 mm or less, for example, about 0.1 mm. The width of the convex portion 55 in the radial direction about the hole axis of the first hole 51 is, for example, 0.05 mm or more and 1 mm or less, for example, about 0.1 mm.

The liquid material container 5 includes a water-repellent layer 9 formed so as to extend from the inner peripheral surface of the first hole 51 to a part of the outer peripheral surface of the liquid material container 5 surrounding the first hole 51. .. The partial region includes the first surface 54A and the second surface 54B of the wall portion 54, and the side surface 55S and the top surface 55T of the convex portion 55. That is, the water-repellent layer 9 is formed so as to cover the inner peripheral surface of the first hole 51, the first surface 54A and the second surface 54B of the wall portion 54, the side surface 55S of the convex portion 55, and the top surface 55T. There is. The water-repellent layer 9 has higher water repellency than the liquid material container 5. The material constituting the water-repellent layer 9 may be any material having more water repellency than the material constituting the liquid material container 5, and is, for example, a fluororesin. The water-repellent layer 9 has a contact angle with water larger than 0 °. Preferably, the water repellent layer 9 has a contact angle with water of 45 ° or more.

The water-repellent layer 9 can be formed by any method, but is formed, for example, by partially forming a fluororesin coating material on the outer peripheral surface and the inner peripheral surface of the liquid material container 5. .. For example, first, on the outer peripheral surface and the inner peripheral surface of the liquid material container 5, only the region where the water-repellent layer 9 should be formed is opened, and a mask film covering the other regions is formed. Next, a fluorine-based resin coating material is formed on the entire outer peripheral surface and inner peripheral surface of the liquid material container 5. Next, the mask film is peeled off and removed from the outer peripheral surface and the inner peripheral surface of the liquid material container 5, so that the coating film formed on the mask film is removed. In this way, the water repellent layer 9 is formed. The water-repellent layer 9 may be formed by, for example, a plasma treatment method. In this case, for example, a fluorine-based gas is used as the process gas.

In the liquid material container 5, for example, when the liquid coating unit 100 is in the first state, the lower surface of the liquid material L stored in the liquid material container 5 is formed on the first surface 54A of the wall portion 54. It is provided so as to be in contact with the water layer 9.

The hole diameter of the first hole 51 is equal to or larger than the outer diameter of the portion 1A of the coating needle 1 and less than the outer diameter of the portion 1B. The hole diameter of the second hole 52 exceeds, for example, the outer diameter of the portion 1B of the coating needle 1. As a result, the portion 1A of the coating needle 1 can be inserted into the first hole 51. The portion 1B of the coating needle 1 can be inserted through the second hole 52, but cannot be inserted through the first hole 51.

The driven member 7 includes a coating needle holder 11, a coating needle holder accommodating portion 12, a coating needle holder fixing portion 13, a cam connecting portion 15, and a bearing 16. The guide unit 33 restricts the driven member 7 from moving in a direction other than the direction of gravity, for example, moving in the intersecting direction. The driven member is restricted from moving in a direction other than the gravity direction, for example, moving in the intersecting direction by the guide portion 33 above the container holding portion 4 described later in the gravity direction.

The coating needle holder 11 holds the coating needle 1 as described above. The coating needle holder 11 is detachably housed in the coating needle holder accommodating portion 12. The coating needle holder accommodating portion 12 is fixed to the coating needle holder fixing portion 13. The cam connecting portion 15 is fixed to the coating needle holder fixing portion 13 and the inner ring (not shown) of the bearing 16. The inner ring of the bearing 16 is fixed to, for example, a portion of the cam connecting portion 15 located above the portion connected to the coating needle holder fixing portion 13 in the direction of gravity. The outer ring of the bearing 16 is slidably connected to the cam member 6 (details will be described later). The outer peripheral surface of the outer ring of the bearing 16 is a sliding surface that can slide in contact with the cam surface 6A.

The cam surface 6A is formed in an annular shape along the outer circumference of the central portion, and is formed in a slope shape so that the distance from the lower surface (the surface on the coating needle 1 side) of the cam member 6 varies. .. For example, the cam surface 6A is arranged at a distance from the upper end flat region where the distance from the lower surface of the cam member 6 is the largest and the upper end flat region, and the distance from the lower surface of the cam member 6 is the largest. Includes a small lower end flat area and a slope connecting the upper end flat area and the lower end flat area. The upper end flat region is a region in FIG. 1 and FIG. 2 that is in contact with the outer peripheral surface of the bearing 16.

The tension applying portion 8 includes a first portion 81, a second portion 82, and an elastic portion 83. The elastic portion 83 has one end and the other end. One end of the elastic portion 83 is fixed to the first portion 81, and the other end of the elastic portion 83 is fixed to the second portion 82. The first part 81 is fixed to the base part 3. The second part 82 is fixed to the coating needle holder fixing part 13 above the first part 81.

