AUTOMATIC WET SANDING APPARATUS

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to Japanese Patent Application No. 2020-037963 filed on Mar. 5, 2020, incorporated herein by reference in its entirety.

BACKGROUND
1. Technical Field

The present disclosure relates to an automatic wet sanding apparatus. In particular, the disclosure relates to measures for achieving high-accuracy automatic wet sanding while also enhancing the durability of an automatic wet sanding apparatus.

2. Description of Related Art

An automatic wet sanding apparatus has been hitherto known that performs automatic wet sanding on painted surfaces of vehicle bodies after completion of a painting process in an automobile production line, for example, as disclosed in Japanese Patent Application Publication No. 58-67377.

This automatic wet sanding apparatus includes an automatic wet sanding unit that is mounted on an automatic wet sanding robot (e.g., an articulated robot). The automatic wet sanding unit includes a sanding sliding body, such as a sanding brush or sandpaper. In an automatic wet sanding process, the sanding sliding body is pressed against a painted surface, and an automatic wet sanding robot is operated to move the sanding sliding body along the painted surface, with water flowing between the sanding sliding body and the painted surface, to sand down the painted surface.

SUMMARY

To give a quality finish to a painted surface by automatic wet sanding, it is necessary to adapt a sanding sliding body to the shape of the painted surface with high accuracy. Specifically, it is necessary to perform automatic wet sanding while changing the posture (direction) of the sanding sliding body according to changes in the curvature of the painted surface with high accuracy (e.g., changing the posture of the sanding sliding body so as to be orthogonal to a line normal to the painted surface), as well as maintaining the pressing force exerted by the sanding sliding body on the painted surface at an appropriate level. In particular, painted surfaces of vehicle bodies are often curved surfaces with non-constant curvature (formed by a collection of a plurality of curved surfaces), and a target value of a sanding depth by automatic wet sanding is a few micrometers. Thus, to give a quality finish to a painted surface, it is important to enhance the adaptability of the sanding sliding body to the shape of a painted surface.

As a configuration for adapting the sanding sliding body to the shape of a painted surface with high accuracy, it is conceivable to couple a piston rod of an air cylinder to the automatic wet sanding unit having the sanding sliding body mounted thereon, and by controlling this air cylinder, change the posture of the automatic wet sanding unit so as to adapt the sanding sliding body to the shape of the painted surface.

When thus using an air cylinder, one may conceive an idea of reducing the diameter of the piston rod to achieve higher adaptability. Specifically, reducing the diameter of the piston rod can increase the pressure of input air for control and enables high-accuracy pressure control. Further, as the area of contact between the piston rod and a part coming into sliding contact therewith (e.g., a seal packing) inside the air cylinder is reduced, the sliding resistance can be reduced. In addition, as the internal volume of the cylinder is reduced, the response speed in adaptation can be increased. Thus, higher adaptability of the sanding sliding body can be achieved.

On the other hand, reducing the diameter of the piston rod may cause a decrease in mechanical strength. A conceivable countermeasure is to provide a guide rod that is parallel to the piston rod. This guide rod is slidably inserted into a bush that is provided inside the air cylinder, and a leading end of the guide rod is coupled to the automatic wet sanding unit. As shown in FIG. 15 (a view of a support structure for a guide rod a of an air cylinder as seen in a cross-section in a direction orthogonal to an extension direction of the guide rod a), a plurality of balls c is interposed between an outer circumferential surface of the guide rod a and an inner circumferential surface of a bush b to allow the guide rod a to slide (move forward and backward) smoothly along the bush b.

However, when the guide rod a is simply formed in a columnar shape, each of the balls c comes into point-contact with the outer circumferential surface of the guide rod a, so that locally high stress acts on the guide rod a. In particular, locally high stress may act on the guide rod a, and cause damage thereto, as a result of vibration. Thus, it has been difficult to make two objects compatible with each other: to achieve high-accuracy automatic wet sanding by enhancing the adaptability of the sanding sliding body to the shape of a painted surface through a reduction of the diameter of the piston rod; and to enhance the durability of the automatic wet sanding apparatus.

The present disclosure has been contrived in view of this issue, and an object thereof is to provide an automatic wet sanding apparatus that is capable of high-accuracy automatic wet sanding while also having high durability.

A solution adopted by the present disclosure to achieve the above object is premised on an automatic wet sanding apparatus that performs automatic wet sanding in which a sanding sliding body is pressed against a painted surface of a painted object that has been painted and the sanding sliding body is moved with water flowing between the sanding sliding body and the painted surface to sand down the painted surface. This automatic wet sanding apparatus includes an automatic wet sanding unit main body on which the sanding sliding body is mounted, and a unit support mechanism that supports the automatic wet sanding unit main body and includes an air cylinder that changes the posture of the automatic wet sanding unit main body. This automatic wet sanding apparatus further includes a guide rod that is slidably supported by a bush provided inside the air cylinder, extends toward the automatic wet sanding unit main body, and is coupled to the automatic wet sanding unit main body. An outer surface of the guide rod has grooves that extend along a shaft centerline of the guide rod and have an arc-shaped cross-section in a direction orthogonal to the shaft centerline, and balls that allow the guide rod to slide along the bush are interposed between a bottom of each of the grooves and an inner surface of the bush.

According to these specifications, automatic wet sanding of sanding down a painted surface of a painted object is performed by pressing the sanding sliding body against the painted surface and moving the sanding sliding body with water flowing between the sanding sliding body and the painted surface to sand down the painted surface. To adapt the sanding sliding body to the shape of the painted surface, the posture of the automatic wet sanding unit main body is changed by controlling the air cylinder that supports the automatic wet sanding unit main body. In the present disclosure, the air cylinder is provided with the guide rod. The presence of this guide rod makes it possible to reduce the diameter of the piston rod of the air cylinder without causing a decrease in the mechanical strength of the unit support mechanism. Further, the balls are interposed between the bottom of each groove (having an arc-shaped cross-section) formed in the outer surface of the guide rod and the inner surface of the bush to allow the guide rod to slide along the bush. Therefore, the balls can be brought into line-contact with the guide rod (the grooves of the guide rod), which can mitigate stress due to vibration. Thus, the present disclosure can make two objects compatible with each other: to achieve high-accuracy automatic wet sanding by enhancing the adaptability of the sanding sliding body to the shape of a painted surface through a reduction of the diameter of the piston rod; and to enhance the durability of the automatic wet sanding apparatus.

The guide rod may be provided on each side of a piston rod of the air cylinder in a direction orthogonal to an extension direction of the piston rod.

This configuration can give sufficient mechanical strength to the unit support mechanism that supports the automatic wet sanding unit main body, making it easy to reduce the diameter of the piston rod of the air cylinder.

A leading end of the guide rod may be coupled to a rod end mechanism that turnably supports the automatic wet sanding unit main body. The rod end mechanism may include a rod end to which the leading end of the guide rod is coupled and a bolt that is inserted into a center hole of the rod end and an opening formed in the automatic wet sanding unit main body, and may be configured such that the automatic wet sanding unit main body is supported so as to be able to rotate along with the bolt relatively to the rod end. An outer circumferential surface of the bolt may have, at least at a position corresponding to the center hole of the rod end, a recess that extends along a shaft centerline of the bolt.

In this configuration, the recess is formed in the outer circumferential surface of the bolt, which can reduce the area of contact between the center hole of the rod end and the outer circumferential surface of the bolt and thereby reduce the sliding resistance during turning of the automatic wet sanding unit main body. Thus, during automatic wet sanding, the posture of the automatic wet sanding unit can be quickly changed according to changes in the curvature of a painted surface so as to adapt the sanding sliding body to the shape of the painted surface.

