JP2015199035A - Applicator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a simply-configured applicator capable of blocking a supply of an application material to a nozzle part and preventing the application material from pulling strings at the end of application.SOLUTION: An applicator 10 applies an application material 200 to an application object 300. A nozzle part 20 discharges the application material 200 through a discharge hole 24 to the application object 300, and can be rotated around an axis in a Z direction. An application material supplier 40 supplies the application material 200 through a first supply pipe 42. A controller 50 rotates the nozzle part 20 in response to a supply of the application material 200 in a predetermined volume from the application material supplier 40 to the nozzle part 20, to block communication between an application material supply hole 22 and the first supply pipe 42. In addition, the controller 50 rotates the nozzle part 20 in response to a discharge of the application material 200 in the predetermined volume from the discharge hole 24, to prevent the application material 200 from pulling strings.

Description

  The present invention relates to a coating apparatus that applies a coating material to a coating object.

  As described in Patent Document 1, there is known a coating apparatus that includes a pipe, a nozzle, a pump, and a CPU and applies a viscous material. The CPU provides a control signal for operating the pump. The pump and the nozzle are connected by a pipe, and the pump sends the viscous material to the nozzle through the pipe. The nozzle discharges the viscous material sent out from the pipe.

JP 2005-246270 A

  However, there is a possibility that the viscous material is supplied from the pipe to the nozzle even after the application is completed. When the viscous material is supplied from the pipe to the nozzle after the application is finished, the viscous material may be excessively discharged from the nozzle. On the other hand, the structure which interrupts | blocks supply of the viscous material from piping to a nozzle using an electromagnetic valve can also be considered. However, solenoid valves are expensive. Further, there is a possibility that stringing of the viscous material may occur at the nozzle when the application of the viscous material is completed. According to this, there exists a possibility that a viscous material may adhere to the location which is not intended.

  In view of the above-described problems, the present invention provides a coating apparatus that can cut off the supply of the coating material to the nozzle at the end of coating of the coating material with a simple configuration and suppresses stringing of the coating material. This is the first purpose. A second object is to more effectively suppress stringing of the coating material.

  The invention disclosed herein employs the following technical means to achieve the above object. Note that the reference numerals in the claims and the parentheses described in this section indicate the correspondence with the specific means described in the following embodiment as one aspect, and limit the technical scope of the invention. Not what you want.

  One of the disclosed inventions is that in the coating apparatus (10) for coating the coating material (200) to the coating object (300), the coating material supply hole (22) to which the coating material is fed, and the supplied coating material. A nozzle part (20) that has a discharge hole (24) for discharging the liquid, discharges the coating material from the discharge hole to the application target, and is rotatable about the discharge axis as an axis, and the nozzle part A first supply pipe (42) that can communicate with the coating material supply hole, a coating material supply section (40) that supplies the coating material from the first supply pipe, and a control section (50) that controls the rotation of the nozzle section. ), And the control unit rotates the nozzle unit in response to the supply of a predetermined amount of the coating material from the coating material supply unit to the nozzle unit, so that the coating material supply hole of the nozzle unit and the first supply Blocks communication with the pipe and discharges the desired amount of coating material from the discharge hole. By rotating the nozzle portion in response to the, which comprises suppressing the stringing of the coating material.

  According to this, the control unit rotates the nozzle unit in response to the supply of a predetermined amount of the coating material from the coating material supply unit to the nozzle unit. By this rotation, the communication between the coating material supply hole of the nozzle portion and the first supply pipe is blocked. Therefore, it can suppress supplying an application material to a nozzle part excessively. Moreover, according to the said structure, supply of the coating material to a nozzle part can be interrupted | blocked, without using a solenoid valve.

  Moreover, according to the said structure, a nozzle part can be rotated around an axis | shaft by making discharge direction into an axis | shaft. By rotating the nozzle portion around the axis, a torsional stress can be applied to the discharged coating material. Therefore, according to the above configuration in which the nozzle portion rotates in response to the discharge of the target discharge amount of the coating material from the discharge hole, the coating material discharged from the nozzle portion can be threaded and applied at the end of coating. The stringing of the material can be suppressed. Therefore, the rotation of the nozzle portion can block the supply of the coating material to the nozzle portion and suppress the stringing of the coating material. That is, with a simple configuration, the supply of the coating material to the nozzle portion can be cut off, and stringing of the coating material at the end of coating can be suppressed.

  One of the other inventions disclosed is a coating apparatus that applies a coating material to a coating object, and has a first screw portion and a discharge hole for discharging the coating material, and applies the coating material from the discharge hole. A nozzle portion that discharges onto an object and that can rotate about the discharge axis as an axis, and a second screw portion that can be screw-coupled to the first screw portion, the first screw portion and the second screw portion, And a control unit that controls the rotation of the nozzle unit. The first screw unit is configured such that when the nozzle unit is rotated, the nozzle unit is in the ejection direction. The control unit is configured to move in a direction away from the application object in accordance with the discharge of the target discharge amount of the coating material from the discharge hole. In addition, by rotating the nozzle part relative to the holding part, Which comprises suppressing.

