JP2020089809A - Painting device - Google Patents

Abstract

To allow painting materials to be supplied by a stable pressure and reduce time during which painting work cannot be performed.SOLUTION: A painting device 100 comprises a first supply pump 41, a second supply pump 42, a painting main body part 2, a first shut-off valve 53 and a second shut-off valve 54. The first supply pump 41 and the second supply pump 42 can discharge painting materials respectively. In the painting main body part 2, a plurality of discharge nozzles 21 are formed. By a discharge pressure of the first supply pump 41, the painting materials are supplied to the painting main body part 2, and when the second supply pump 42 do not discharge the painting materials, the second shut-off valve 54 can inhibit supply of the painting materials to a part or all of a plurality of discharge nozzles 21. By a discharge pressure of the second supply pump 42, the painting materials are supplied to the painting main body part 2, and when the second supply pump 41 does not discharge the painting materials, the first shut-off valve 53 can inhibit supply of the painting materials to the part or all of the plurality of discharge nozzles 21.SELECTED DRAWING: Figure 5

Description

The present invention relates to a coating device for coating a work with a coating material.

2. Description of the Related Art Conventionally, there is known a coating device that automatically coats a work such as a home electric appliance or a car body. Patent Document 1 discloses a coating apparatus (application apparatus) of this type.

The coating device of Patent Document 1 has a nozzle device that discharges a damping material onto a vehicle body from a nozzle hole, a supply pump and a supply passage, and continuously drives the supply pump to supply the damping material to the pump. From the supply passage to the supply passage in a substantially fixed amount, a return passage for branching from the supply passage to return the damping material to the supply pump, and a storage section provided in the return passage for storing the damping material And a return pump having. This application device is configured to switch the supply destination of the damping material to the nozzle hole or the return passage based on the application information of the damping material to the vehicle body. After the application is completed, the return pump sends the damping material stored in the storage section to the supply pump.

Patent No. 5527778

However, in the configuration of Patent Document 1, it is necessary to return the damping material stored in the storage portion of the return pump to the supply pump after the application is completed. Therefore, it took time until the next coating operation can be started.

The present invention has been made in view of the above circumstances, and an object thereof is to be able to supply a coating material at a stable pressure, reduce the time during which a coating operation cannot be performed, and perform coating efficiently. It is to provide a coating device that can be used.

The problem to be solved by the present invention is as described above. Next, means for solving the problem and its effect will be described.

According to the viewpoint of the present invention, a coating device having the following configuration is provided. That is, this coating device includes a first pump, a second pump, an injection unit, a moving unit, and a switching unit. The first pump can discharge the coating material. The second pump can discharge the coating material. A plurality of injection ports for injecting the coating material are formed in the injection unit. The moving unit is capable of moving the spraying unit relative to the work to be coated. The switching unit switches supply/stop of supply of the coating material to each of the injection ports. When the coating material is supplied to the spraying unit by the discharge pressure of the first pump and the second pump is not discharging the coating material, the switching unit may partially or entirely discharge the plurality of sprays. The supply of coating material to the mouth can be stopped. When the coating material is supplied to the spraying unit by the discharge pressure of the second pump and the first pump is not discharging the coating material, the switching unit may partially or entirely discharge the plurality of sprays. The supply of coating material to the mouth can be stopped.

With this, regardless of whether the coating material is sprayed from the spraying unit by the first pump or the second pump, the presence or absence of spraying from each spraying port can be switched to realize, for example, an appropriate coating pattern. Since the coating material can be sprayed while switching the discharge by the first pump and the discharge by the second pump, the time during which the coating material cannot be discharged can be shortened compared to the case where the coating material is discharged from only one pump, and the coating can be performed efficiently. It can be carried out.

According to the present invention, it is possible to supply a coating material at a stable pressure, shorten the time during which the coating operation cannot be performed, and provide a coating apparatus capable of efficiently performing coating.

The figure which shows a mode that a work is coated using the coating device which concerns on 1st Embodiment of this invention. The schematic diagram which shows a mode that a coating material is replenished to a 1st supply pump in a coating device. The schematic diagram which shows the standby state which a 1st supply pump discharges a coating material and does not inject a coating material from a discharge nozzle. The schematic diagram which shows a mode that a coating material is sprayed from all the discharge nozzles by the discharge pressure of a 1st supply pump. The schematic diagram which shows a mode that a coating material is sprayed from some discharge nozzles. The schematic diagram which shows a mode that a coating material is replenished to a 2nd supply pump in a coating device. The schematic diagram which shows the standby state which a 2nd supply pump discharges a coating material and does not inject a coating material from a discharge nozzle. The schematic diagram which shows a mode that a coating material is sprayed from all the discharge nozzles by the discharge pressure of a 2nd supply pump. The schematic diagram which shows a mode that a coating material is sprayed from some discharge nozzles. The schematic diagram which shows the structure of the coating device of 2nd Embodiment.

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a state in which a work W is coated using a coating apparatus 100 according to the first embodiment of the present invention. FIG. 2 is a schematic diagram showing how the coating material is supplied to the first supply pump 41 in the coating apparatus 100.

The coating apparatus 100 shown in FIG. 1 is used, for example, for automatically coating a work W, which is an object to be coated, with a coating material for soundproofing, rustproofing, vibration damping, and the like. The work W may be, for example, a floor panel of an automobile, but is not limited to this.