In the present disclosure, the air cylinder that changes the posture of the automatic wet sanding unit main body having the sanding sliding body mounted thereon is provided with the guide rod. The outer surface of the guide rod has the grooves that extend along the shaft centerline of the guide rod and have an arc-shaped cross-section in a direction orthogonal to the shaft centerline, and the balls are interposed between the bottom of each groove and the inner surface of the bush provided inside the air cylinder. Thus, it is possible to make two objects compatible with each other: to achieve high-accuracy automatic wet sanding by enhancing the adaptability of the sanding sliding body to the shape of a painted surface through a reduction of the diameter of the piston rod; and to enhance the durability of the automatic wet sanding apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS

Features, advantages, and technical and industrial significance of exemplary embodiments of the disclosure will be described below with reference to the accompanying drawings, in which like numerals denote like elements, and wherein:

FIG. 1 is a schematic configuration view of an automatic wet sanding station in an embodiment;

FIG. 2 is a schematic configuration view showing a first automatic wet sanding apparatus;

FIG. 3 is a view showing an automatic wet sanding robot;

FIG. 4A is a vertical sectional view of an automatic wet sanding unit;

FIG. 4B is a schematic view showing a disc main body;

FIG. 5 is a perspective view showing part of a guide rod of an air cylinder;

FIG. 6 is a sectional view showing a support structure for the guide rod inside the air cylinder;

FIG. 7 is a sectional view showing a structure for supporting a unit main body by a rod end mechanism;

FIG. 8 is a schematic configuration view of a pad cleaning unit;

FIG. 9 is a schematic configuration view of a pad draining unit;

FIG. 10 is a schematic configuration view of a paper checking unit;

FIG. 11 is a block diagram illustrating a control system of the automatic wet sanding apparatus;

FIG. 12 is a flowchart illustrating an automatic wet sanding operation by the automatic wet sanding apparatus;

FIG. 13 is a sectional view illustrating flows of water in the automatic wet sanding unit in a state of performing automatic wet sanding;

FIG. 14 is a side view of a vehicle body illustrating moving paths of the automatic wet sanding unit in the automatic wet sanding operation; and

FIG. 15 is a sectional view showing a conventional support structure for a guide rod of an air cylinder.

DETAILED DESCRIPTION OF EMBODIMENTS

An embodiment of the present disclosure will be described below based on the drawings. In this embodiment, a case will be described where the disclosure is applied to an automatic wet sanding apparatus that is provided on an automobile production line and performs automatic wet sanding on painted surfaces of vehicle bodies.

Schematic Configuration of Automatic Wet Sanding Station

First, a schematic configuration of an automatic wet sanding station on an automobile production line in which automatic wet sanding apparatuses are installed will be described. FIG. 1 is a schematic configuration view of an automatic wet sanding station 1 in this embodiment. The automatic wet sanding station 1 is installed on the automobile production line, on a downstream side of a painting station (not shown).

As shown in FIG. 1, the automatic wet sanding station 1 has a configuration in which four automatic wet sanding apparatuses 21, 22, 23, 24 are installed two on each side of a conveyor 11 that transfers vehicle bodies V.

When the vehicle body V is transferred as indicated by arrow A in FIG. 1 (when the vehicle body V is transferred on the conveyor 11 from the left side toward the right side in FIG. 1), the automatic wet sanding apparatuses 21, 22 located on a downstream side in the transfer direction perform automatic wet sanding on painted surfaces of front doors LFD, RFD and front fenders LFF, RFF of the vehicle body V. Specifically, the automatic wet sanding apparatus 21 (hereinafter referred to as a first automatic wet sanding apparatus 21) located on the left side as seen from the transfer direction (the upper side in FIG. 1) performs automatic wet sanding on the painted surfaces of the left front door LFD and the left front fender LFF of the vehicle body V. The automatic wet sanding apparatus 22 (hereinafter referred to as a second automatic wet sanding apparatus 22) located on the right side as seen from the transfer direction (the lower side in FIG. 1) performs automatic wet sanding on the painted surfaces of the right front door RFD and the right front fender RFF of the vehicle body V.

Meanwhile, the automatic wet sanding apparatuses 23, 24 located on an upstream side in the transfer direction perform automatic wet sanding on painted surfaces of rear doors LRD, RRD and rear fenders LRF, RRF of the vehicle body V. Specifically, the automatic wet sanding apparatus 23 (hereinafter referred to as a third automatic wet sanding apparatus 23) located on the left side as seen from the transfer direction performs automatic wet sanding on the painted surfaces of the left rear door LRD and the left rear fender LRF of the vehicle body V. The automatic wet sanding apparatus 24 (hereinafter referred to as a fourth automatic wet sanding apparatus 24) located on the right side as seen from the transfer direction performs automatic wet sanding on the painted surfaces of the right rear door RRD and the right rear fender RRF of the vehicle body V.

As the automatic wet sanding apparatuses 21 to 24 have the same configuration, the first automatic wet sanding apparatus 21 will be described here as a representative. In FIG. 1, those of the devices and members composing the automatic wet sanding apparatuses 21 to 24 that are the same are denoted by the same reference signs.

FIG. 2 is a schematic configuration view showing the first automatic wet sanding apparatus 21. As shown in FIG. 2, the first automatic wet sanding apparatus 21 includes an automatic wet sanding robot 3 and a changer 4. The automatic wet sanding robot 3 is formed by an articulated robot, and an automatic wet sanding unit 5 to be described later is mounted on the automatic wet sanding robot 3. Automatic wet sanding is performed on the painted surfaces of the vehicle body V (in the case of the first automatic wet sanding apparatus 21, the painted surfaces of the left front door LFD and the left front fender LFF) by the automatic wet sanding unit 5. The changer 4 replaces sandpaper (the “sanding sliding body” as termed in the present disclosure) that is mounted on the automatic wet sanding unit 5. In the following, the automatic wet sanding robot 3, the automatic wet sanding unit 5, and the changer 4 will be specifically described.

Automatic Wet Sanding Robot

As shown in FIG. 3, the automatic wet sanding robot 3 is formed by an articulated robot. Specifically, the automatic wet sanding robot 3 in this embodiment includes a swivel base 30, and first to fifth arms 31, 32, 33, 34, 35 that are coupled to one another by joints or the like.

A rotating mechanism (including a motor) that can rotate around a vertical axis is housed inside the swivel base 30. A rotating mechanism that can rotate around a horizontal axis is housed at each joint. The swivel base 30 and the first arm 31, the first arm 31 and the second arm 32, and the third arm 33 and the fourth arm 34 are coupled to each other by a joint having a rotating mechanism that arrows the arms 31, 32, 33, 34 to turn relatively. The second arm 32 and the third arm 33, and the fourth arm 34 and the fifth arm 35 are coupled to each other by a rotating mechanism that can rotate relatively around an axis along an extension direction of the arm. Rotational motion of these rotating mechanisms causes the swivel base 30 to rotate or the arms 31 to 35 to swing or rotate, which can in turn move the automatic wet sanding unit 5 to an arbitrary position or change the posture thereof to an arbitrary posture. Rotational motion of each rotating mechanism is performed based on a command signal from a robot controller 83 (see FIG. 11) to be described later.

The automatic wet sanding unit 5 is mounted at a leading end of the fifth arm 35. Specifically, the automatic wet sanding unit 5 is mounted on a frame 36 that is mounted at the leading end of the fifth arm 35.

The configuration of the automatic wet sanding robot 3 is not limited to the above-described one.

Automatic Wet Sanding Unit

Next, the automatic wet sanding unit 5 will be described. FIG. 4A is a vertical sectional view of the automatic wet sanding unit 5. FIG. 4B is a schematic view showing a disc main body 54a to be described later (a schematic view of the disc main body 54a as seen from a direction along a central axis thereof). The vertical sectional view of FIG. 4A shows a section located at a position corresponding to line IV-IV in FIG. 4B.

The posture of the automatic wet sanding unit 5 (the automatic wet sanding unit 5 in the first automatic wet sanding apparatus 21) shown in FIG. 4A is a posture in which the sandpaper 56 mounted on the automatic wet sanding unit 5 faces downward. When automatic wet sanding is being performed, the automatic wet sanding unit 5 is in a posture in which the sandpaper 56 faces the painted surface (the surface extending in a substantially vertical direction) of the left front door LFD or the left front fender LFF of the vehicle body V as shown in FIG. 3, i.e., a posture to which the automatic wet sanding unit 5 turns about 90° from the posture shown in FIG. 4A so as to face the vehicle body V. Therefore, when automatic wet sanding is being performed, a downward direction in FIG. 4A is a direction facing the vehicle body and an upward direction in FIG. 4A is a direction facing the opposite side from the vehicle body. In the following description of the automatic wet sanding unit 5 using FIG. 4A and 4B, a state where the automatic wet sanding unit 5 is in the posture shown in FIG. 4A (the posture in which the sandpaper 56 faces downward) will be taken as an example.