  According to this, torsional stress can be applied to the discharged coating material by the rotation of the nozzle portion. Further, by moving the nozzle portion, not only the torsional stress but also a stress acting in a direction in which the nozzle portion is separated from the application target can be applied to the coating material. Therefore, stringing of the coating material at the end of coating can be more effectively suppressed.

It is a side view which shows schematic structure of the coating device which concerns on 1st Embodiment. It is sectional drawing which shows the detailed structure of the nozzle part in a 1st communication state. It is sectional drawing which follows the III-III line | wire of FIG. 1, and is a figure for demonstrating the rotation angle of the nozzle part in a 1st communication state. It is sectional drawing for demonstrating the rotation angle of the nozzle part in a 1st non-communication state, and respond | corresponds to FIG. It is sectional drawing which shows the detailed structure of the nozzle part in a 1st non-communication state. It is sectional drawing for demonstrating the rotation angle of the nozzle part in a 1st non-communication state, and respond | corresponds to FIG. It is sectional drawing which follows the VII-VII line of FIG. 1, and is a figure for demonstrating arrangement | positioning of the rotation suppression part in a 1st communication state, and a 2nd protrusion part. It is a figure for demonstrating arrangement | positioning of the rotation suppression part and 2nd protrusion part in a 1st non-communication state, and respond | corresponds to FIG. It is a side view which shows schematic structure of the nozzle part and holding | maintenance part of the coating device which concerns on 2nd Embodiment. It is sectional drawing which shows the detailed structure of the nozzle part in a coating material feeding period. It is sectional drawing which shows the detailed structure of the nozzle part after the coating material feeding period end. It is sectional drawing which follows the XII-XII line | wire of FIG. 9, and is a figure for demonstrating the rotation angle of the nozzle part in a coating material feeding period. It is sectional drawing for demonstrating the rotation angle of the nozzle part after the coating material feeding period completion | finish, Comprising: It corresponds to FIG. It is sectional drawing which shows the detailed structure of the nozzle part in the 1st communication state of the coating device which concerns on a modification. It is sectional drawing which shows the detailed structure of the nozzle part in a 1st non-communication state. It is sectional drawing which shows the detailed structure of the nozzle part in the coating device which concerns on 3rd Embodiment. It is a side view which shows schematic structure of the coating device which concerns on 4th Embodiment. It is sectional drawing which shows the detailed structure of the nozzle part in a 2nd communication state. It is sectional drawing which follows the XIX-XIX line | wire of FIG. 17, and is a figure for demonstrating the rotation angle of the nozzle part in a 2nd communication state. It is sectional drawing which shows the detailed structure of the nozzle part in a 1st communication state. It is sectional drawing for demonstrating the rotation angle of the nozzle part in a 1st communication state, and respond | corresponds to FIG.

  Embodiments of the present invention will be described below with reference to the drawings. In the following embodiments, common or related elements are given the same reference numerals. In the following, the discharge direction is indicated as the Z direction, the specific direction perpendicular to the Z direction is indicated as the X direction, and the direction perpendicular to the Z direction and the X direction is indicated as the Y direction.

(First embodiment)
First, based on FIGS. 1-8, the structure of the coating device 10 which concerns on this embodiment is demonstrated. 7 and 8 indicate the trajectory of the second protrusion 32 when the nozzle unit 20 rotates.

  As shown in FIG. 1, the coating device 10 is a device that applies a coating material 200 to a coating object 300. The coating apparatus 10 includes a nozzle unit 20, a coating material supply unit 40, and a control unit 50. In the present embodiment, the coating apparatus 10 further includes a holding unit 60, a rotation suppressing unit 70, a motor 80, an object driving unit 90, and a load cell (not shown).

  As shown in FIG. 2, the nozzle unit 20 has a coating material supply hole 22 and a discharge hole 24. The nozzle portion 20 has an internal space 26 that extends along the Z direction. The coating material supply hole 22 is formed in the side wall 28 of the wall surface surrounding the internal space 26. The discharge hole 24 is formed at one end of the nozzle unit 20 on the application target 300 side in the Z direction. The coating material 200 supplied from the coating material supply hole 22 is accommodated in the internal space 26. The coating material 200 accommodated in the internal space 26 is discharged from the discharge hole 24 in the Z direction. The load cell detects the load of the coating material 200 accommodated in the internal space 26 and the nozzle unit 20 itself, and outputs a detection signal to the control unit 50.

  The nozzle unit 20 is rotatable around the axis about the discharge direction. That is, it can be rotated around the axis about the Z direction. The rotation axis of the nozzle unit 20 passes through the center O of the side wall 28 in the XY plane. In addition, the nozzle portion 20 includes a first protrusion 30 that is formed to protrude outward from the side wall 28 in the XY plane. The first projecting portion 30 is formed so as to surround the side wall 28 in the XY plane, and fits with the groove portion 62 in the holding portion 60. For example, the first protrusion 30 is formed in an annular shape over the entire circumference of the side wall 28.

  In addition, the nozzle unit 20 has a second protrusion 32. The second protrusion 32 is formed to protrude outward from the side wall 28 in the XY plane at a position different from the first protrusion 30 on the side wall 28. The 2nd protrusion part 32 is formed in the position equal to the rotation suppression part 70 in a Z direction. The 2nd protrusion part 32 is corresponded to the protrusion part as described in a claim.