As shown in FIG. 1, the coating apparatus 100 includes a coating robot (moving unit, robot) 1 and a coating main body unit (jetting unit) 2. Further, as shown in FIG. 2, the coating device 100 includes a coating material supply unit 3.

As shown in FIG. 1, the coating robot 1 can be configured, for example, as a vertical articulated robot having six degrees of freedom of movement. The coating robot 1 includes a support base 11 and an articulated arm 12.

The support base 11 is attached at a predetermined position and supports the articulated arm 12. The multi-joint arm 12 has a plurality of joints, and the position and orientation of its tip can be changed in various ways. The painting body 2 is attached to the tip of the articulated arm 12.

The multi-joint arm 12 has actuators (not shown) for moving each joint. The coating robot 1 can move the coating body 2 with respect to the work W by moving the joint of the multi-joint arm 12 via this actuator.

The coating main body 2 includes a plurality (four in the present embodiment) of coating guns 20. As shown in FIG. 2, each coating gun 20 is formed with a discharge nozzle (spraying port) 21. The coating gun 20 can spray a coating material from a discharge nozzle 21.

The four coating guns 20 are oriented parallel to each other, and are arranged in a straight line at equal intervals. By spraying the coating material simultaneously from the four coating guns 20, a wide width can be coated at one time. In each of the coating guns 20, an open/close valve (for example, a needle valve) (not shown) is provided near the discharge nozzle 21. The on-off valve opens and closes the path of the coating material reaching the discharge nozzle 21. The on-off valve can switch injection/stoppage of injection of the coating material from the discharge nozzle 21 in the same manner as the first cutoff valve 53 and the second cutoff valve 54 described later.

As shown in FIG. 2, the coating material supply unit 3 includes a plurality of (two in this embodiment) supply systems 30. Each supply system 30 can supply the coating material to the coating main body 2 independently of each other. In the following description, in order to identify each of the two supply systems 30, the supply system 30 depicted on the upper side of FIG. 2 and the like is referred to as a first supply system 31, and the supply system depicted on the lower side. The system 30 may be referred to as the second supply system 32.

As shown in FIG. 2, the first supply system 31 includes a first supply pump (first pump) 41 and a first supply path (coating material path) 51. The first supply system 31 supplies the coating material stored in the first supply pump 41 to the coating main body 2 via the first supply path 51.

The first supply pump 41 is composed of a cylinder pump. As shown in FIG. 2 and the like, the first supply pump 41 includes a first cylinder 43 and a first piston 44.

The first cylinder 43 is formed in a cylindrical shape, and the first piston 44 is housed inside the first cylinder 43. In FIG. 2 and the like, the coating material is stored in the space defined by the first cylinder 43 and the first piston 44. In this way, the first cylinder 43 functions as a first storage unit that stores the coating material.

The first piston 44 is mechanically connected to the output shaft of the first electric motor 91 via a cylinder rod or the like. The first piston 44 is driven by the first electric motor 91. The operation of the first electric motor 91 is controlled by a controller (not shown).

The first piston 44 is driven by the first electric motor 91 and can move in the first cylinder 43 in the axial direction. When the first piston 44 moves toward one side of the first cylinder 43, the coating material in the first cylinder 43 is discharged to the first supply path 51. When the first piston 44 moves toward the opposite side, the coating material is sucked into the first cylinder 43 from the first supply path 81 or the first supply path 51.

In the following description, the moving direction of the first piston 44 when the first supply pump 41 discharges the coating material may be referred to as the discharge direction. The moving direction of the first piston 44 when the first supply pump 41 sucks the coating material may be referred to as the suction direction.

The first supply path 51 is composed of a pipe or the like through which the coating material flows. The first supply path 51 connects the first supply pump 41 and the coating main body section 2. The first supply route 51 includes a first main route 51a, a plurality of first branch routes 51b, and a common route 5. However, the common path 5 is common to the second supply path 52 described later.

A first manifold 61 is provided between the first main route 51a and the first branch route 51b. When the coating material flows toward the coating main body portion 2, the first manifold 61 distributes the coating material supplied via the first main path 51a to the respective first branch paths 51b. On the other hand, when the coating material flows toward the first supply pump 41, the first manifold 61 collectively supplies the coating material from each of the first branch paths 51b to the first main path 51a.

The first main path 51a connects the first supply pump 41 and the first manifold 61. A first pressure sensor (first pressure detection unit) 71 that detects the pressure of the flowing coating material is provided on the first main path 51a. The first pressure sensor 71 transmits the detected pressure to the control device.

A first temperature adjusting unit 57 that adjusts the temperature of the coating material flowing through the first main path 51a is arranged in the first main path 51a. The first temperature adjusting unit 57 heats or cools the coating material based on the detection value of a temperature detection sensor (not shown) so that the coating material becomes constant at a predetermined temperature.

The first branch path 51b connects the first manifold 61 and a common path 5 described later. In the coating apparatus 100 of this embodiment, four first branch paths 51b are provided according to the number of coating guns 20 included in the coating main body 2. An end of each of the first branch paths 51b opposite to the first manifold 61 is connected to each of the coating guns 20 included in the coating main body 2 via the common path 5.

A first cutoff valve (switching unit) 53 is provided on each of the first branch paths 51b. Since the number of the first branch paths 51b is 4, the number of the first cutoff valves 53 is also 4.

The first cutoff valve 53 is, for example, an electromagnetic valve. The first cutoff valve 53 opens and closes based on a control signal from a controller (not shown). By opening and closing the first cutoff valve 53, the flow of the coating material in the first supply path 51 is allowed/blocked. The opening/closing of each of the four first shutoff valves 53 is individually controlled by the control device. Only a part of the four first cutoff valves 53 can be closed under the control of the control device.