As shown in FIG. 4A, the automatic wet sanding unit 5 includes a unit main body (automatic wet sanding unit main body) 5A and a unit support mechanism 5B that is mounted on the frame 36. Thus, the unit main body 5A is supported by the automatic wet sanding robot 3 through the unit support mechanism 5B and the frame 36 (more specifically, supported at the leading end of the fifth arm 35 of the automatic wet sanding robot 3 through the unit support mechanism 5B and the frame 36).

Unit Main Body

The unit main body 5A includes an air motor 50, a skirt 51, a water supply pipe 52, an eccentric head 53, a disc 54, a cushion pad 55, sandpaper (the “sanding sliding body” as termed in the present disclosure) 56, a hood 57, a water deflecting member 58, and a seal member 59.

Air Motor

The air motor 50 includes a driving shaft 50a that extends downward in the posture shown in FIG. 4A. An air supply pipe (not shown) is connected to the air motor 50, and the driving shaft 50a is rotated by the pressure of air supplied through the air supply pipe as an air pump (not shown) is activated. Long dashed short dashed line O1 in FIG. 4A and 4B indicates the center of rotation of the driving shaft 50a.

Skirt

The skirt 51 is integrally mounted on a casing 50b of the air motor 50, and an inside of the skirt 51 forms an introduction space 51a into which water for automatic wet sanding is introduced. Specifically, the skirt 51 includes a cylindrical mounting part 51b, a skirt main part 51c of which the diameter increases from a lower end edge of the mounting part 51b toward a lower side, and a hood mounting part 51d that extends cylindrically from a lower end edge of the skirt main part 51c toward the lower side.

The inside diameter of the mounting part 51b is substantially equal to the outside diameter of the casing 50b of the air motor 50. An inner circumferential surface of the mounting part 51b is joined to an outer circumferential surface of the casing 50b of the air motor 50. Thus, the skirt 51 is supported by the air motor 50. Since the diameter of the skirt main part 51c increases toward the lower side as mentioned above, the inside diameter of the introduction space 51a inside the skirt main part 51c also increases toward the lower side. The hood mounting part 51d has an annular engaging groove 51e that is depressed toward an upper side by a predetermined dimension from a lower end surface of the hood mounting part 51d. The engaging groove 51e is used to fix the hood 57 and the seal member 59 to be described later.

Water Supply Pipe

The water supply pipe 52 supplies water for automatic wet sanding into the introduction space 51a of the skirt 51. The water supply pipe 52 is connected at an upstream end to a water pump 52a (see FIG. 11) and at a downstream end to the skirt main part 51c of the skirt 51, and supplies water for automatic wet sanding into the introduction space 51a of the skirt 51 as the water pump 52a is activated.

Eccentric Head

The eccentric head 53 is integrated with the driving shaft 50a of the air motor 50, and is formed so as to have its center offset from the center of rotation O1 of the driving shaft 50a. FIG. 4A and 4B shows a state where the center of the eccentric head 53 is offset toward the left side in FIG. 4A and 4B. As indicated by the imaginary line in FIG. 4B, the eccentric head 53 is formed by a substantially elliptical disc, and a position in the eccentric head 53 that is located off the center position of the ellipse (in FIG. 4B, an off-center position on the right side) is located on the center of rotation O1 of the driving shaft 50a. Therefore, when the driving shaft 50a rotates (around the center of rotation O1) as the air motor 50 is activated, the eccentric head 53 rotates eccentrically around the center of rotation O1. Imaginary line B in FIG. 4B indicates a trajectory of movement of an outer end of the eccentric head 53 (a position at an outer edge thereof on the offset side; point C in FIG. 4B) when the eccentric head 53 rotates eccentrically. As this imaginary line B shows, the outer end (the position at the outer edge on the offset side) of the eccentric head 53 is located on an inner circumferential side relative to outer circumferential ends of disc holes 54e to be described later.

Disc

The disc 54 is composed of a disc main body 54a and a disc cover 54b that are integrally combined.

The disc main body 54a is formed by a metal disc that has a larger diameter than the hood mounting part 51d of the skirt 51. An outer circumferential surface 54c of the disc main body 54a is formed by a sloping surface of which the diameter increases downward.

As shown in FIG. 4B, the disc main body 54a has a disc center hole 54d, the disc holes 54e, and communication passages 54f.

The disc center hole 54d is formed by a circular opening that is bored at a central portion of the disc main body 54a. The disc center hole 54d extends from an upper surface to a lower surface of the disc main body 54a.

The disc holes 54e are formed at three positions on an outer circumferential side, each at a predetermined distance from the center of the disc main body 54a. The disc holes 54e also extend from the upper surface to the lower surface of the disc main body 54a. The disc holes 54e are disposed at positions at regular angular intervals in a circumferential direction (positions at 120° angular intervals).

The communication passages 54f allow communication between the disc center hole 54d and the disc holes 54e. Specifically, the communication passages 54f extend radially from the center of the disc main body 54a and each communicate at an inner end with the disc center hole 54d and at an outer end with the disc hole 54e. The communication passages 54f also extend from the upper surface to the lower surface of the disc main body 54a.

The disc cover 54b is formed by a metal disc that has an outside diameter substantially equal to the outside diameter of the upper surface of the disc main body 54a. The disc cover 54b has a bearing part 54g which is a part provided at a central portion and at which the plate thickness of the disc cover 54b is increased. The bearing part 54g and the eccentric head 53 are connected to each other by a bearing 53a. Thus, the disc cover 54b is rotatably supported by the eccentric head 53. The disc cover 54b is rotatably supported by the eccentric head 53, for example, as an inner race of the bearing 53a is coupled to the eccentric head 53 while an outer race of the bearing 53a is coupled to the bearing part 54g of the disc cover 54b.

Further, the disc cover 54b has openings 54h at positions corresponding to the disc holes 54e of the disc main body 54a. The inside diameter of the opening 54h is substantially equal to the inside diameter of the disc hole 54e. With the positions of the openings 54h coinciding with the positions of the disc holes 54e, the disc cover 54b is joined to the upper surface of the disc main body 54a by means such as screw fastening or welding. This means that the disc center hole 54d and the communication passages 54f are closed at an upper side by the disc cover 54b. Thus, in the disc 54, a water channel 54i is formed that continues through the openings 54h of the disc cover 54b and the disc holes 54e, the communication passages 54f, and the disc center hole 54d of the disc main body 54a. Since the disc cover 54b is joined to the upper surface of the disc main body 54a as mentioned above, the entire disc 54 is rotatably supported by the eccentric head 53 through the bearing 53a.

The center position of the disc main body 54a, the center position of the disc cover 54b, the center position of the disc center hole 54d, and the center of rotation of the bearing 53a are located on the same axis (see O2 in FIG. 4A and 4B). In FIG. 4B, the positions of the disc 54 when the disc 54 rotates around the center position O2 by 90° at a time are indicated by the solid line, the dashed line, the long dashed short dashed line, and the long dashed double-short dashed line, respectively. The dimension of offset of the center position O2 of the disc center hole 54d (the center position of the disc 54) relative to the center of rotation O1 of the driving shaft 50a of the air motor 50 is set to be smaller than half the inside diameter of the disc center hole 54d.

Cushion Pad

The cushion pad 55 is integrally mounted on the lower surface of the disc 54. The cushion pad 55 is formed by a cushion member made of sponge or the like and has a form of a disc of which the outside diameter is substantially equal to the outside diameter of the disc main body 54a. An outer circumferential surface 55a of the cushion pad 55 is formed by a sloping surface of which the diameter decreases toward the lower side.

As shown in FIG. 4A, the cushion pad 55 has, at a central portion thereof, a pad center hole 55b that is formed by a circular opening. The pad center hole 55b extends from an upper surface to a lower surface of the cushion pad 55. The center position of the pad center hole 55b coincides with the center position of the disc center hole 54d. Thus, the pad center hole 55b communicates with the water channel 54i formed in the disc 54. The inside diameter of the pad center hole 55b is slightly larger than the inside diameter of the disc center hole 54d.