  The coating material supply unit 40 supplies the coating material 200 to the nozzle unit 20. The coating material supply unit 40 includes a first supply pipe 42 and a coating material feeding unit (not shown). The coating material feeding unit feeds the coating material 200 to the first supply pipe 42 and employs, for example, a pump. The first supply pipe 42 has a substantially cylindrical shape formed along the X direction, and is formed so that one end surface thereof is in contact with the side wall 28. The inner diameter of the first supply pipe 42 and the diameter of the coating material supply hole 22 are equal to each other.

  As shown in FIGS. 2 and 3, the first supply pipe 42 can communicate with the coating material supply hole 22 of the nozzle unit 20. Hereinafter, a state in which the coating material supply hole 22 and the first supply pipe 42 are communicated is referred to as a first communication state. In the case of the first communication state, the opening on the side wall 28 side of the first supply pipe 42 and the coating material supply hole 22 just overlap.

  When the nozzle portion 20 is rotated from the first communication state, the communication between the coating material supply hole 22 and the first supply pipe 42 can be blocked as shown in FIGS. Hereinafter, a state where the communication between the coating material supply hole 22 and the first supply pipe 42 is blocked is referred to as a first non-communication state.

  The control unit 50 controls the rotation of the nozzle unit 20. The control unit 50 is configured to include, for example, a microcomputer. The control unit 50 controls the rotation of the nozzle unit 20 by outputting a control signal to the motor 80 and controlling the rotation of the motor 80. The control unit 50 also outputs a control signal to the coating material feeding unit and the object driving unit 90 to perform control. The control unit 50 controls the rotation of the nozzle unit 20 based on the feedback signal of the coating material feeding unit, the detection signal of the load cell, and the like.

  The holding unit 60 is disposed around the side wall 28 of the nozzle unit 20 and holds the nozzle unit 20. The holding part 60 is formed in a substantially cylindrical shape formed along the Z direction, and one end on the application target object 300 side is open. The holding part 60 has a groove part 62 that fits into the first projecting part 30 of the nozzle part 20. The groove part 62 is formed over the entire circumference of the holding part 60. As the first projecting portion 30 and the groove portion 62 are fitted, the holding portion 60 holds the nozzle portion 20 rotatably. The holding unit 60 is formed integrally with the first supply pipe 42 and the rotation suppressing unit 70.

  The rotation suppression unit 70 is disposed around the nozzle unit 20 in the XY plane and suppresses the rotation of the nozzle unit 20. In the present embodiment, the rotation suppression unit 70 is formed so as to protrude from the holding unit 60 toward the application object 300 in the Z direction. The rotation suppression unit 70 is disposed in the trajectory of the second protrusion 32 in the XY plane. Hereinafter, with reference to the direction from the nozzle unit 20 toward the application target 300 in the Z direction, clockwise rotation is indicated as a normal rotation direction and counterclockwise rotation is indicated as a reverse rotation direction.

  As shown in FIG. 7, in the first communication state, the rotation suppression unit 70 is located on the reverse rotation direction side of the second protrusion 32 and is in contact with the second protrusion 32. Therefore, it is suppressed that the nozzle part 20 rotates in the reverse rotation direction in the first communication state.

  When the nozzle unit 20 is rotated in the normal rotation direction from the first communication state, the first non-communication state is obtained. For example, as shown in FIG. 8, the nozzle portion 20 is rotated 180 degrees in the forward rotation direction from the first communication state. Since the rotation suppression unit 70 is formed integrally with the holding unit 60, the position of the rotation suppression unit 70 is unchanged even when the nozzle unit 20 rotates. Therefore, the second protrusion 32 is separated from the rotation suppression unit 70 by the rotation of the nozzle unit 20. When rotating the nozzle part 20 in the forward rotation direction, the nozzle part 20 can be rotated until the second protrusion 32 comes into contact with the rotation suppressing part 70. When changing from the first non-communication state to the first communication state, the nozzle unit 20 is rotated in the reverse rotation direction until the second protrusion 32 and the rotation suppression unit 70 come into contact with each other.

  The motor 80 rotates the nozzle unit 20 based on a control signal from the control unit 50. The motor 80 is disposed on the side of the holding unit 60 opposite to the application object 300 in the Z direction. The motor 80 has an output shaft 82 connected to the nozzle unit 20. The output shaft 82 is formed along the Z direction, penetrates the holding portion 60 and is connected to the nozzle portion 20. As the output shaft 82 rotates, the nozzle unit 20 rotates around the axis about the Z direction.

  The object driving unit 90 moves the application object 300 based on a control signal from the control unit 50. By moving the application target object 300, it is possible to select a position on the application target object 300 where the application material 200 is applied.

  Next, based on FIGS. 2-6, the process until the coating device 10 apply | coats the coating material 200 to the coating target object 300 is demonstrated.

  First, the control unit 50 outputs a control signal to the object driving unit 90. As a result, the object driving unit 90 moves the application object 300 so that the application material 200 is applied to the target location.

  Next, the control unit 50 outputs a control signal to the motor 80. Thereby, the motor 80 rotates the nozzle part 20, and it is set as the 1st communication state as shown in FIG.2 and FIG.3. Here, it is assumed that the nozzle unit 20 is in an empty state in which the coating material 200 is not accommodated in the internal space 26.