As shown in FIG. 2, the second supply system 32 includes a second supply pump (second pump) 42 and a second supply route (coating material route) 52. The second supply system 32 supplies the coating material stored in the second supply pump 42 to the coating main body 2 via the second supply path 52.

The second supply pump 42 is composed of a cylinder pump having a second cylinder 45 and a second piston 46. The configuration of the second supply pump 42 is the same as that of the first supply pump 41, and thus detailed description thereof will be omitted. The second cylinder 45 functions as a second storage unit that stores the coating material. The inner diameter of the second cylinder 45 is equal to the inner diameter of the first cylinder 43.

The second piston 46 is mechanically connected to the output shaft of the second electric motor 92 via a cylinder rod or the like. The second piston 46 is driven by the second electric motor 92. The operation of the second electric motor 92 is controlled by the control device.

The second supply path 52 is composed of a pipe or the like through which the coating material flows. The second supply path 52 connects the second supply pump 42 and the coating main body section 2. The second supply path 52 includes a second main path 52a, a plurality of second branch paths 52b, and a common path 5.

A second manifold 62 is provided between the second main route 52a and the second branch route 52b. When the coating material flows toward the coating body 2, the second manifold 62 distributes the coating material supplied via the second main path 52a to the respective second branch paths 52b. On the other hand, when the coating material flows toward the second supply pump 42, the second manifold 62 collectively supplies the coating material from the respective second branch paths 52b to the second main path 52a.

The second main path 52a connects the second supply path 52 and the second manifold 62. A second pressure sensor (second pressure detector) 72 that detects the pressure of the flowing coating material is provided on the second main path 52a. The second pressure sensor 72 transmits the detected pressure to the control device.

A second temperature adjusting unit 58 that adjusts the temperature of the coating material flowing through the second main path 52a is arranged in the second main path 52a. The second temperature adjusting unit 58 heats or cools the coating material based on the detection value of a temperature detection sensor (not shown) so that the coating material becomes constant at a predetermined temperature.

The second branch path 52b connects the second manifold 62 and the common path 5. In the coating apparatus 100 of the present embodiment, four second branch paths 52b are provided according to the number of coating guns 20 included in the coating main body 2 according to the number of coating guns 20. In each of the second branch paths 52b, the end on the opposite side of the second manifold 62 is connected to each of the coating guns 20 included in the coating main body section 2 via the common path 5.

Each of the second branch paths 52b is provided with a second cutoff valve (switching section) 54. Since the number of the second branch paths 52b is 4, the number of the second cutoff valves 54 is also 4.

The second cutoff valve 54 is, for example, an electromagnetic valve. The second cutoff valve 54 opens and closes based on a control signal from a control device (not shown). By opening and closing the second cutoff valve 54, the flow of the coating material in the second supply path 52 can be permitted or blocked. The opening/closing of each of the four second shutoff valves 54 is individually controlled by the control device. Only a part of the four second shutoff valves 54 can be closed under the control of the control device.

The coating apparatus 100 includes a common path 5 as shown in FIG. The common path 5 is commonly used in the first supply path 51 of the first supply system 31 and the second supply path 52 of the second supply system 32.

The common path 5 is configured as a part of the first supply path 51 and the second supply path 52, which is arranged closer to the coating main body 2 than the first cutoff valve 53 and the second cutoff valve 54. Four common paths 5 are provided. In the common path 5, each first branch path 51b is connected to a portion connected to the corresponding second branch path 52b. Each common path 5 is connected to each of the four coating guns 20.

In other words, the first branch path 51b and the second branch path 52b are connected to each other. One second branch path 52b is connected to one first branch path 51b. The coating material flowing through the first branch path 51b can flow toward the second supply pump 42 through the second branch path 52b. The coating material flowing through the second branch path 52b can flow toward the first supply pump 41 via the first branch path 51b.

As shown in FIG. 2 and the like, the coating apparatus 100 of the present embodiment includes a first replenishment path 81, a first replenishment path 81, a first replenishment path 81, and The second supply path 82, the first supply valve 83, and the second supply valve 84 are provided.

The first replenishment route 81 and the second replenishment route 82 are composed of piping or the like through which the coating material flows. A storage tank (not shown) is connected upstream of the first supply path 81. A storage tank (not shown) is connected upstream of the second supply path 82. The storage tank may be common to the first supply path 81 and the second supply path 82.

A first supply valve 83 is provided in the middle of the first supply path 81. A second supply valve 84 is provided in the middle of the second supply path 82. The first supply valve 83 and the second supply valve 84 are, for example, electromagnetic valves, and open and close based on a control signal from the control device. By opening and closing the first supply valve 83 and the second supply valve 84, the flow of the coating material in the first supply path 81 and the second supply path 82 can be allowed/blocked.

Next, the operation of the coating apparatus 100 when coating is performed with the discharge pressure of the first supply pump 41, and the flow of the coating material during each operation will be described in detail with reference to FIGS. 2 to 5.

First, as shown in FIG. 2, the first supply pump 41 receives the supply of the coating material from the first supply path 81 and supplies the coating material to the first cylinder 43 (suction operation).

Specifically, the control device closes the second supply valve 84, all the first cutoff valves 53, and all the second cutoff valves 54. On the other hand, the control device opens the first supply valve 83.