Sandpaper

The sandpaper 56 is detachably mounted on the lower surface of the cushion pad 55. Specifically, a lower surface 56a (a surface that faces the vehicle body V during automatic wet sanding) of the sandpaper 56 is a sanding surface. For example, this sanding surface is composed of resin. On the other hand, an upper surface 56b (a surface mounted to the lower surface of the cushion pad 55) is mounted to the lower surface of the cushion pad 55 by a touch-and-close fastener, such as Magictape®.

The sandpaper 56 has, at a central portion thereof, a paper center hole 56c that is formed by a circular opening. In a state where the sandpaper 56 is mounted at a correct position on the lower surface of the cushion pad 55, the center position of the paper center hole 56c coincides with the center position of the pad center hole 55b. The inside diameter of the paper center hole 56c may be set to be equal to the inside diameter of the pad center hole 55b or slightly larger than the inside diameter of the pad center hole 55b.

Hood

The hood 57 is a member that is mounted at a lower end of the skirt 51 and prevents scattering of water that is released toward an outer periphery of the disc 54 after being introduced into the introduction space 51a of the skirt 51. (This release of water will be described later.) Specifically, the hood 57 includes a cylindrical mounting part 57a, a hood main part 57b of which the diameter increases from a lower end edge of the mounting part 57a toward the lower side, and a water deflecting part 57c that extends obliquely downward from a lower end edge of the hood main part 57b.

The diameter of the mounting part 57a is substantially equal to the diameter of the engaging groove 51e formed in the skirt 51. As the mounting part 57a is inserted into the engaging groove 51e, the hood 57 is supported by the skirt 51.

The outside diameter of the hood main part 57b is set to be slightly larger than the outside diameter of the disc 54.

The water deflecting part 57c is formed by a part that is slightly bent downward from an outer circumferential end of the hood main part 57b.

Water Deflecting Member

The water deflecting member 58 is mounted on the water deflecting part 57c of the hood 57 and formed by an annular rubber member that slopes toward an inner circumferential side (such that the diameter decreases) while extending downward from a lower end edge of the water deflecting part 57c. The water deflecting member 58 is mounted to the water deflecting part 57c by means such as bonding or screw fastening.

Seal Member

Like the hood 57, the seal member 59 is mounted at a lower end of the skirt 51. Specifically, the seal member 59 is formed by a flat cylindrical member made of urethane. The diameter of the seal member 59 is substantially equal to the diameter of the engaging groove 51e formed in the skirt 51. The seal member 59 is supported by the skirt 51 as an upper end portion of the seal member 59 is inserted into the engaging groove 51e while being overlapped with the mounting part 57a of the hood 57.

The height of the seal member 59 is substantially equal to the dimension of a clearance between a ceiling part inside the engaging groove 51e and the upper surface of the disc 54. Therefore, when no external pressure (e.g., water pressure) is acting on the seal member 59, a lower end of the seal member 59 is in contact with the upper surface of the disc 54 along an entire circumference of the seal member 59 (without clearance) as shown in FIG. 4A. Thus, the introduction space 51a of the skirt 51 can be turned into a substantially sealed space. When a water pressure acts on an inner side of the seal member 59 and this water pressure exceeds a predetermined value, the seal member 59 deforms elastically and a small clearance is formed between the lower end of the seal member 59 and the upper surface of the disc 54, and water flows through this clearance.

Unit Support Mechanism

Next, the unit support mechanism 5B will be described. As mentioned above, the unit support mechanism 5B is a mechanism that supports the unit main body 5A onto the automatic wet sanding robot 3 through the frame 36.

As shown in FIG. 3 and FIG. 4A and 4B, the unit support mechanism 5B includes a pair of air cylinders 60. As shown in FIG. 3, the air cylinders 60 are respectively mounted on both side surfaces (an upper surface and a lower surface in FIG. 3) of the frame 36. From the air cylinders 60, one piston rod 61A and two guide rods 61B (see FIG. 2) protrude so as to be able to move forward and backward. Specifically, the guide rods 61B are provided one on each side of the piston rod 61A (each side in a direction orthogonal to an extension direction of the piston rod 61A). The configuration of the guide rods 61B and a support structure therefor will be described later.

The automatic wet sanding unit 5 includes a unit case 5C (see the imaginary line in FIG. 4A) that covers an outer side of the air motor 50 and the skirt 51. As shown in FIG. 4A, lower ends of the piston rod 61A and the guide rods 61B are connected to support blocks 62. One coupling rod 63 extends from a lower surface of each support block 62. A rod end mechanism 5D is provided at a lower end of the coupling rod 63, and the unit main body 5A is supported by the rod end mechanism 5D so as to be able to turn around a horizontal axis. The specific configuration of the rod end mechanism 5D will also be described later.

Configuration of Guide Rod and Support Structure Therefor

Next, the configuration of the guide rods 61B and the support structure therefor that are the feature of this embodiment will be described.

FIG. 5 is a perspective view showing part of the guide rod 61B of the air cylinder 60. FIG. 6 is a sectional view showing the support structure for the guide rod 61B inside the air cylinder 60 (a view of a cross-section in a direction orthogonal to an extension direction of the guide rod 61B).

As shown in FIG. 6, the guide rod 61B is slidably supported by a bush 60a that is provided inside the air cylinder 60. The bush 60a is a cylindrical member and fixed inside the air cylinder 60. The inside diameter of the bush 60a is set to be slightly larger than the outside diameter of the guide rod 61B. An inner surface of the bush 60a has grooves 60b that extend along a shaft centerline of the bush 60a and have an arc-shaped cross-section. The grooves 60b are formed at four positions in a circumferential direction of the bush 60a. For example, the grooves 60b are formed at positions spaced apart at 90° intervals in the circumferential direction.

An outer surface (outer circumferential surface) of the guide rod 61B has grooves 61a that extend along a shaft centerline of the guide rod 61B and have an arc-shaped cross-section in a direction orthogonal to the shaft centerline. The grooves 61a are formed at four positions in a circumferential direction of the guide rod 61B. For example, the grooves 61a are formed at positions spaced apart at 90° intervals in the circumferential direction.

The guide rod 61B is inserted into the bush 60a such that the grooves 60b formed in the inner surface of the bush 60a and the grooves 61a formed in the outer surface of the guide rod 61B face each other, and spherical metal balls 61b are interposed between the grooves 60b, 61a. While this is not shown, a plurality of balls 61b is arrayed in each pair of grooves 60b, 61a along an extension direction thereof. A bottom plate of the air cylinder 60 has an opening (not shown) of a shape corresponding to the outer shape of the guide rod 61B, so that the balls 61b do not fall from the air cylinder 60 while the guide rod 61B is allowed to slide.

In the above configuration, the guide rod 61B is supported by the bush 60a so as to be able to slide along the extension direction of the guide rod 61B. The radii of curvature of the grooves 60b, 61a and the radius of the balls 61b are substantially equal. In this configuration, therefore, an outer surface of each ball 61b is in line-contact with each of the groove 60b of the bush 60a and the groove 61a of the guide rod 61B.

Configuration of Rod End Mechanism

Next, the configuration of the rod end mechanism 5D will be described.

FIG. 7 is a sectional view taken along line VII-VII in FIG. 4A, showing the structure for supporting the unit main body 5A by the rod end mechanism 5D. As shown in FIG. 4A, 4B and FIG. 7, the rod end mechanism 5D includes a rod end 64, a bearing member 67, and a bearing bolt 66.

The rod end 64 has a cylindrical shape, and the coupling rod 63 is coupled to an upper part of the rod end 64. The rod end 64 has, at a central portion thereof, a bolt insertion hole 64a that extends through the rod end 64 in a horizontal direction. The bearing member (so-called bearing metal) 67 is provided along an inner surface of the bolt insertion hole 64a. The outside diameter of the bearing member 67 is substantially equal to the inside diameter of the bolt insertion hole 64a, and the inside diameter of the bearing member 67 is substantially equal to the outside diameter of a threaded part 66a of the bearing bolt 66.