  Next, the control unit 50 outputs a control signal to the coating material feeding unit of the coating material supply unit 40. As a result, the coating material 200 is supplied from the first supply pipe 42 to the internal space 26 through the coating material supply hole 22. The coating material 200 supplied to the internal space 26 is discharged from the discharge hole 24 to the coating object 300 over time due to its own weight.

  Next, the control unit 50 determines whether or not a predetermined amount of the coating material 200 is supplied from the coating material supply unit 40 to the nozzle unit 20 based on the feedback signal from the coating material feeding unit. The control unit 50 outputs a control signal to the motor 80 to rotate the nozzle unit 20 in response to a predetermined amount of the coating material 200 being supplied to the nozzle unit 20. As a result, the first non-communication state is set as shown in FIGS. In the present embodiment, the nozzle portion 20 is rotated 30 degrees from the first communication state to be in the first non-communication state. Since the first non-communication state is established, the coating material 200 in the first supply pipe 42 is not supplied to the nozzle unit 20.

  In the period of the first communication state, the amount of the coating material 200 supplied to the empty nozzle unit 20 needs to be equal to or more than the target discharge amount discharged from the discharge hole 24. In the present embodiment, the nozzle unit 20 is rotated to be in the first non-communication state in response to the coating material 200 having the same amount as the target discharge amount being supplied to the nozzle unit 20 in the first communication state.

  Next, the control unit 50 determines whether or not a target discharge amount of the coating material 200 has been discharged from the discharge hole 24 based on the detection signal from the load cell. The control unit 50 outputs a control signal to the motor 80 and rotates the nozzle unit 20 in response to the discharge of the target discharge amount of the coating material 200. In the present embodiment, the nozzle unit 20 rotated in the normal rotation direction by 30 degrees from the first communication state in the above procedure is further rotated by 150 degrees in the normal rotation direction. During this rotation, the first communication state never occurs. In this embodiment, after all the coating materials 200 in the nozzle part 20 are discharged, the nozzle part 20 is rotated. When the coating material 200 is subsequently applied, the above procedure is repeated.

  Next, the effect of the above-described coating apparatus 10 will be described.

  According to the present embodiment, the control unit 50 rotates the nozzle unit 20 in response to the supply of a predetermined amount of the coating material 200 from the coating material supply unit 40 to the nozzle unit 20. By this rotation, the first non-communication state is established. Therefore, it is possible to suppress excessive supply of the coating material 200 to the nozzle unit 20. Moreover, according to the said structure, supply of the coating material 200 to the nozzle part 20 can be interrupted | blocked, without using a solenoid valve.

  According to the present embodiment, the nozzle unit 20 is rotatable around the axis about the Z direction. When the nozzle part 20 rotates around the axis, a torsional stress can be applied to the discharged coating material 200. Therefore, according to the above configuration in which the nozzle unit 20 rotates in response to the discharge of the coating material 200 having a target discharge amount from the discharge hole 24, the coating material 200 discharged from the nozzle unit 20 can be threaded. The stringing of the coating material 200 at the end of coating can be suppressed.

  Therefore, the rotation of the nozzle unit 20 can block the supply of the coating material 200 to the nozzle unit 20 and suppress stringing of the coating material 200. That is, with a simple configuration, the supply of the coating material 200 to the nozzle unit 20 can be blocked at the end of the coating of the coating material 200, and stringing of the coating material 200 can be suppressed.

  According to the present embodiment, when the nozzle unit 20 is rotated from the first non-communication state, the second protrusion 32 and the rotation suppression unit 70 are brought into contact with each other at a predetermined rotation angle to be in the first communication state. it can. Accordingly, the first supply pipe 42 and the coating material supply hole 22 can be communicated with each other with high positional accuracy in the first communication state.

  In the present embodiment, the control unit 50 controls the rotation of the nozzle unit 20 based on the load cell detection signal, but the present invention is not limited to this. For example, the nozzle unit 20 may include a sensor that detects the pressure in the internal space 26, and the control unit 50 may control the rotation of the nozzle unit 20 based on a detection signal from the sensor. By detecting the pressure in the internal space 26, the amount of the coating material 200 accommodated in the internal space 26 is determined. Further, the control unit 50 may determine whether or not the target discharge amount of the coating material 200 has been discharged from the discharge hole 24 based on the passage of a predetermined time.

  In this embodiment, although the rotation suppression part 70 showed the structure located in the reverse rotation direction side of the 2nd protrusion part 32 in a 1st communication state, it is not limited to this. A configuration in which the rotation suppression unit 70 is positioned on the positive rotation direction side of the second protrusion 32 in the first communication state may be employed. In that case, the first non-communication state can be obtained by rotating the nozzle portion 20 in the reverse rotation direction from the first communication state. Further, by rotating the nozzle portion 20 in the forward rotation direction, the first non-communication state can be changed to the first communication state.

  In the present embodiment, the coating material 200 is supplied from a state in which the nozzle portion 20 is empty to set the first non-communication state, and then all the supplied coating material 200 is discharged from the discharge holes 24. However, the present invention is not limited to this. A configuration in which the coating material 200 is supplied to the nozzle unit 20 from a state in which the coating material 200 is accommodated in the internal space 26 may be employed.