The first electric motor 91 moves the first piston 44 of the first supply pump 41 in the suction direction. As a result, the first supply pump 41 sucks the coating material from the first supply path 81 into the first cylinder 43 to supply the coating material.

At this time, the second electric motor 92 of the second supply pump 42 is stopped. In FIG. 2, a state in which a small amount of coating material is stored in the second cylinder 45 is depicted. However, the amount of coating material stored in the second cylinder 45 may be zero immediately after the coating apparatus 100 is operated.

When a sufficient amount of coating material is stored in the first cylinder 43, the coating apparatus 100 enters the state shown in FIG. 3 before the actual coating, and the pressure of the coating material flowing through the first supply path 51 becomes appropriate. Prepare to become.

Specifically, in FIG. 3, the control device closes the first supply valve 83 and the second supply valve 84. On the other hand, the control device opens all the first shutoff valves 53 and the second shutoff valves 54.

3 to 5, the control device closes the open/close valve of each coating gun 20 when the corresponding second shutoff valve 54 is open, and opens it when the second shutoff valve 54 is closed. To control. In the state of FIG. 3, the open/close valves of all the coating guns 20 are closed.

In this state, the control device drives the first electric motor 91 to move the first piston 44 of the first supply pump 41 in the discharge direction as shown by the white arrow in FIG. At this time, the drive speed of the first electric motor 91 is kept constant. As a result, the first supply pump 41 discharges the coating material at a constant flow rate (first discharge operation). Therefore, the coating material can be quantitatively supplied from the first supply pump 41.

The controller monitors the pressures of the first pressure sensor 71 and the second pressure sensor 72 while driving the first electric motor 91 as described above. Then, the control device controls the second electric motor 92 of the second supply pump 42 so that the detected pressures of the first pressure sensor 71 and the second pressure sensor 72 become predetermined pressures, respectively, and the second piston 46 is operated. If necessary, it is moved in the suction direction (second pressure adjusting operation).

In FIG. 3, suction is performed by the second supply pump 42 so that all of the coating material discharged from the first supply pump 41 flows to the second supply pump 42. If the suction amount of the second supply pump 42 is smaller than the discharge amount of the first supply pump 41, the pressure of the coating material rises, and vice versa. Therefore, by appropriately controlling the speed of the second piston 46 in the suction direction based on the pressures detected by the first pressure sensor 71 and the second pressure sensor 72, the pressure of the coating material in the first supply path 51 is It can be set to a predetermined pressure suitable for injection. The control device controls the second electric motor 92 so as to achieve this predetermined pressure.

In the state of FIG. 3, the coating material is not sprayed from the coating gun 20 and is stored in the second cylinder 45 of the second supply pump 42. FIG. 3 shows a transient state for preparing pressure, which can be switched to the state shown in FIG. 4 or 5 in a short time.

Based on the detection results of the first pressure sensor 71 and the second pressure sensor 72, the control device confirms that the pressure of the coating material flowing through the first supply path 51 and the like is stable within a predetermined range in the state of FIG. After confirming the above, start painting.

Specifically, the control device continues all the first discharge operation of the first supply pump 41 and the second pressure adjustment operation of the second supply pump 42, and as shown in FIG. 54 is closed, or some of the four second shutoff valves 54 are closed as shown in FIG. As described above, the open/close valve of the coating gun 20 is closed when the second shutoff valve 54 is open and is opened when the second shutoff valve 54 is closed. At this time, the four first cutoff valves 53 are all in the open state.

The coating material is sprayed onto the surface of the work W from the coating gun 20 corresponding to the closed second shutoff valve 54. On the other hand, when the second shutoff valve 54 is opened, the coating material is not sprayed from the corresponding coating gun 20. In this way, the second shutoff valve 54 opens/closes the path (second branch path 52b) on the side through which the coating material escapes, thereby supplying/stopping the supply of the coating material to some or all of the four discharge nozzles 21. Can be switched substantially.

The second cutoff valve 54 is opened/closed based on predetermined coating information. As a result, it is possible to switch between spraying/spraying of the coating material and to realize a coating pattern by spraying from some of the four discharge nozzles 21. The painting robot 1 moves the painting body 2 in synchronization with the opening and closing of the painting gun 20. As a result, a predetermined portion of the work W can be painted.

It is also conceivable that, when painting one work W at a place separated from each other, all four second shutoff valves 54 are opened during the painting process as shown in FIG. The work W is coated with the coating material while appropriately switching the states of FIGS. 3, 4, and 5.

The discharge speed of the first supply pump 41 does not change regardless of whether the four second shutoff valves 54 are opened or closed. In response to opening of the second shutoff valve 54 of at least one of the four, the second supply pump 42 performing the second pressure adjusting operation sucks the coating material. As a basic control, the control device obtains the number of closed second shutoff valves 54 (in other words, the number of coating guns 20 spraying the coating material) by the injection amount per one coating gun 20. The total injection amount that is obtained is subtracted from the discharge amount of the first supply pump 41, and the second supply pump 42 sucks the obtained amount. Thereby, the pressure of the flowing coating material can be made constant. Based on the above basic control, the control device appropriately corrects the speed of the second piston 46 in the suction direction based on the pressure detected by the first pressure sensor 71 and the second pressure sensor 72 (feedback control ), and controls the second electric motor 92 so as to realize the corrected speed. Thereby, the pressure of the coating material in the first supply path 51 can be stabilized at a predetermined pressure suitable for injection. Therefore, it is possible to secure the coating quality especially at the time of switching the injection/injection stop by the coating gun 20.