A fastening nut 65 is mounted on an outer surface of the unit case 5C, at a position at which the fastening nut 65 faces the rod end 64 (see FIG. 4A and 4B). The bearing bolt 66 is screwed from outside into the bearing member 67 and a screw hole 65a of the fastening nut 65, and the unit case SC is thereby turnably supported by the rod end 64. Thus, during automatic wet sanding, turning the unit case 5C relatively to the rod ends 64 can turn the entire automatic wet sanding unit 5 and thereby deflect the directions of the disc 54 and the cushion pad 55 to directions along the painted surface of the vehicle body V. As a result, a large area of the sanding surface (lower surface) 56a of the sandpaper 56 can be brought into contact with the painted surface of the vehicle body V. While the entire automatic wet sanding unit 5 is thus turned, an inner surface of the bearing member 67 and an outer surface of the threaded part 66a of the bearing bolt 66 turn relatively to each other.

The rod end mechanism 5D features recesses 66b that are formed in an outer circumferential surface of the threaded part 66a of the bearing bolt 66 so as to extend along a shaft centerline of the bearing bolt 66. As shown in FIG. 7, in the outer circumferential surface of the threaded part 66a of the bearing bolt 66, the recesses 66b extend along the shaft centerline of the bearing bolt 66 and have an arc-shaped cross-section in a direction orthogonal to the shaft centerline. The recesses 66b are formed at eight positions in a circumferential direction of the threaded part 66a of the bearing bolt 66. For example, the recesses 66b are formed at positions spaced apart at 45° intervals in the circumferential direction. When the recesses 66b are formed, the area of contact between the outer circumferential surface of the threaded part 66a of the bearing bolt 66 and the inner circumferential surface of the bearing member 67 becomes smaller than when these recesses are not formed.

Changer

Next, the changer 4 will be described. As shown in FIG. 2, the changer 4 includes a paper peeling unit 41, a pad cleaning unit 42, a pad draining unit 43, a paper mounting unit 44, and a paper checking unit 45.

Paper Peeling Unit

The paper peeling unit 41 peels (removes) the sandpaper 56 of the automatic wet sanding unit 5 from the cushion pad 55 upon completion of automatic wet sanding. If automatic wet sanding is performed on a plurality of vehicle bodies V using the same sandpaper 56 (without replacing the sandpaper 56), the sanding efficiency may decrease or paint of the vehicle body V that has previously undergone automatic wet sanding may transfer onto the subsequent vehicle body V. To avoid such a situation, the sandpaper 56 is replaced each time automatic wet sanding on one vehicle body V is completed. The paper peeling unit 41 performs a step of peeling the sandpaper 56 from the cushion pad 55 to replace the sandpaper 56.

The paper peeling unit 41 includes a clamping shaft 41a and a clamping hook 41b. The clamping shaft 41a is formed by a metal shaft that is supported by a frame 41c so as to be able to rotate around a horizontal axis. The clamping shaft 41a is coupled to a clamping shaft motor 41d and configured to be able to rotate as the clamping shaft motor 41d is activated. The clamping hook 41b is provided above and close to the clamping shaft 41a. Thus, the clamping hook 41b can catch the sandpaper 56 between the clamping hook 41b and the clamping shaft 41a.

A sandpaper collection box 41e is installed under the clamping shaft 41a, and the sandpaper 56 peeled from the cushion pad 55 drops into the sandpaper collection box 41e to be collected.

Pad Cleaning Unit

The pad cleaning unit 42 cleans the cushion pad 55 from which the sandpaper 56 has been peeled by the paper peeling unit 41. After automatic wet sanding, paint (paint separated from the vehicle body V by sanding; sanding dust) adheres to the sandpaper 56 and the cushion pad 55. Therefore, even when the sandpaper 56 is replaced, if automatic wet sanding is performed on the subsequent vehicle body V without cleaning the cushion pad 55, the paint may transfer onto the vehicle body V. The pad cleaning unit 42 is installed to avoid such a situation.

As shown in FIG. 8, the pad cleaning unit 42 includes a cleaning tank 42a, a water supply pipe 42b, and a circulating circuit 42c. The cleaning tank 42a has an inside diameter that is larger than the outside diameter of the automatic wet sanding unit 5. A metal mesh 42d extending in a horizontal direction is provided inside the cleaning tank 42a, at an intermediate point in a vertical direction (depth direction).

The water supply pipe 42b is connected at an upstream end to a water supply pump 42j (see FIG. 11) and at a downstream end to the cleaning tank 42a, and supplies cleaning water (pure water) to the cleaning tank 42a as the water supply pump 42j is activated. A valve 42e for regulating water supply is provided on the water supply pipe 42b.

The circulating circuit 42c has a configuration in which a circulating pump 42g and a filter 42h are provided on the route of a circulating pipe 42f The circulating pipe 42f is connected at one end (upstream end) to a bottom of the cleaning tank 42a and at the other end (downstream end) to a side surface of the cleaning tank 42a. During cleaning of a pad, water circulating action is performed in which the circulating pump 42g is activated to extract water from the bottom of the cleaning tank 42a and this water is purified by the filter 42h and then returned to the cleaning tank 42a through the side surface. A drain valve 42i is connected to the filter 42h. The drain valve 42i is opened to discharge water from the cleaning tank 42a.

Pad Draining Unit

The pad draining unit 43 drains the cushion pad 55 that has been cleaned by the pad cleaning unit 42.

As shown in FIG. 9, the pad draining unit 43 includes a draining table 43a and an air blow nozzle 43b. The draining table 43a is composed of a rack frame 43c and a mesh-like inclined plate 43d mounted thereon. To drain the cushion pad 55, the automatic wet sanding robot 3 is operated to press the cushion pad 55 against the inclined plate 43d of the draining table 43a, and water is thereby squeezed out from the cushion pad 55. During draining, air is blown from the air blow nozzle 43b toward the cushion pad 55 to increase the draining efficiency. An air blow motor 43e (see FIG. 11) is connected to the air blow nozzle 43b.

The cushion pad 55 may be pressed against the inclined plate 43d of the draining table 43a such that the entire cushion pad 55 is evenly pressed against the inclined plate 43d. However, it is preferable that the position at which the cushion pad 55 is pressed against the inclined plate 43d be changed in a circumferential direction of the cushion pad 55, as it can further increase the draining efficiency. Specifically, the position at which the cushion pad 55 is pressed against the inclined plate 43d is changed in the circumferential direction by moving the center line O2 (center positions) of the disc 54 and the cushion pad 55 as indicated by the arrows in FIG. 9.

Paper Mounting Unit

The paper mounting unit 44 mounts new sandpaper 56 onto the cushion pad 55 that has been drained by the pad draining unit 43.

As shown in FIG. 2, the paper mounting unit 44 includes a paper stand 44a and a paper pressing plate 44b. A plurality of sheets of unused sandpaper 56 is placed on top of one another on the paper stand 44a. Each sheet of sandpaper 56 is placed on the paper stand 44a in such a manner that the surface having a touch-and-close fastener to be mounted to the cushion pad 55 faces upward.

An air cylinder 44c is connected to the paper pressing plate 44b. The air cylinder 44c is activated to move the paper pressing plate 44b between a position at which the paper pressing plate 44b presses the upper side of the sandpaper 56 and a position at which the paper pressing plate 44b has receded from the sandpaper 56. The paper pressing plate 44b has a U-shaped cutout 44d, and when the paper pressing plate 44b is located at the position at which the paper pressing plate 44b presses the upper side of the sandpaper 56 as shown in FIG. 2, part of the touch-and-close fastener of the sandpaper 56 is exposed upward. In this state, the cushion pad 55 is pressed against the upper surface of the sandpaper 56, and then the paper pressing plate 44b recedes from the sandpaper 56, so that the entire touch-and-close fastener of the sandpaper 56 is mounted to the cushion pad 55.

Paper Checking Unit

In a state where the sandpaper 56 has been mounted on the cushion pad 55 by the paper mounting unit 44, the paper checking unit 45 checks whether or not the mounting position of the sandpaper 56 is the correct position.