  In the present embodiment, the nozzle unit 20 is rotated after all the coating material 200 in the internal space 26 has been discharged, but this is not a limitation. The coating material 200 may remain in the internal space 26 as long as the nozzle unit 20 is rotated after the coating material 200 having a target ejection amount is ejected.

(Second Embodiment)
In the present embodiment, description of portions common to the coating apparatus 10 shown in the first embodiment is omitted.

  In the present embodiment, as shown in FIGS. 9 to 11, the nozzle unit 20 and the holding unit 60 are screw-coupled. The nozzle portion 20 has a first screw portion 34 on the outer periphery of the side wall 28. The holding portion 60 has a second screw portion 64 that fits with the first screw portion 34 at a portion facing the first screw portion 34 of the nozzle portion 20. The first screw part 34 is formed with the Z direction as an axis so that the nozzle part 20 moves along the Z direction when the nozzle part 20 is rotated. When the first screw part 34 and the second screw part 64 are screw-coupled, the holding part 60 holds the nozzle part 20 rotatably.

  The holding unit 60 also has a supply pipe connection hole 66 for connecting the first supply pipe 42 to the coating material supply hole 22. The first supply pipe 42 is connected to the coating material supply hole 22 through the supply pipe connection hole 66. The supply pipe connection hole 66 is formed at a position different from the second screw part 64 on the outer wall of the holding part 60.

  In the present embodiment, as shown in FIGS. 12 and 13, the first supply pipe 42 and the coating material supply hole 22 are fixed to each other in the first communication state. That is, the communication between the first supply pipe 42 and the coating material supply hole 22 is maintained even when the nozzle portion 20 rotates. Therefore, the supply pipe connection hole 66 opens widely in the XY plane on the outer wall of the holding part 60 to such an extent that the first supply pipe 42 can rotate according to the rotation of the nozzle part 20. In the present embodiment, the supply pipe connection hole 66 opens 180 degrees on the outer wall of the holding unit 60 with respect to the center O in the XY plane.

  The control unit 50 outputs a control signal to the coating material feeding unit. Thereby, the coating material feeding unit feeds the coating material 200 to the internal space 26 via the first supply pipe 42. In the present embodiment, a period during which the coating feeding unit feeds the coating material 200 to the nozzle unit 20 is referred to as a coating material feeding period. Here, as shown in FIG. 10, in the coating material feeding period, the separation distance between the coating object 300 and the nozzle unit 20 in the Z direction is defined as a distance L1.

  The control unit 50 determines whether or not a predetermined amount of coating material is supplied from the coating material supply unit 40 to the nozzle unit 20 based on the feedback signal of the coating material feeding unit. When a predetermined amount of coating material is supplied to the nozzle unit 20, the control unit 50 outputs a control signal to the coating material feeding unit to stop the supply of the coating material 200. Thereby, the coating material supply period ends.

  Further, the control unit 50 determines whether or not the target discharge amount of the coating material 200 has been discharged from the discharge hole 24 based on the load cell detection signal. The control unit 50 outputs a control signal to the motor 80 and rotates the nozzle unit 20 in response to the discharge of the target discharge amount of the coating material 200. In the present embodiment, the nozzle portion 20 is rotated 45 degrees in the forward rotation direction as shown in FIG. 13 from the state in which the extending direction of the first supply pipe 42 is parallel to the X direction as shown in FIG.

  As shown in FIG. 11, after the nozzle unit 20 is rotated, the distance between the coating object 300 and the nozzle unit 20 in the Z direction is defined as a distance L2. The control unit 50 moves the nozzle unit 20 in a direction away from the application target object 300 by rotating the nozzle unit 20. That is, the control unit 50 rotates the nozzle unit 20 so that the distance L2 is larger than the distance L1.

  According to this embodiment, torsional stress can be applied to the discharged coating material 200 by the rotation of the nozzle portion 20. Further, not only the torsional stress but also the stress that acts in the direction in which the nozzle unit 20 moves away from the application target 300 can be applied to the coating material 200 by the movement of the nozzle unit 20. Therefore, stringing of the coating material 200 at the end of coating can be more effectively suppressed.

  In the present embodiment, the nozzle unit 20 is rotated 45 degrees in the forward rotation direction, but the present invention is not limited to this. The rotation angle and the rotation direction of the nozzle unit 20 can be adopted as long as the nozzle unit 20 is moved in a direction away from the application target object 300.

  In the present embodiment, the first supply pipe 42 and the coating material supply hole 22 are fixed to each other in the first communication state, but the present invention is not limited to this. As shown in FIGS. 14 and 15, a configuration in which the first communication state and the first non-communication state are selected according to the rotation of the nozzle unit 20 may be employed. As in the first embodiment, the holding unit 60 and the first supply pipe 42 are integrally formed, and the nozzle unit 20 is rotatably held by the holding unit 60. However, the nozzle part 20 and the holding | maintenance part 60 are screw-coupled with respect to 1st Embodiment.

  In this case, the control unit 50 outputs a control signal to the motor 80 to rotate the nozzle unit 20 in response to the supply of a predetermined amount of the coating material 200 from the coating material supply unit 40 to the nozzle unit 20. Next, the control unit 50 rotates the nozzle unit 20 in accordance with the discharge of the target discharge amount of the coating material 200, and moves the nozzle unit 20 in a direction away from the application target 300. According to this, in addition to the effect of this embodiment, there can exist an effect similar to 1st Embodiment.