The coating material that has not been sprayed in the coating body 2 flows from the first supply path 51 to the second supply path 52 and is stored in the second cylinder 45 of the second supply pump 42.

The amount of coating material stored in the first cylinder 43 gradually decreases as the coating work is performed. At an appropriate time when the amount of the coating material stored in the first cylinder 43 becomes small, the control device stops the driving of the first electric motor 91 and ends the coating by the discharge pressure of the first supply pump 41.

At the time when the coating by the discharge pressure of the first supply pump 41 is completed, the second cylinder 45 stores a certain amount of coating material. After that, the control device switches to coating with the discharge pressure of the second supply pump 42.

Next, the operation of the coating apparatus 100 when coating is performed with the discharge pressure of the second supply pump 42, and the flow of the coating material during each operation will be described with reference to FIGS. 6 to 9.

In FIG. 6, the second supply pump 42 receives the supply of the coating material from the second supply path 82 and supplies the coating material to the second cylinder 45 (suction operation). The operation at this time is substantially the same as that in the case of FIG. 2 except that the first supply system 31 and the second supply system 32 are replaced, and therefore detailed description thereof will be omitted.

As described above, before the replenishment, the coating material that has flowed from the first supply pump 41 to the second supply pump 42 in the process in which the second supply pump 42 performs the second pressure adjusting operation is supplied to the second cylinder 45. It is stored. In the operation of FIG. 6, the new coating material supplied from the second supply path 82 is additionally supplied to the coating material originally stored in the second cylinder 45.

When a sufficient amount of coating material is stored in the second cylinder 45, the coating apparatus 100 is in the state shown in FIG. 7 before the actual coating. The coating apparatus 100 prepares the pressure of the coating material flowing through the second supply path 52 in the state of FIG. 7. The operation at this time is substantially the same as that in the case of FIG. 3 except that the first supply system 31 and the second supply system 32 are replaced, and therefore detailed description thereof will be omitted.

In FIGS. 7 to 9, the control device closes the opening/closing valve of each coating gun 20 when the corresponding first shutoff valve 53 is open, and opens it when the first shutoff valve 53 is closed. To control. In the state of FIG. 7, the open/close valves of all the coating guns 20 are closed.

When the second piston 46 of the second supply pump 42 is moved in the discharge direction as shown by the white arrow in FIG. 7, the drive speed of the second electric motor 92 is kept constant. As a result, the second supply pump 42 discharges the coating material at a constant flow rate (second discharging operation). Thereby, the coating material can be quantitatively supplied from the second supply pump 42.

The controller monitors the pressures of the second pressure sensor 72 and the first pressure sensor 71 while driving the second electric motor 92 as described above. Then, the control device controls the first electric motor 91 of the first supply pump 41 so that the detected pressures of the second pressure sensor 72 and the first pressure sensor 71 become predetermined pressures, respectively, and the first piston 44 is moved. If necessary, it is moved to the suction side (first pressure adjusting operation). This first pressure adjusting operation is substantially the same as the above-mentioned second pressure adjusting operation, and therefore its explanation is omitted.

The second discharge operation and the first pressure adjusting operation are continuously performed through the states shown in FIGS. 7 to 9. By the cooperation of the second supply pump 42 and the first supply pump 41, the flow rate of the coating material flowing through the second supply path 52 becomes constant and the pressure becomes stable.

After that, the controller coats the work W with the coating material while appropriately switching the states of FIGS. 7, 8 and 9.

Specifically, the control device switches between opening and closing the four first shutoff valves 53 while continuing the second discharge operation of the second supply pump 42 and the first pressure adjusting operation of the first supply pump 41. As described above, the open/close valve of the coating gun 20 is closed when the first shutoff valve 53 is open and is opened when the first shutoff valve 53 is closed. At this time, the four second shutoff valves 54 are all open.

The coating material is sprayed onto the surface of the work W from the coating gun 20 corresponding to the closed first shutoff valve 53. On the other hand, when the first shutoff valve 53 is opened, the coating material is not sprayed from the corresponding coating gun 20. In this way, the first shutoff valve 53 opens/closes the path (first branch path 51b) on the side through which the coating material escapes, thereby supplying/stopping the supply of the coating material to some or all of the four discharge nozzles 21. Can be switched substantially.

The amount of coating material stored in the second cylinder 45 gradually decreases as the coating work is performed. At an appropriate time when the amount of the coating material stored in the second cylinder 45 becomes small, the control device stops the driving of the second electric motor 92 and ends the coating by the discharge pressure of the second supply pump 42.

At the time when the coating by the discharge pressure of the second supply pump 42 is completed, the first cylinder 43 stores a small amount of coating material. After that, the control device returns to the state of FIG. 2 and switches to coating with the discharge pressure of the first supply pump 41.

As described above, before the replenishment, the coating material that has flowed from the second supply pump 42 to the first supply pump 41 in the process of the first supply pump 41 performing the first pressure adjustment operation is supplied to the first cylinder 43. It is stored. In the operation of FIG. 2, the new coating material supplied from the first supply path 81 is additionally supplied to the coating material originally stored in the first cylinder 43.

In the present embodiment, coating is performed on one or a plurality of works W while switching between coating with the discharge pressure of the first supply pump 41 and coating with the discharge pressure of the second supply pump 42. The roles of one pump generating the discharge pressure and the other pump adjusting the pressure alternate. Since the two supply systems 30 have substantially the same configuration, the configuration is simple and the cost can be reduced.