As shown in FIG. 10, the paper checking unit 45 includes a stand 45a and a camera 45b. The stand 45a includes a pair of plates 45c (see FIG. 2) disposed at an interval that is substantially equal to the outside diameter of the cushion pad 55, and a positioning plate 45d that couples the plates 45c together at ends on one side. The camera 45b is disposed under the stand 45a and takes an image of the cushion pad 55 (with the sandpaper 56 mounted thereon) placed on the stand 45a. The posture of the camera 45b is set such that the center line O2 of the cushion pad 55 in a state of being placed on the stand 45a and a center line of the camera 45b coincide with each other. Whether or not the mounting position of the sandpaper 56 is the correct position is checked by using data of the image of the cushion pad 55 and the sandpaper 56 taken by the camera 45b.

Control System

Next, a control system of the automatic wet sanding apparatuses 21 to 24 will be described. FIG. 11 is a block diagram illustrating the control system of the automatic wet sanding apparatuses 21 to 24.

As shown in FIG. 11, the control system of the automatic wet sanding apparatuses 21 to 24 has a configuration in which a starting switch 81, a conveyor controller 82, the robot controller 83, an automatic wet sanding unit controller 84, and a changer controller 85 are electrically connected to a central processing unit 8 that comprehensively controls the automatic wet sanding apparatuses 21 to 24, such that various signals including command signals can be sent and received between the central processing unit 8 and these components.

The starting switch 81 sends a command signal for starting the automatic wet sanding apparatuses 21 to 24 to the central processing unit 8 according to operation by a worker. When this start command signal is received, the automatic wet sanding apparatuses 21 to 24 are started (activated) to start an automatic wet sanding operation to be described later.

The conveyor controller 82 controls transfer of the vehicle body V by the conveyor 11. Specifically, the conveyor controller 82 operates the conveyor 11 until the vehicle body V that is an object of automatic wet sanding reaches a predetermined position (the position shown in FIG. 1) in the automatic wet sanding station 1, and temporarily stops the conveyor 11 at that point. When a predetermined time has elapsed after completion of automatic wet sanding by the automatic wet sanding apparatuses 21 to 24, the conveyor controller 82 operates the conveyor 11 again to transfer the vehicle body V having undergone automatic wet sanding to the next station, and operates the conveyor 11 until the vehicle body V that is the next object of automatic wet sanding reaches the predetermined position in the automatic wet sanding station 1.

The robot controller 83 controls the automatic wet sanding robots 3 of the respective automatic wet sanding apparatuses 21 to 24. The robot controller 83 sends command signals to various motors M that are provided in the rotating mechanisms of each automatic wet sanding robot 3 according to information on teaching that is performed on the automatic wet sanding robot 3 in advance. Thus, the robot controller 83 controls the position of the automatic wet sanding unit 5 based on the teaching information.

The automatic wet sanding unit controller 84 controls the automatic wet sanding unit 5. The water pump 52a, the air motor 50, and the air cylinders 60 are connected to the automatic wet sanding unit controller 84.

The water pump 52a is activated in accordance with a command signal from the automatic wet sanding unit controller 84 and supplies water for automatic wet sanding to the introduction space 51a of the skirt 51 through the water supply pipe 52. The air motor 50 is activated in accordance with a command signal from the automatic wet sanding unit controller 84 and rotates the driving shaft 50a. The air cylinders 60 are activated in accordance with a command signal from the automatic wet sanding unit controller 84 and move the piston rods 61A forward and backward. Thus, the automatic wet sanding unit 5 is moved forward and backward and the posture thereof is changed.

The changer controller 85 controls the units 41 to 45 of the changer 4. The clamping shaft motor 41d, the water supply pump 42j, the circulating pump 42g, the drain valve 42i, the air blow motor 43e, the air cylinder 44c, and the camera 45b are connected to the changer controller 85.

In the step of peeling the sandpaper 56 from the cushion pad 55 by the paper peeling unit 41, the clamping shaft motor 41d is activated by a command signal from the changer controller 85 and rotates the clamping shaft 41a. In the step of cleaning the cushion pad 55 by the pad cleaning unit 42, a water supplying action by the water supply pump 42j, a water circulating action by the circulating pump 42g, and a water discharging action by the drain valve 42i are performed in accordance with command signals from the changer controller 85. In the step of draining the cushion pad 55 by the pad draining unit 43, the air blow motor 43e is activated by a command signal from the changer controller 85 and blows air toward the cushion pad 55. In the step of mounting the sandpaper 56 onto the cushion pad 55 by the paper mounting unit 44, the air cylinder 44c is activated by a command signal from the changer controller 85 and the paper pressing plate 44b is moved between the position at which the paper pressing plate 44b presses the upper side of the sandpaper 56 and the position at which the paper pressing plate 44b has receded from the sandpaper 56.

The changer controller 85 receives imaging data (data of an image of the cushion pad 55 with the sandpaper 56 mounted thereon) from the camera 45b provided in the paper checking unit 45 and determines whether or not the sandpaper 56 is mounted at the correct position.

Automatic Wet Sanding Operation

Next, the automatic wet sanding operation of the vehicle body V in the automatic wet sanding station 1 configured as described above will be described.

FIG. 12 is a flowchart illustrating the automatic wet sanding operation by the first automatic wet sanding apparatus 21. The same automatic wet sanding operation is concurrently performed in the other automatic wet sanding apparatuses 22 to 24.

As shown in FIG. 12, in the automatic wet sanding operation by the first automatic wet sanding apparatus 21, the following steps are sequentially performed after “carrying in vehicle body”: a pad wetting step, front door automatic wet sanding step, front fender automatic wet sanding step, starting to carry out vehicle body, paper peeling step, pad cleaning step, pad draining step, paper mounting step, and paper checking step.

Carrying In Vehicle Body

In the step of carrying in the vehicle body, the conveyor 11 is activated by a command signal from the conveyor controller 82, and the vehicle body V that is an object of automatic wet sanding is transferred to the predetermined position (the position shown in FIG. 1) in the automatic wet sanding station 1. Then, the conveyor 11 stops. The conveyor 11 is kept in the stopped state until a predetermined time elapses that is when automatic wet sanding by each of the automatic wet sanding apparatuses 21 to 24 is completed.

Pad Wetting Step

In the pad wetting step, the automatic wet sanding robot 3 is operated by a command signal from the robot controller 83, and the automatic wet sanding unit 5 is immersed in water stored in the cleaning tank 42a of the pad cleaning unit 42. Specifically, the water supply pump 42j is activated by a command signal from the changer controller 85 and water is supplied to the cleaning tank 42a, and with the water thus stored in the cleaning tank 42a, the automatic wet sanding unit 5 is immersed in the water inside the cleaning tank 42a. In this way, the sandpaper 56 and the cushion pad 55 are wetted before the automatic wet sanding process is started.

Front Door Automatic Wet Sanding Step

In the front door automatic wet sanding step, the automatic wet sanding robot 3 is operated to move the automatic wet sanding unit 5 to a position at which it faces the front door (in the case of the first automatic wet sanding apparatus 21, the left front door LFD) (see FIG. 3). Then, the automatic wet sanding unit 5 is activated by a command signal from the automatic wet sanding unit controller 84.

Specifically, the water pump 52a is activated to supply water for automatic wet sanding to the introduction space 51a of the skirt 51 through the water supply pipe 52.

Further, the air motor 50 is activated to rotate the driving shaft 50a. As the driving shaft 50a rotates, the eccentric head 53 rotates eccentrically in the introduction space 51a of the skirt 51. The eccentric head 53 rotates eccentrically in the water present in the introduction space 51a. As the water in the introduction space 51a is thus stirred, the pressure of the water in the introduction space 51a becomes higher. As described above, the introduction space 51a communicates with the water channel 54i that continues through the openings 54h of the disc cover 54b and the disc holes 54e, the communication passages 54f, and the disc center hole 54d of the disc main body 54a. Therefore, the water stirred in the introduction space 51a is pushed out to the openings 54h of the disc cover 54b. FIG. 13 is a sectional view illustrating flows of water in the automatic wet sanding unit 5 in a state of performing automatic wet sanding. (FIG. 13 is a view of a section located at a position corresponding to line XIII-XIII in FIG. 4B.) As indicated by arrows W1 in FIG. 13, the water pushed out of the introduction space 51a to the openings 54h of the disc cover 54b flows from the openings 54h through the disc holes 54e, the communication passages 54f, and the disc center hole 54d. The water having passed through the disc center hole 54d passes through the pad center hole 55b of the cushion pad 55 and is pumped toward the painted surface of the vehicle body V through the paper center hole 56c of the sandpaper 56. Then, in the automatic wet sanding process, this water flows into the gap between the sanding surface 56a of the sandpaper 56 and the painted surface and is pushed out from the central portion toward the outer circumferential side of the sandpaper 56 between the sanding surface 56a and the painted surface.