(Third embodiment)
In the present embodiment, description of portions common to the coating apparatus 10 shown in the first embodiment is omitted. In the present embodiment, the nozzle portion 20 and the holding portion 60 are screwed together as in the second embodiment.

  In the present embodiment, as shown in FIG. 16, the coating apparatus 10 includes a cleaning liquid supply unit 100 that supplies a cleaning liquid 400. The nozzle unit 20 has a cleaning liquid supply hole 36 to which the cleaning liquid 400 is supplied. The cleaning liquid supply hole 36 is formed in the side wall 28.

  The cleaning liquid supply unit 100 includes a cleaning liquid supply pipe 102 and a cleaning liquid feed unit (not shown). The cleaning liquid supply pipe 102 has a substantially cylindrical shape formed along the X direction, and is disposed in contact with the side wall 28 at a position different from the first supply pipe 42. The cleaning liquid supply pipe 102 is formed integrally with the holding unit 60. By the rotation of the nozzle unit 20, communication between the cleaning liquid supply pipe 102 and the cleaning liquid supply hole 36 is selected.

  The control unit 50 causes the cleaning liquid supply pipe 102 and the cleaning liquid supply hole 36 to communicate with each other by rotating the nozzle unit 20 after the nozzle unit 20 has applied the target discharge amount of the coating material 200. Next, the cleaning liquid supply unit 100 supplies the cleaning liquid 400 from the cleaning liquid supply pipe 102 to the internal space 26 through the cleaning liquid supply hole 36. The cleaning liquid 400 supplied to the internal space 26 is discharged from the discharge hole 24.

  According to this, the internal space 26 of the nozzle part 20 can be wash | cleaned with a simple structure, and it can suppress that the nozzle part 20 is disposable. Therefore, the cost of using the new nozzle unit 20 can be suppressed.

  In the present embodiment, the configuration is such that the communication and non-communication of the cleaning liquid supply pipe 102 and the cleaning liquid supply hole 36 are selected by the rotation of the nozzle unit 20, but the present invention is not limited to this. Similarly to the first supply pipe 42 and the coating material supply hole 22 of the second embodiment, a configuration in which the cleaning liquid supply pipe 102 and the cleaning liquid supply hole 36 are fixed to each other in a connected state may be employed.

  In the present embodiment, the configuration in which the nozzle portion 20 and the holding portion 60 are screw-coupled is shown, but the present invention is not limited to this. The holding unit 60 can be adopted as long as the nozzle unit 20 is rotatably held. For example, the structure which the 1st protrusion part 30 of the nozzle part 20 and the groove part 62 of the holding | maintenance part 60 fit may be sufficient like 1st Embodiment.

(Fourth embodiment)
In the present embodiment, description of portions common to the coating apparatus 10 shown in the first embodiment is omitted. In the present embodiment, the nozzle portion 20 and the holding portion 60 are screwed together as in the second embodiment.

  As shown in FIG. 17, the coating apparatus 10 includes an air supply unit 110 that supplies air (not shown). As shown in FIGS. 18 to 21, the nozzle unit 20 has an air supply hole 38 through which air is supplied. The air supply hole 38 is formed in the side wall 28. The air supply hole 38 is formed in the side wall 28 with an interval of 90 degrees from the coating material supply hole 22 to the positive rotation direction side in the XY plane.

  The air supply unit 110 includes an air feed unit (not shown) and a second supply pipe 112, and adjusts the pressure of the internal space 26 by supplying air to the nozzle unit 20. The air feed unit sends air to the second supply pipe 112, and employs a regulator, for example. The second supply pipe 112 has a substantially cylindrical shape formed along the X direction, and is disposed at a position different from the first supply pipe 42 in the nozzle unit 20. In the present embodiment, the second supply pipe 112 is formed on the side opposite to the first supply pipe 42 in the nozzle portion 20 so that one end surface of the second supply pipe 112 is in contact with the side wall 28. The inner diameter of the second supply pipe 112 and the diameter of the air supply hole 38 are equal to each other. The second supply pipe 112 is formed integrally with the holding unit 60.

  As shown in FIGS. 18 and 19, the second supply pipe 112 can communicate with the air supply hole 38. Hereinafter, a state in which the air supply hole 38 and the second supply pipe 112 are communicated is referred to as a second communication state. In the case of the second communication state, the opening on the side wall 28 side of the second supply pipe 112 and the air supply hole 38 just overlap.

  When the nozzle unit 20 is rotated from the second communication state, the communication between the air supply hole 38 and the second supply pipe 112 can be blocked as shown in FIGS. Hereinafter, a state where the communication between the air supply hole 38 and the second supply pipe 112 is blocked is referred to as a second non-communication state. In the present embodiment, when the nozzle portion 20 is rotated 90 degrees in the reverse rotation direction from the second communication state shown in FIG. 19, the first communication state shown in FIG. 21 is obtained. Similarly, in the case of the first communication state, when the nozzle portion 20 is rotated 90 degrees in the forward rotation direction, the second communication state is established. In the present embodiment, the first communication state is the second non-communication state, and the second communication state is the first non-communication state.