The elastic portion 83 is provided so as to be elastically deformable between one end and the other end. The elastic portion 83 is, for example, a spring member. The elastic portion 83 is provided so as to be able to apply a downward force in the direction of gravity to the driven member when it is in the first state and the second state. The force generated by the elastic portion 83 acts on the bearing 16 via the second portion 82, the coating needle holder fixing portion 13, and the cam connecting portion 15. The tension applying portion 8 is provided so as to be able to maintain a state in which the bearing 16 is pressed against the cam surface 6A of the cam member 6 in both the first state and the second state. The distance between the first part 81 and the second part 82 in the direction of gravity is mutably provided by the adjusting part 84. The adjusting portion 84 is provided so that the magnitude of the force applied to the bearing 16 by the elastic portion 83 can be changed.

[Configuration of liquid coating device]
The liquid coating device 200 according to the present embodiment includes the liquid coating unit 100 described above. The liquid coating device 200 includes a liquid coating unit 100, an observation optical system 110, a CCD camera 111 connected to the observation optical system 110, a Z-axis table 120, an X-axis table 121, and a Y-axis table 122. The table 123 and the control unit 130 are included.

The observation optical system 110 is provided for observing the coating position of the substrate 140 to be coated. The CCD camera 111 of the observation optical system 110 converts the observed image into an electric signal. The liquid coating unit 100 and the observation optical system 110 are mounted on a moving body of the Z-axis table 120. As a result, the liquid coating unit 100 and the observation optical system 110 are movably supported by the Z-axis table 120 in the Z-axis direction in FIG. The Z-axis table 120 is mounted on the moving body of the X-axis table 121. As a result, the Z-axis table 120 is movably supported by the X-axis table 121 in the X-axis direction in FIG. The substrate 140 to be coated is placed on the moving body of the Y-axis table 122. As a result, the substrate 140 to be coated is supported by the Y-axis table 122 so as to be movable in the Y-axis direction in FIG. The Y-axis table 122 is installed on the upper surface of the base 123. The Y-axis table 122 is provided so that the substrate 140 as an object can be mounted. The Y-axis table 122 is provided so as to be movable in the Y-axis direction. The Z-axis direction in FIG. 7 is a direction along the direction of gravity.

The control unit 130 includes an operation panel 131, a monitor 132, and a control computer 133. The control unit 130 controls the liquid coating unit 100, the observation optical system 110, the Z-axis table 120, the X-axis table 121, and the Y-axis table 122. The operation panel 131 is used to input a command to the control computer 133. The monitor 132 displays the image data converted by the CCD camera 111 of the observation optical system 110 and the output data from the control computer 133.

[Liquid application method]
Next, a liquid coating method using the liquid coating device 200 will be described. In the liquid coating method, the X-axis table 121, the Y-axis table 122, and the Z-axis table 120 are arranged so that the first coating position of the coating positions of the substrate 140, which is the object to be coated, is located directly below the observation optical system 110. Is moved. The coating position of the substrate 140 is observed and determined by the observation optical system 110. The substrate 140 is moved by the X-axis table 121, the Y-axis table 122, and the Z-axis table 120 so that the coating position determined in this way is directly below the liquid coating unit 100. The liquid coating unit 100 at this time is in the first state. Then, when the liquid coating unit 100 is placed in the second state at the determined coating position, the liquid material is coated on the coating position of the substrate 140. After that, the liquid coating unit 100 is put into the first state again. Further, the substrate 140 is moved by the X-axis table 121, the Y-axis table 122, and the Z-axis table 120 so that the next coating position is directly below the liquid coating unit 100. After the movement is completed, the liquid coating unit 100 is brought into the second state, so that the liquid material is coated on the coating position of the substrate 140. Each of these steps can be performed continuously and repeatedly. As a result, a predetermined circuit pattern can be formed on the upper surface of the substrate 140 in a short time by the liquid coating method according to the present embodiment.

[Action effect]
The liquid coating unit 100 according to the present embodiment is a liquid coating unit for coating a liquid material on the surface of an object by using the coating needle 1. The liquid coating unit 100 includes a coating needle 1, a liquid material container 5 for storing the liquid material L, and a driving unit 2 for raising and lowering the coating needle 1 with respect to the liquid material container 5. The liquid material container 5 is formed with a space 50 for storing the liquid material L, and a first hole 51 and a second hole 52 for inserting the coating needle 1 into the space 50. The first hole 51 is formed below the space 50 in the direction of gravity. The second hole 52 is formed on the side opposite to the first hole 51 with the space 50 interposed therebetween. The liquid material container 5 includes a water-repellent layer 9 formed so as to extend from the inner peripheral surface of the first hole 51 to a part of the outer peripheral surface of the liquid material container 5 surrounding the first hole 51. ..