With the water thus flowing, the sanding surface 56a of the sandpaper 56 is pressed against the painted surface with a predetermined pressure, and with the water flowing between the sanding surface 56a and the painted surface, the automatic wet sanding robot 3 is operated to move the sandpaper 56 along the painted surface of the left front door LFD to sand down the painted surface.

During automatic wet sanding, the air cylinder 60 is activated in accordance with a command signal from the automatic wet sanding unit controller 84 to control forward and backward motion of the piston rod 61A. Thus, the automatic wet sanding unit 5 is moved forward and backward and the posture thereof is changed such that the sandpaper adapts to the shape of the painted surface with high accuracy. Specifically, automatic wet sanding is performed while the posture of the sandpaper is changed according to changes in the curvature of the painted surface with high accuracy (e.g., the posture of the sanding sliding body is changed so as to be orthogonal to a line normal to the painted surface), as well as the pressing force exerted by the sanding sliding body on the painted surface is maintained at an appropriate level. While the piston rod 61A is thus moved forward and backward, the guide rods 61B are also moved forward and backward along with the piston rod 61A. As for forward and backward motion of the guide rods 61B, since each guide rod 61B is slidably supported by the bush 60a through the balls 61b as described above, the guide rods 61B are smoothly moved forward and backward as the balls 61b roll.

Since the disc 54 is rotatably supported by the eccentric head 53 as described above, the disc 54, the cushion pad 55, and the sandpaper 56 make eccentric motion (motion in which the center point of the disc 54 moves in circles) around the center of rotation O1 of the driving shaft 50a, without being forced to rotate when the eccentric head 53 rotates eccentrically.

FIG. 14 is a side view of a vehicle body illustrating moving paths of the automatic wet sanding unit 5 in the automatic wet sanding operation. Arrow D1 in FIG. 14 is one example of moving paths of the automatic wet sanding unit 5 of the first automatic wet sanding apparatus 21 when the automatic wet sanding unit 5 sands down the painted surface of the left front door LFD. Arrow D2 is one example of moving paths of the automatic wet sanding unit 5 of the first automatic wet sanding apparatus 21 when the automatic wet sanding unit 5 sands down the painted surface of the left front fender LFF (when the automatic wet sanding unit 5 performs the front fender automatic wet sanding step to be described later). Arrow D3 is one example of moving paths of the automatic wet sanding unit 5 of the third automatic wet sanding apparatus 23 when the automatic wet sanding unit 5 sands down the painted surface of the left rear fender LRF. Arrow D4 is one example of moving paths of the automatic wet sanding unit 5 of the third automatic wet sanding apparatus 23 when the automatic wet sanding unit 5 sands down the painted surface of the left rear door LRD.

While automatic wet sanding on the painted surface of the left front door LFD is performed by the automatic wet sanding unit 5 of the first automatic wet sanding apparatus 21, automatic wet sanding on the painted surface of the left rear fender LRF is performed by the automatic wet sanding unit 5 of the third automatic wet sanding apparatus 23. While automatic wet sanding on the painted surface of the left front fender LFF is performed by the automatic wet sanding unit 5 of the first automatic wet sanding apparatus 21, automatic wet sanding on the painted surface of the left rear door LRD is performed by the automatic wet sanding unit 5 of the third automatic wet sanding apparatus 23. This is to prevent the automatic wet sanding robot 3 of the first automatic wet sanding apparatus 21 and the automatic wet sanding robot 3 of the third automatic wet sanding apparatus 23 from coming too close to each other during automatic wet sanding.

Since water is pushed out toward the painted surface via the disc center hole 54d and the pad center hole 55b in automatic wet sanding as described above, automatic wet sanding is performed while water is pushed out from the central portion toward the outer circumferential side of the sandpaper 56 between the sandpaper 56 and the painted surface. Thus, sanding dust resulting from automatic wet sanding is washed away toward the outer circumferential side by water that is pushed out toward the outer circumferential side, so that sanding dust is less likely to remain around the sandpaper 56. As a result, automatic wet sanding can be performed with the likelihood of clogging due to sanding dust being reduced.

The following flow of water also occurs inside the automatic wet sanding unit 5. As water in the introduction space 51a is stirred by eccentric rotation of the eccentric head 53, the water pressure rises and this water pressure acts on the seal member 59. As shown in FIG. 4A, the upper end portion of the seal member 59 is inserted and supported in the engaging groove 51e of the skirt 51, while a lower end portion thereof is not supported and is in contact with the upper surface of the disc 54 along the entire circumference of the seal member 59. Therefore, when a water pressure acts on the seal member 59 and this water pressure exceeds a predetermined value, the lower end portion of the seal member 59 deforms elastically toward the outer circumferential side, leaving a small clearance between the lower end of the seal member 59 and the upper surface of the disc 54. Water flows through this clearance. Arrows W2 in FIG. 13 indicate this flow of water. The water thus flowing out toward the outer circumferential side through the clearance between the seal member 59 and the disc 54 collides with the water deflecting part 57c of the hood 57 and changes its flow direction to a direction toward the painted surface of the vehicle body V. Then, the water collides with the water deflecting member 58 and changes its flow direction so as to be directed toward the center side (the side toward the cushion pad 55) while flowing toward the painted surface of the vehicle body V. Inner surfaces of the hood 57 and the water deflecting member 58 are cleaned by this flow of water, and sanding dust adhering to these inner surfaces, if any, is removed. Then, the water collides with the painted surface of the vehicle body V and is sent (bounced) back by the painted surface, and changes its flow direction so as to be directed toward the center side (the side toward the disc 54) while flowing away from the painted surface of the vehicle body V (see arrows W3 in FIG. 13). As the water thus undergoes changes in the flow direction, the water having flowed out toward the outer circumferential side through the clearance between the seal member 59 and the disc 54 is unlikely to scatter widely in a peripheral part of the automatic wet sanding unit 5. It is therefore unlikely that paint separated from the vehicle body V by automatic wet sanding adheres to a wide area of the vehicle body V.

Front Fender Automatic Wet Sanding Step

When the front door automatic wet sanding step is completed, the operation of the automatic wet sanding unit 5 is temporarily stopped, and then the front fender automatic wet sanding step is started. In the front fender automatic wet sanding step, the automatic wet sanding robot 3 is operated to move the automatic wet sanding unit 5 to a position at which it faces the front fender (in the case of the first automatic wet sanding apparatus 21, the left front fender LFF). Then, the automatic wet sanding unit 5 is activated by a command signal from the automatic wet sanding unit controller 84. The operation of the automatic wet sanding unit 5 in this step is the same as in the front door automatic wet sanding step described above and therefore will not be described here.

Starting to Carry Out Vehicle Body

When the front door automatic wet sanding step is completed, the operation of the automatic wet sanding unit 5 is stopped and the vehicle body V starts to be carried out. Specifically, the conveyor 11 is activated to transfer the vehicle body V that has undergone automatic wet sanding toward the next station.

Paper Peeling Step

As the vehicle body V starts to be carried out, the paper peeling step by the paper peeling unit 41 provided in the changer 4 is performed. In the paper peeling step, the automatic wet sanding robot 3 is operated to move the automatic wet sanding unit 5 to a position at which the sandpaper 56 is caught between the clamping shaft 41a and the clamping hook 41b, and then the automatic wet sanding unit 5 is moved upward to thereby peel the sandpaper 56 from the cushion pad 55. Thereafter, the clamping shaft motor 41d is activated to rotate the clamping shaft 41a, so that the sandpaper 56 peeled from the cushion pad 55 drops into the sandpaper collection box 41e to be collected.