When the pump that supplies the discharge pressure is switched between the first supply pump 41 and the second supply pump 42, the coating material is replenished. It is preferable to use this replenishment time to replace the work W to be coated with another new work W, because work efficiency is improved.

However, the first supply pump 41 and the second supply pump 42 may alternately supply the discharge pressure during the coating of one work W. In this case, even if a large amount of coating material cannot be stored in the first supply pump 41 and the second supply pump 42, one large work W can be coated. Therefore, the first supply pump 41 and the second supply pump 42 can be downsized and the cost can be reduced.

A plurality of works W may be coated while one pump is supplying the discharge pressure.

The second supply pump 42 does not send the coating material stored in the second cylinder 45 in accordance with the second pressure adjusting operation (from FIG. 3 to FIG. 5) to the counterpart first supply pump 41, as shown in FIG. It is sprayed onto the work W together with the coating material newly replenished in (FIGS. 7 to 9). Similarly, the first supply pump 41 does not send the coating material stored in the first cylinder 43 along with the first pressure adjusting operation (FIGS. 7 to 9) to the second supply pump 42 on the other side. , And is sprayed onto the work W together with the coating material newly supplied in FIG. 2 (from FIG. 3 to FIG. 5). Therefore, the step of pumping the coating material to the pump on the other side can be omitted, so that the time during which coating is substantially impossible can be shortened. As a result, the coating efficiency can be improved.

As described above, the coating apparatus 100 of the present embodiment includes the first supply pump 41, the second supply pump 42, the coating main body 2, the coating robot 1, the first shutoff valve 53, and the second shutoff valve. And a valve 54. The first supply pump 41 and the second supply pump 42 can each discharge a coating material. A plurality of discharge nozzles 21 for injecting a coating material are formed on the coating body 2. The coating robot 1 can move the coating body 2 relative to the work W to be coated. The first shutoff valve 53 and the second shutoff valve 54 switch the supply/stop of the supply of the coating material to the respective discharge nozzles 21. When the coating material is supplied to the coating main body portion 2 by the discharge pressure of the first supply pump 41 and the second supply pump 42 is not discharging the coating material, the second shutoff valve 54 is part of a plurality of Alternatively, the supply of the coating material to all the discharge nozzles 21 can be stopped. When the coating material is supplied to the coating main body 2 by the discharge pressure of the second supply pump 42 and the first supply pump 41 is not discharging the coating material, the first shutoff valve 53 is part of a plurality of Alternatively, the supply of the coating material to all the discharge nozzles 21 can be stopped.

Thereby, regardless of which of the first supply pump 41 and the second supply pump 42 is used to inject the coating material from the coating main body 2, the presence or absence of the injection from each of the discharge nozzles 21 is switched to, for example, an appropriate coating pattern. Can be realized. Since the coating material can be sprayed while switching the discharge by the first supply pump 41 and the discharge by the second supply pump 42, the time during which the coating cannot be performed can be shortened as compared with the case of using one pump, and the coating can be performed efficiently. be able to.

Further, in the coating apparatus 100 of the present embodiment, when the coating material is supplied to the coating main body 2 by the first supply pump 41, the first supply pump 41 discharges the coating material at a constant flow rate. I do. When the first supply pump 41 performs the first discharge operation, the second supply pump 42 performs the second pressure adjustment operation of adjusting the pressure of the first supply path 51 to which the coating material is supplied by the first discharge operation. .. When the coating material is supplied to the coating main body 2 by the second supply pump 42, the second supply pump 42 performs the second discharging operation of discharging the coating material at a constant flow rate. When the second supply pump 42 performs the second discharge operation, the first supply pump 41 performs the first pressure adjustment operation of adjusting the pressure of the second supply path 52 to which the coating material is supplied by the second discharge operation. ..

As a result, the coating material can be sprayed from the discharge nozzle 21 while realizing a stable pressure, so that high coating quality can be realized. Further, since it is not necessary to specially provide the pressure adjusting device, it is possible to simplify the configuration of the coating device 100.

The coating device 100 of the present embodiment also includes a first pressure sensor 71 and a second pressure sensor 72. The first pressure sensor 71 detects the pressure in the first supply path 51 through which the coating material is supplied to the coating main body 2 by the first discharge operation of the first supply pump 41. The second pressure sensor 72 detects the pressure in the second supply path 52 through which the coating material is supplied to the coating main body 2 by the second discharge operation of the second supply pump 42. When the first supply pump 41 performs the first discharge operation and the second supply pump 42 performs the second pressure adjusting operation while the work W is being coated, the second supply pump 42 is the second pressure sensor. The coating material is sucked from the first supply path 51 so as to adjust the pressure based on the detection result of at least one of the 72 and the first pressure sensor 71. When the second supply pump 42 performs the second discharge operation and the first supply pump 41 performs the first pressure adjusting operation during the coating on the work W, the first supply pump 41 is the first pressure sensor. The coating material is sucked from the second supply path 52 so as to adjust the pressure based on the detection result of at least one of the 71 and the second pressure sensor 72.

Accordingly, the pressure control can be accurately performed by performing the pressure adjusting operation based on the detected pressure.

Further, in the coating apparatus 100 of the present embodiment, when the first supply pump 41 performs the first pressure adjusting operation, the first supply pump 41 has at least one of the first pressure sensor 71 and the second pressure sensor 72. The pressure is adjusted by feedback control based on the detection result. When the second supply pump 42 performs the second pressure adjustment operation, the second supply pump 42 adjusts the pressure by feedback control based on the detection result of at least one of the second pressure sensor 72 and the first pressure sensor 71. ..