A flow path when the liquid material L wets and spreads from the space 50 of the liquid material container 5 onto the outer peripheral surface of the liquid material container 5, and a flow path when the liquid material L wets and spreads on the outer peripheral surface of the liquid material container 5 via the coating needle 1. Is formed from the inner peripheral surface of the first hole 51 to a part of the outer peripheral surface of the liquid material container 5 surrounding the first hole 51. In the liquid coating unit 100, the water-repellent layer 9 is formed so as to extend from the inner peripheral surface of the first hole 51 to a part of the outer peripheral surface of the liquid material container 5 surrounding the first hole 51. Therefore, as compared with the conventional liquid coating unit, the liquid material L is less likely to get wet and spread on the outer peripheral surfaces of the liquid material container 5 (for example, the first surface 54A and the second surface 54B of the wall portion 54). Therefore, in the liquid coating unit 100, a pool of the liquid material L is formed on the second surface 54B even in the first state and the second state after the liquid material L is continuously applied a plurality of times. Instead, a state substantially equivalent to the first state shown in FIG. 3 and the second state shown in FIG. 6 can be maintained. Therefore, in the liquid coating unit 100, as compared with the conventional liquid coating unit, for example, the liquid material L is less likely to accumulate on the second surface 54B of the wall portion 54 adjacent to the first hole 51, and the liquid material L is less likely to accumulate. It is difficult for the pool to grow in size. As a result, in the liquid coating unit 100, the change in the coating amount when the highly viscous liquid material L is continuously coated a plurality of times is suppressed as compared with the conventional liquid coating unit.

In the liquid coating unit 100, the liquid material container 5 is formed so as to surround the periphery of the wall portion 54 and the wall portion 54 formed so as to surround the periphery of the first hole 51 on the outer peripheral surface thereof. It also includes a convex portion 55 that protrudes downward from the wall portion 54. The partial region includes the first surface 54A and the second surface 54B facing the surface of the substrate 140 as an object in the wall portion 54, the top surface 55T of the convex portion 55, the top surface 55T of the convex portion 55, and the wall. It has a side surface 55S of a convex portion 55 connecting the first surface 54A and the second surface 54B of the portion 54. In other words, the water-repellent layer 9 extends from the inner peripheral surface of the first hole 51 to the first surface 54A and the second surface 54B of the wall portion 54, the side surface 55S of the convex portion 55, and the top surface 55T of the convex portion 55. , Is formed to extend.

In this way, even if the liquid material L wets and spreads on the second surface 54B of the wall portion 54 of the liquid material container 5, the liquid material L gets wet with the side surface 55S and the top surface 55T of the convex portion 55. Hard to spread. Therefore, in the liquid coating unit 100, the accumulation of the liquid material L is less likely to occur on the second surface 54B as compared with the conventional liquid coating unit, and the accumulation of the liquid material L is less likely to occur on the first surface 54A, the second surface 54B, and the side surface. It is difficult to form so as to be continuous on 55S and the top surface 55T. As a result, in the liquid coating unit 100, the change in the coating amount when the highly viscous liquid material L is continuously coated a plurality of times is suppressed as compared with the conventional liquid coating unit.

[Modification example]
The liquid coating unit 100 according to the present embodiment may have the following configuration, for example.

As shown in FIG. 8, the liquid material container 5 does not have to include the convex portion 55. In such a liquid material container 5, as compared with the liquid material container 5 shown in FIGS. 3 to 6, the second surface 54B of the wall portion 54 is in the radial direction with the hole axis of the first hole 51 as the central axis. Widely installed. The width of the second surface 54B of the wall portion 54 in the radial direction about the hole axis of the first hole 51 is, for example, 0.1 mm or more and 2 mm or less, for example, about 0.2 mm.

Even in this way, the water-repellent layer 9 is formed so as to extend from the inner peripheral surface of the first hole 51 to the first surface 54A and the second surface 54B of the wall portion 54. Therefore, even in such a modified example of the liquid coating unit 100, a pool of the liquid material L is generated on the second surface 54B of the wall portion 54 adjacent to the first hole 51 as compared with the conventional liquid coating unit. It is difficult to make the liquid material L pool large. As a result, the modified example shown in FIG. 8 can exert the same effect as the liquid coating unit 100.