Pad Cleaning Step

In the pad cleaning step by the pad cleaning unit 42, cleaning water (pure water) is supplied to the cleaning tank 42a as the water supply pump 42j is activated, and the water is circulated through the circulating circuit 42c as the circulating pump 42g is activated. In this state, the automatic wet sanding robot 3 is operated to move the automatic wet sanding unit 5 into the cleaning tank 42a, and the cushion pad 55 is pressed against the metal mesh 42d to squeeze out water (water with paint mixed therein) contained in the cushion pad 55. Then, the automatic wet sanding unit 5 is slightly raised to separate the cushion pad 55 from the metal mesh 42d. In this state, the air motor 50 is activated and the cushion pad 55 is rotated (eccentrically rotated) in the water to clean the cushion pad 55. As the circulating pump 42g operates during these actions, water is circulated by being extracted from the bottom of the cleaning tank 42a and purified by the filter 42h and then returned to the cleaning tank 42a through the side surface of the cleaning tank 42a. Thereafter, the automatic wet sanding unit 5 is further slightly raised to move the cushion pad 55 to above the level of the water in the cleaning tank 42a, and the air motor 50 is activated again to drain the cushion pad 55 using a centrifugal force. Meanwhile, the drain valve 42i is opened to discharge the water from the cleaning tank 42a.

Pad Draining Step

In the pad draining step by the pad draining unit 43, the automatic wet sanding robot 3 is operated to press the cushion pad 55 against the inclined plate 43d of the draining table 43a, and water is thereby squeezed out of the cushion pad 55. In this process, the center line O2 of the disc 54 and the cushion pad 55 is moved as indicated by the arrows in FIG. 9 such that the position at which the cushion pad 55 is pressed against the inclined plate 43d is changed in the circumferential direction of the cushion pad 55. During draining, the air blow motor 43e is activated to blow air from the air blow nozzle 43b toward the cushion pad 55 and thereby increase the draining efficiency.

Paper Mounting Step

In the paper mounting step by the paper mounting unit 44, with the paper pressing plate 44b pressing the upper side of the sandpaper 56 as shown in FIG. 2, the automatic wet sanding robot 3 is operated to press the cushion pad 55 against the upper surface of the sandpaper 56. In this state, the air cylinder 44c is activated to move the paper pressing plate 44b away from the sandpaper 56, so that the entire touch-and-close fastener of the sandpaper 56 is mounted to the cushion pad 55. Since the cushion pad 55 is rotatably supported by the bearing 53a, it is preferable that at a stage preceding the paper mounting step, the cushion pad 55 be pressed against a positioning plate (not shown) to adjust the posture of the cushion pad 55 relative to the center of rotation O1 of the driving shaft 50a (the phase position of the cushion pad 55 in the offset direction) to a correct posture.

Paper Checking Step

In the paper checking step by the paper checking unit 45, the automatic wet sanding robot 3 is operated to place the cushion pad 55 (with the sandpaper 56 mounted thereon) on the stand 45a as shown in FIG. 10, and the outer circumferential surface of the cushion pad 55 is pressed against the plates 45c and the positioning plate 45d. In this state, an image of the cushion pad 55 and the sandpaper 56 is taken from below by the camera 45b. This imaging data is sent to the central processing unit 8 through the changer controller 85, and the central processing unit 8 checks whether or not the mounting position of the sandpaper 56 is the correct position. When it is determined that the mounting position of the sandpaper 56 is the correct position, the automatic wet sanding operation starting from the pad wetting step is performed on the next vehicle body V that has been transferred to the predetermined position in the automatic wet sanding station 1 by the step of carrying in the vehicle body. On the other hand, when it is determined that the mounting position of the sandpaper 56 is not the correct position, the action of mounting the sandpaper 56 is redone. To redo the mounting action, for example, the paper peeling step and the paper mounting step are sequentially performed.

The actions from “carrying in vehicle body” to the “paper checking step” are repeatedly performed to sequentially perform automatic wet sanding on each of vehicle bodies V transferred to the automatic wet sanding station 1.

Advantages of Embodiment

In the embodiment having been described above, the air cylinder 60 that changes the posture of the unit main body 5A of the automatic wet sanding unit 5 is provided with the guide rods 61B. The outer surface of each guide rod 61B has the grooves 61a that extend along the shaft centerline of the guide rod 61B and have an arc-shaped cross-section in a direction orthogonal to the shaft centerline, and the balls 61b are interposed between the bottom of each groove 61a and the inner surface (each groove 60b formed in the inner surface) of the bush 60a provided inside the air cylinder 60. Since providing the guide rods 61B can enhance the mechanical strength of the unit support mechanism 5B, the diameter of the piston rod 61A of the air cylinder 60 can be reduced. As described above, reducing the diameter of the piston rod 61A can increase the pressure of input air for control and enables high-accuracy pressure control. Further, as the area of contact between the piston rod and a part coming into sliding contact therewith (e.g., a seal packing) inside the air cylinder is reduced, the sliding resistance can be reduced. In addition, as the internal volume of the cylinder is reduced, the response speed in adaptation can be increased. Thus, higher adaptability of the sandpaper 56 can be achieved. Therefore, the configuration of this embodiment can make two objects compatible with each other: to achieve high-accuracy automatic wet sanding by enhancing the adaptability of the sandpaper 56 to the shape of a painted surface through a reduction of the diameter of the piston rod 61A; and to enhance the durability of the automatic wet sanding apparatuses 21 to 24.

In the embodiment, the guide rod 61B is provided on each side of the piston rod 61A of the air cylinder 60 in a direction orthogonal to the extension direction of the piston rod 61A. This configuration can give sufficient mechanical strength to the unit support mechanism SB that supports the unit main body 5A, making it easy to reduce the diameter of the piston rod 61A of the air cylinder 60.

In the embodiment, the outer circumferential surface of the threaded part 66a of the bearing bolt 66 provided in the rod end mechanism 5D has the recesses 66b that extend along the shaft centerline of the bearing bolt 66. Thus, the area of contact between the inner circumferential surface of the bearing member 67 disposed inside the rod end 64 and the outer circumferential surface of the threaded part 66a of the bearing bolt 66 can be reduced, and thereby the sliding resistance occurring between the bearing member 67 and the bearing bolt 66 when the unit main body 5A turns along with the bearing bolt 66 can be reduced. Therefore, during automatic wet sanding, the posture of the automatic wet sanding unit 5 can be quickly changed according to changes in the curvature of a painted surface so as to adapt the sandpaper 56 to the shape of the painted surface.

Other Embodiments

The present disclosure is not limited to the above embodiment and all modifications and applications encompassed by the scope of the claims and an equivalent scope are possible.

For example, in the above embodiment, the case has been described in which the present disclosure is applied to the automatic wet sanding apparatuses 21 to 24 for which the painted object is the vehicle body V and which perform automatic wet sanding on the painted surfaces of the vehicle body V. The painted object in the present disclosure is not limited to the vehicle body V, and the disclosure is applicable to automatic wet sanding apparatuses for various painted objects.

In the above embodiment, a total of two guide rods 61B are provided one on each side of one piston rod 61A. The present disclosure is not particularly limited in terms of the number of the guide rods 61B and the positions at which they are disposed. In the above embodiment, the grooves 61a are formed at four positions in the outer circumferential surface of each guide rod 61B. The present disclosure is not particularly limited in terms of the number of the grooves 61a either.

In the above embodiment, the recesses 66b formed in the outer circumferential surface of the threaded part 66a of the bearing bolt 66 have an arc-shaped cross-section. However, the cross-sectional shape is not limited to an arc shape and the recesses 66b may have an arbitrary shape. As to the range of formation of the recesses 66b in the outer circumferential surface of the threaded part 66a, the recesses 66b may be formed along the entire threaded part 66a in the extension direction thereof, or may be formed only at positions corresponding to the bolt insertion hole (center hole) 64a of the rod end 64 (positions corresponding to the bearing member 67).

The sandpaper 56 is used as a sanding sliding body in the above embodiment, but a sanding brush may instead be used.

The air motor 50 is used as a rotation power source in the above embodiment, but an electric motor or the like may instead be used.

The present disclosure is applicable to an automatic wet sanding apparatus that performs automatic wet sanding on a painted surface of a vehicle body.

AUTOMATIC WET SANDING APPARATUS

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

International Classifications

Abstract

Description

Claims

Priority Claims (1)