As a result, it is possible to perform pressure control that is less likely to be affected by disturbance.

In addition, in the coating apparatus 100 of the present embodiment, in a part of the first supply path 51 (first main path 51a) through which the coating material flows when the first supply pump 41 performs the first discharge operation, as shown in FIG. When the first supply pump 41 performs the first pressure adjusting operation, the coating material flows in the reverse direction as shown in FIG. 9, for example. In a part of the second supply path 52 (second main path 52a) in which the coating material flows when the second supply pump 42 performs the second discharge operation, the second supply pump 42 adjusts the second pressure, as shown in FIG. When performing the operation, the coating material flows in the opposite direction as shown in FIG. 5, for example.

Thereby, the structure of the path through which the coating material flows can be simplified.

In addition, in the coating apparatus 100 of the present embodiment, the first supply pump 41 has the first cylinder 43 that can store the coating material. The second supply pump 42 has a second cylinder 45 capable of storing the coating material. The second supply pump 42 performs the second pressure adjustment operation so that the coating material from the first supply pump 41 is stored in the second cylinder 45 as shown in FIG. The suction operation is performed as shown in FIG. 6 so as to further store the coating material different from the coating material, and then the second discharging operation of FIG. 8 and the like is performed. The first supply pump 41 operates the first pressure adjusting operation so that the coating material from the second supply pump 42 is stored in the first cylinder 43 as shown in FIG. The suction operation is performed as shown in FIG. 2 so as to further store the coating material different from the coating material, and then the first discharging operation of FIG. 4 and the like is performed.

Thereby, the coating material stored in the first supply pump 41 or the second supply pump 42 as a result of the pressure adjustment can be sprayed from the coating main body 2. Therefore, the waste of the coating material can be reduced. Further, each of the first supply pump 41 and the second supply pump 42 discharges the coating material after sufficiently storing the coating material, so that it is possible to perform coating for a long time with one discharge operation, resulting in work efficiency. Can be increased.

In addition, the coating apparatus 100 of the present embodiment includes a first temperature adjusting unit 57 and a second temperature adjusting unit 58 that adjust the temperature of the coating material.

Thereby, the coating quality can be further improved by adjusting the viscosity of the coating material.

Further, in the coating apparatus 100 of the present embodiment, while the same work W is being coated, the state where the coating material is supplied to the coating main body 2 by the discharge pressure of the first supply pump 41 and the second supply. It is also possible to switch between the state in which the coating material is supplied to the coating main body 2 by the discharge pressure of the pump 42.

In this case, even if the first supply pump 41 and the second supply pump 42 having a small capacity of the storage portion (that is, the first cylinder 43 and the second cylinder 45) are adopted, the pumps for discharging are flexibly switched. However, a large work W can be coated or the work W can be thickly coated. Therefore, downsizing and cost reduction of the coating apparatus 100 can be realized.

In addition, in the coating apparatus 100 of the present embodiment, the coating main body 2 is moved by the coating robot 1 with respect to the work W.

This allows the work W having various shapes to be coated flexibly.

Next, a second embodiment will be described. FIG. 10: is a schematic diagram which shows the structure of the coating device 100x of 2nd Embodiment. In addition, in the description of the present embodiment, the same or similar members as those in the above-described embodiment may be denoted by the same reference numerals in the drawings, and description thereof may be omitted.

The coating apparatus 100x of the present embodiment includes a third supply system 33 separately from the first supply system 31 and the second supply system 32. Since the configuration of the third supply system 33 is the same as that of the first supply system 31 and the second supply system 32, the description thereof will be omitted. The common path 5 is commonly used in the three supply systems 30.

In this coating apparatus 100x, as shown in FIG. 10, while the first supply system 31 supplies the discharge pressure to the coating main body 2 and the second supply system 32 adjusts the pressure, the third supply system 33 can supply the coating material from the supply path 85. Next, the third supply system 33 supplies the discharge pressure to the coating main body 2, and the second supply system 32 supplies the coating material from the supply route 85 while the first supply system 31 adjusts the pressure. . Next, while the second supply system 32 supplies the discharge pressure to the coating main body 2 and the third supply system 33 adjusts the pressure, the first supply system 31 supplies the coating material from the first supply path 81. To replenish.

As described above, in the present embodiment, by cyclically switching the roles of the three supply systems 30, the time during which the coating work cannot be performed can be further shortened as compared with the first embodiment, and the efficiency can be improved. It can be further improved.

Although the preferred embodiment of the present invention has been described above, the above configuration can be modified as follows, for example.

The first supply pump 41 is not limited to a single cylinder pump, and may be composed of a plurality of cylinder pumps that are simultaneously driven by one drive unit. The same applies to the second supply pump 42.

The first supply pump 41 is not limited to the configuration in which the first piston 44 is mechanically driven by the first electric motor 91, and an air booster pump or the like can be used, for example. Similarly, for example, an air booster pump or the like can be used as the second supply pump 42.

The first supply pump 41 may be configured not to include a storage unit (specifically, the first cylinder 43) that stores the coating material. The same applies to the second supply pump 42.

The coating device 100x may include four or more supply systems.

The number of coating guns 20 (the number of discharge nozzles 21) may be 5 or more, or 3 or less.