  When the control unit 50 supplies a predetermined amount of the coating material 200 to the inside in the first communication state, the control unit 50 rotates the nozzle unit 20 by 90 degrees in the normal rotation direction to set the second communication state. When the second communication state is established, the control unit 50 outputs a control signal to the air feeding unit to adjust the pressure in the internal space 26. By supplying a predetermined amount of air to the internal space 26, a target discharge amount of the coating material 200 is discharged from the discharge holes 24.

  In the present embodiment, the diameter of the discharge hole 24 and the viscosity of the coating material 200 are adjusted so that the coating material 200 in the internal space 26 is not discharged from the discharge hole 24 unless air is supplied. That is, the coating material 200 is discharged from the discharge hole 24 only in the second communication state.

  In response to a predetermined amount of air being supplied to the internal space 26, the control unit 50 rotates the nozzle unit 20 by 90 degrees in the reverse rotation direction, thereby setting the second non-communication state and the first communication state. By this rotation, stringing of the coating material 200 is suppressed. By repeating the above procedure, the coating material 200 is continuously applied.

  According to the present embodiment, the air supply unit 110 can supply air to the nozzle unit 20 and discharge the coating material 200 from the discharge hole 24. Therefore, it is possible to suppress a decrease in accuracy of the discharge amount of the coating material 200 discharged from the nozzle unit 20.

  When the air supplied to the nozzle unit 20 flows into the first supply pipe 42, there is a concern that the supply of the coating material 200 in the coating material supply unit 40 may be suppressed. Further, when air flows into the first supply pipe 42, it may be difficult to control the amount of air supplied from the air supply unit 110 to the nozzle unit 20. According to the present embodiment, the air supply unit 110 enters the second communication state only in the first non-communication state, and supplies air to the nozzle unit 20. According to this, it is possible to suppress the air supplied from the air supply unit 110 to the nozzle unit 20 from flowing into the first supply pipe 42. Therefore, it is possible to suppress a decrease in accuracy of the discharge amount of the coating material 200 discharged from the nozzle unit 20.

  According to the present embodiment, the control unit 50 rotates the nozzle unit 20 in accordance with the supply of the target supply amount of air to the nozzle unit 20 to be in the second non-communication state. Therefore, it is possible to suppress excessive supply of air to the nozzle unit 20 and backflow of air to the second supply pipe 112. Therefore, it is possible to suppress a decrease in accuracy of the discharge amount of the coating material 200 discharged from the nozzle unit 20. A configuration in which the supply of air to the nozzle unit 20 is blocked using an electromagnetic valve is also conceivable. On the other hand, according to the said structure, since the supply of the air to the nozzle part 20 can be interrupted | blocked, without using an electromagnetic valve, a cost increase can be suppressed.

  In the present embodiment, the second communication state and the second non-communication state are selected according to the rotation of the nozzle unit 20, but the present invention is not limited to this. Similarly to the first supply pipe 42 and the coating material supply hole 22 of the second embodiment, a configuration in which the second supply pipe 112 and the air supply hole 38 are fixed to each other in the second communication state may be employed.

  In the present embodiment, the configuration in which the nozzle portion 20 and the holding portion 60 are screw-coupled is shown, but the present invention is not limited to this. The holding unit 60 can be adopted as long as the nozzle unit 20 is rotatably held. For example, the structure which the 1st protrusion part 30 of the nozzle part 20 and the groove part 62 of the holding | maintenance part 60 fit may be sufficient like 1st Embodiment.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  In the said embodiment, although the coating device 10 showed the structure which has the holding | maintenance part 60, the rotation suppression part 70, the motor 80, and the target object drive part 90, it is not limited to this. The coating device 10 can be employed as long as it has at least the nozzle unit 20, the coating material supply unit 40, and the control unit 50 and applies the coating material 200 to the coating object 300.

  In the said embodiment, although the nozzle part 20 showed the structure which has the internal space 26 and the side wall 28, it is not limited to this. The nozzle unit 20 includes at least a coating material supply hole 22 and a discharge hole 24. The nozzle unit 20 discharges the coating material 200 from the discharge hole 24, and can be adopted as long as it can rotate around the axis about the discharge direction. it can.

  In the said embodiment, although the coating material supply hole 22 showed the structure formed in the side wall 28, it is not limited to this. The coating material supply hole 22 can be used as long as it can communicate with the first supply pipe 42 and the coating material 200 is supplied from the first supply pipe 42.

  In the above-described embodiment, the configuration in which the holding unit 60 is formed integrally with the first supply pipe 42 and the rotation suppression unit 70 is shown, but the present invention is not limited to this. The holding part 60, the 1st supply pipe 42, and the rotation suppression part 70 may be formed separately. Moreover, in the said embodiment, although the rotation angle of the nozzle part 20 was specifically shown like 30 degree | times etc., it is not limited to this.

  In the said embodiment, the nozzle part 20 was rotated in two steps. Specifically, it was rotated to change from the first communication state to the first non-communication state, and further rotated to suppress stringing of the coating material 200. However, the present invention is not limited to this. For example, if the air supply unit 110 is configured to supply air to the nozzle unit 20, the nozzle unit 20 can be rotated once.