As shown in FIG. 9, the water-repellent layer 9 may be formed on the entire surface of the liquid material container 5. The entire surface of the liquid material container 5 includes an outer peripheral surface of the liquid material container 5 and an inner peripheral surface of the liquid material container 5. The inner peripheral surface of the liquid material container 5 has an inner peripheral surface of the first hole 51 and the second hole 52, and a surface facing the space 50. Even in such a modified example of the liquid coating unit 100, since the water-repellent layer 9 is formed on the second surface 54B of the wall portion 54 adjacent to the first hole 51, the liquid is formed on the second surface 54B. Accumulation of material L is unlikely to occur. As a result, the modified example shown in FIG. 9 can exert the same effect as the liquid coating unit 100 described above. Further, the water-repellent layer 9 in the modified example can be formed more easily than the water-repellent layer 9 in the liquid coating unit 100. The water-repellent layer 9 in the modified example can be formed without forming a mask film on the outer peripheral surface and the inner peripheral surface of the liquid material container 5. Therefore, the manufacturing cost of the liquid coating unit according to the modified example is reduced as compared with the liquid coating unit 100.

The water-repellent layer 9 may be formed, for example, by modifying the material constituting the outer peripheral surface or the inner peripheral surface of the liquid material container 5.

Further, in the present embodiment, an example of forming a circuit pattern on the substrate 140 by using the liquid coating apparatus 200 has been shown, but the present invention is not limited to this. That is, the liquid coating unit 100 according to the present invention and the liquid coating device 200 including the liquid coating unit 100 can be used, for example, to coat a conductive material in mounting a crystal oscillator, or to apply a catalyst material to a MEMS (Micro Electro Mechanical Systems) gas sensor. It can be suitably used for applications such as coating and coating of an adhesive to an LED (Light Emitting Diode) in which a small amount of liquid material is stably coated.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The present invention is particularly advantageously applied to a liquid coating unit including a liquid material container in which a highly viscous liquid material is stored, and a liquid material coating apparatus including the liquid coating unit.

1 Coating needle, 1A, 1B part, 1E needle tip, 2 Servo motor (driving part), 3 Base part, 4 Container holding part, 5 Liquid material container, 6 Cam member, 7 Driven member, 8 Tension applying part, 9 Repellent Water layer, 11 coating needle holder, 12 coating needle holder housing section, 13 coating needle holder fixing section, 15 cam connecting section, 16 bearings, 21 rotating section, 33 guide section, 34 adjusting section, 50 space, 51 first hole, 52 2nd hole, 53 3rd hole, 54 wall part, 54A 1st surface, 54B 2nd surface, 55 convex part, 55S side surface, 55T top surface, 81 1st part, 82 2nd part, 83 elastic part, 100 Liquid coating unit, 110 observation optical system, 111 camera, 120 Z-axis table, 121 X-axis table, 122 Y-axis table, 123 base, 130 control unit, 131 operation panel, 132 monitor, 133 control computer, 140 board, 200 Liquid coating device.

Claims (4)

A liquid coating unit for applying a liquid material to the surface of an object using a coating needle.
With the coating needle
A liquid material container for storing the liquid material and
The coating needle is moved up and down with respect to the liquid material container, and the first state in which the needle tip of the coating needle is housed in the liquid material container and the needle tip of the coating needle come into contact with the surface of the object. Equipped with a drive unit that switches between the possible second state
The liquid material container is formed with a space for storing the liquid material and first and second holes for inserting the coating needle into the space.
The first hole is formed below the space in the direction of gravity.
The second hole is formed on the side opposite to the first hole with the space in between.
The liquid material container includes a water-repellent layer formed so as to extend from at least the inner peripheral surface of the first hole to a part of the outer peripheral surface of the liquid material container surrounding the first hole. ,
The liquid material container has a wall portion formed so as to surround the periphery of the first hole on the outer peripheral surface, and a wall portion formed so as to surround the periphery of the wall portion and below the wall portion. Including protruding convex parts
The wall portion is centered on a first surface formed so as to extend in a direction intersecting the gravity direction and the horizontal direction as a lower surface facing the surface of the object, and a hole axis of the first hole. It has a second surface that is arranged outside the first surface in the radial direction as an axis and is formed so as to extend along the horizontal direction.
The partial region connects the first surface and the second surface of the wall portion, the top surface of the convex portion, the top surface of the convex portion, and the second surface of the wall portion. It has the side surface of the convex part and
When the liquid material container is in the first state, the lower surface of the liquid material stored in the liquid material container is in contact with the water-repellent layer formed on the first surface of the wall portion. The lower surface of the liquid material stored in the liquid material container is not formed on the second surface of the wall portion in the first state and the second state. A liquid coating unit provided in. The liquid coating unit according to claim 1, wherein the smaller angle of the angle formed by the first surface of the wall portion with respect to the hole axis of the first hole is 30 degrees or more and 60 degrees or less. The liquid coating unit according to claim 1 or 2, wherein the water-repellent layer is formed on the entire surface of the liquid material container. The liquid coating unit according to any one of claims 1 to 3 and
A liquid coating device including a holding table for holding the object.

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