The work W may be held by a robot, and the work W may be moved with respect to the coating main body 2 fixedly attached. Both the work W and the coating body 2 may be movable by a robot. At least one of the coating body 2 and the work W may be movable by a device other than a robot.

The open/close valve of the coating gun 20 may be omitted.

The first pressure adjustment operation of the first supply pump 41 may be performed based on the detection result of either the first pressure sensor 71 or the second pressure sensor 72, instead of the detection result. In the first pressure adjusting operation, feedforward control may be performed instead of or in addition to the feedback control. The same applies to the second pressure adjustment operation of the second supply pump 42.

The arrangement and configuration of the first temperature adjusting unit 57 and the second temperature adjusting unit 58 can be appropriately changed. The temperature adjustment can be realized, for example, by performing heat exchange between the coating material and the hot water/cold water in a heat exchanger, but is not limited thereto.

1 Painting robot (moving part, robot)
2 Paint body (spray part)
21 Discharge nozzle (jet port)
41 First Supply Pump (First Pump)
42 Second supply pump (second pump)
51 First supply route (coating material route)
52 Second supply route (coating material route)
53 First shutoff valve (switching part)
54 Second shutoff valve (switching part)
71 First Pressure Sensor (First Pressure Detector)
72 Second pressure sensor (second pressure detector)
100 coating equipment W work

Claims (9)

A first pump capable of discharging coating material,
A second pump that can discharge the coating material,
An injection part having a plurality of injection ports for injecting a coating material,
A moving unit capable of moving the injection unit relative to the work to be coated,
A switching unit for switching the supply/stop of supply of the coating material to each of the injection ports;
Equipped with
When the coating material is supplied to the spraying unit by the discharge pressure of the first pump and the second pump is not discharging the coating material, the switching unit may partially or entirely discharge the plurality of sprays. It is possible to stop the supply of coating material to the mouth,
When the coating material is supplied to the spraying unit by the discharge pressure of the second pump and the first pump is not discharging the coating material, the switching unit may partially or entirely discharge the plurality of sprays. A coating device capable of stopping the supply of coating material to the mouth. The coating apparatus according to claim 1,
When the coating material is supplied to the injection unit by the first pump, the first pump performs a first discharge operation of discharging the coating material at a constant flow rate,
When the first pump performs the first discharging operation, the second pump performs a second pressure adjusting operation for adjusting the pressure of the coating material path to which the coating material is supplied by the first discharging operation,
When the coating material is supplied to the injection unit by the second pump, the second pump performs a second discharging operation of discharging the coating material at a constant flow rate,
When the second pump performs the second discharging operation, the first pump performs a first pressure adjusting operation for adjusting the pressure of the coating material path to which the coating material is supplied by the second discharging operation. Characteristic coating equipment. The coating apparatus according to claim 2, wherein
A first pressure detection unit that detects the pressure of a coating material path through which the coating material is supplied to the injection unit by the first discharge operation of the first pump;
A second pressure detector that detects the pressure of the coating material path through which the coating material is supplied to the sprayer by the second discharge operation of the second pump;
Equipped with
When the first pump performs the first discharge operation and the second pump performs the second pressure adjusting operation during the coating on the work, the second pump detects the second pressure. Section and the first pressure detection unit, to suck the coating material from the coating material path so as to adjust the pressure based on the detection result of at least one,
When the second pump performs the second discharge operation and the first pump performs the first pressure adjusting operation during the coating of the work, the first pump detects the first pressure detection operation. Unit and the second pressure detecting unit, the coating apparatus sucks the coating material from the coating material path so as to adjust the pressure based on the detection result of at least one of the coating unit and the second pressure detecting unit. The coating apparatus according to claim 3,
When the first pump performs the first pressure adjustment operation, the first pump adjusts the pressure by feedback control based on the detection result of at least one of the first pressure detection unit and the second pressure detection unit. Then
When the second pump performs the second pressure adjustment operation, the second pump adjusts the pressure by feedback control based on the detection result of at least one of the second pressure detection unit and the first pressure detection unit. A coating device characterized by: The coating apparatus according to any one of claims 2 to 4,
In a part of the coating material path through which the coating material flows when the first pump performs the first discharging operation, the coating material flows in the opposite direction when the first pump performs the first pressure adjusting operation,
In a part of the coating material path through which the coating material flows when the second pump performs the second discharging operation, the coating material flows in the opposite direction when the second pump performs the second pressure adjusting operation. And coating equipment. The coating apparatus according to any one of claims 2 to 5,
The first pump has a first storage part capable of storing the coating material,
The second pump has a second storage part capable of storing the coating material,
The second pump applies a coating different from the coating material from the first pump to the second storage part in which the coating material from the first pump is stored by performing the second pressure adjusting operation. After performing the suction operation so as to further store the material, the second discharging operation is performed,
The first pump applies a coating different from the coating material from the second pump to the first storage part in which the coating material from the second pump is stored by performing the first pressure adjusting operation. A coating apparatus, wherein a suction operation is performed so as to further store the material, and then the first discharging operation is performed. The coating apparatus according to any one of claims 1 to 6,
A coating apparatus comprising a temperature adjusting section for adjusting the temperature of a coating material. The coating device according to any one of claims 1 to 7,
While the same work is being coated, a state in which the coating material is supplied to the injection unit by the discharge pressure of the first pump and a state in which the coating material is supplied to the injection unit by the discharge pressure of the second pump A coating device that can be switched between states. The coating apparatus according to any one of claims 1 to 8,
The coating device, wherein the moving unit is a robot.

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