  Specifically, at the same time that the coating material supply unit 40 supplies a predetermined amount of the coating material 200 to the nozzle unit 20, the air supply unit 110 supplies air to the nozzle unit 20 to discharge the coating material 200 with a target discharge amount. According to this, the control part 50 can suppress stringing while changing from the 1st communication state to the 1st non-communication state by rotating the nozzle part 20. FIG.

  DESCRIPTION OF SYMBOLS 10 ... Coating apparatus, 20 ... Nozzle part, 22 ... Coating material supply hole, 24 ... Discharge hole, 26 ... Internal space, 28 ... Side wall, 30 ... 1st protrusion Part 32... Second protrusion 34. First screw part 36. Cleaning liquid supply hole 38. Air supply hole 40. Coating material supply part 42. DESCRIPTION OF SYMBOLS 1 Supply pipe, 50 ... Control part, 60 ... Holding part, 62 ... Groove part, 64 ... 2nd screw part, 66 ... Supply pipe connection hole, 70 ... Rotation suppression part, DESCRIPTION OF SYMBOLS 80 ... Motor, 82 ... Output shaft, 90 ... Object drive part, 100 ... Cleaning liquid supply part, 102 ... Cleaning liquid supply pipe, 110 ... Air supply part, 112 ... Second supply pipe, 200 ... coating material, 300 ... coating object, 400 ... cleaning liquid

Claims (8)

In the coating apparatus (10) for applying the coating material (200) to the coating object (300),
It has an application material supply hole (22) to which the application material is supplied, and an ejection hole (24) for discharging the supplied application material, and the application material is applied from the discharge hole to the application object. A nozzle portion (20) capable of discharging and rotating around an axis about the discharge direction;
A first supply pipe (42) capable of communicating with the application material supply hole of the nozzle section; and an application material supply section (40) for supplying the application material from the first supply pipe;
A control unit (50) for controlling the rotation of the nozzle unit,
The control unit rotates the nozzle unit in response to the supply of a predetermined amount of the coating material from the coating material supply unit to the nozzle unit, so that the coating material supply hole of the nozzle unit and the first nozzle are rotated. 1 to cut off the stringing of the coating material by blocking the communication with the supply pipe and rotating the nozzle portion in response to the ejection material of the target ejection amount being ejected from the ejection hole. A characteristic coating apparatus. A holding part (60) for holding the nozzle part;
The nozzle part has a first screw part (34),
The holding portion has a second screw portion (64) that can be screw-coupled to the first screw portion, and holds the nozzle portion by screw-coupling the first screw portion and the second screw portion. ,
The first screw part is formed around the discharge direction so that the nozzle part moves along the discharge direction when the nozzle part is rotated,
The control unit moves the nozzle unit to the holding unit so that the nozzle unit moves in a direction away from the application object in response to ejection of the target discharge amount of the coating material from the discharge hole. The coating apparatus according to claim 1, wherein stringing of the coating material is suppressed by rotating the coating material. A rotation suppressing part (70) disposed around the nozzle part and suppressing rotation of the nozzle part;
The nozzle part has a protruding part (32) formed to protrude toward the outside of the nozzle part,
The rotation suppression unit suppresses the nozzle unit from rotating in one rotation direction by contacting the protrusion when the coating material supply hole and the first supply pipe communicate with each other. The coating apparatus according to claim 1 or 2, wherein the coating apparatus is characterized. An air supply unit (110) having a second supply pipe (112) and supplying air from the second supply pipe;
The nozzle part has an air supply hole (38) through which the air is supplied,
The second supply pipe can communicate with the air supply hole;
When the air supply hole and the second supply pipe communicate with each other, the air supply unit supplies the air to the nozzle unit to discharge the coating material of the target discharge amount from the discharge hole. The coating apparatus according to any one of claims 1 to 3, wherein   The coating apparatus according to claim 4, wherein the air supply unit supplies the air to the nozzle unit only when communication between the coating material supply hole and the first supply pipe is blocked. The nozzle unit is rotatable with respect to the air supply unit around the axis with the discharge direction as an axis,
The control unit blocks communication between the air supply hole of the nozzle unit and the second supply pipe by rotating the nozzle unit in response to a predetermined amount of the air being supplied to the nozzle unit. The coating apparatus according to claim 4, wherein the coating apparatus is a coating apparatus. In a coating apparatus that applies a coating material to a coating object,
It has a first screw part and a discharge hole for discharging the coating material, discharges the coating material from the discharge hole to the application object, and is rotatable around the axis about the discharge direction. A nozzle part;
A second screw portion that can be screw-coupled to the first screw portion, and a holding portion that holds the nozzle portion by screw-coupling the first screw portion and the second screw portion;
A control unit for controlling the rotation of the nozzle unit,
The first screw part is formed around the discharge direction so that the nozzle part moves along the discharge direction when the nozzle part is rotated,
The control unit moves the nozzle unit to the holding unit so that the nozzle unit moves in a direction away from the application object in response to ejection of the target discharge amount of the coating material from the discharge hole. A coating apparatus characterized by suppressing stringing of the coating material by rotating the coating material. The nozzle part has a cleaning liquid supply hole (36) to which a cleaning liquid (400) is supplied,
The coating apparatus according to claim 1, wherein the discharge hole is capable of discharging the cleaning liquid.

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