JP2005329782A - Method and device for conveying vehicular windshield - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and a device for conveying a vehicular windshield by which the windshield can be mounted on a vehicle with excellent accuracy in a simple configuration. <P>SOLUTION: A windshield W1 is moved to a predetermined position by a lifter 2, and an exterior side of the windshield W1 is opened. The windshield W1 is held by a glass holding machine 32 of a mounting robot 3, and conveyed to the mounting position of a car C. The position of the windshield W1 is finely adjusted by controlling the mounting robot 3 so that the position of the windshield W1 is matched with the mounting position of the car C while the position of the windshield W1 is compared with the mounting position of the car C. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a vehicle wind glass conveying method and apparatus for conveying window glass, which has been pre-processed, to a vehicle mounting position of a vehicle conveyed on an assembly line.

When attaching window glass to the front side and the rear side of a vehicle conveyed on the assembly line, for example, the following method is used. That is, the window glass that has been subjected to pretreatment such as degreasing and primer coating is transferred to a predetermined position, and the transferred window glass is gripped (received) by the mounting robot, and is transported to the mounting position of the vehicle and attached. (For example, refer to Patent Document 1).
Japanese Patent Laid-Open No. 10-29573

  By the way, in such a method, the pre-processed window glass and the mounting robot are in a predetermined positional relationship, and the window glass gripped by the mounting robot and the vehicle are in a predetermined positional relationship. Cost. That is, when the pre-processed window glass is received by the mounting robot, it is necessary to align the position of the mounting robot and the window glass, and when the mounting robot transports the window glass to the mounting position of the vehicle, And alignment with the mounting position is required. For this reason, a positioning device for accurately positioning the pre-processed window glass and the transported vehicle and a control means for aligning position data are required. As a result, the entire installation facility becomes complicated, and introduction costs and maintenance costs increase.

  Then, an object of this invention is to provide the conveyance method of the window glass for vehicles which can attach a window glass to a vehicle with a simple structure accurately, and its apparatus.

In order to achieve the above object, the invention according to claim 1 is a vehicle wind glass transporting device for transporting a wind glass that has been pretreated to a mounting position of the vehicle, wherein the wind glass has been pretreated. The window glass is transferred to a predetermined position where the exterior side of the window glass is open, and the window glass is held by the transfer means. Compared with the transport means that holds on the surface side and transports to the mounting position of the vehicle, and the position of the transported window glass and the mounting position of the vehicle, transport so that the position of the wind glass matches the mounting position of the vehicle And control means for controlling the movement of the means.
(Function)
Since the position of the conveyed wind glass is compared with the mounting position of the vehicle and the conveying means is controlled so that the position of the window glass matches the mounting position of the vehicle, the window glass is accurately mounted on the vehicle. Moreover, since the positioning of the window glass to the mounting position of the vehicle is finally performed by the control of the conveying means by the control means, when the conveying means holds the window glass, or when the conveying means holds the window glass in the vehicle. When transporting to the mounting position, it is not necessary to align the position.

According to the first aspect of the present invention, it is not necessary to align the position when the conveying means holds the window glass or when the conveying means conveys the window glass to the mounting position of the vehicle. This eliminates the need for a positioning device for accurately positioning the pre-processed window glass and the conveyed vehicle, and a control means for aligning position data, resulting in a simple configuration.

Hereinafter, the present invention will be described based on the illustrated embodiments.
FIG. 1 is a schematic configuration diagram showing a vehicle window glass conveyance device 1 and its peripheral devices according to the present embodiment.
The transfer device 1 holds the wind glasses W1 and W2 that have been pre-processed, and transfers the lift glass 2 (transfer means) that transfers the glass to a predetermined position, and the wind glass W1 and W2 transferred by the lifter 2 to the mounting position of the vehicle C. And a control means for controlling the movement of the mounting robot 3 so that the position of the window glass W1, W2 matches the mounting position of the vehicle C. The vehicle C is transported on the assembly line by the conveyor 7, temporarily stops at the process area (station) where the transport device 1 is disposed, and the window glasses W <b> 1 and W <b> 2 are attached.
In the figure, reference numeral 4 denotes a belt conveyor that conveys the window glass W1 and W2. The window glass W1 and W2 that have been subjected to degreasing and primer application are supplied to the conveyor 4 by the operator H. At this time, the window glass W1 on the front side and the window glass W2 on the rear side are alternately supplied, and the window glasses W1 and W2 are sequentially attached to one vehicle C on the front side and the rear side. It has become. Moreover, it supplies so that the exterior surface (surface which faces the outer side of the vehicle C when it attaches to the vehicle C) of the window glass W1 and W2 faces the conveyor 4 side.
In the middle of the conveyor 4, a sealing robot 5 for applying a sealer (adhesive) to the outer peripheral edges of the window glasses W1 and W2 is disposed. This sealing robot 5 is attached to a gate-shaped base frame 6 and applies a sealer to the entire outer periphery of the window glass W1, W2 by an application mechanism 5b attached to the tip of an arm 5a. That is, when the window glasses W1 and W2 conveyed on the conveyor 4 are stopped and positioned at predetermined positions, the sealing robot 5 moves the window glasses W1 and W2 in accordance with the movements that have been taught in advance. The sealer is applied to the entire outer periphery of the film. It should be noted that a certain period of time (dry time) for drying the primer is required after the degreasing and primer application is completed and before the sealer is applied. In this embodiment, the dry time is 60 seconds. The arrangement of the sealing robot 5 and the speed of the conveyor 4 are set so that
In this way, the wind glasses W1 and W2 that have undergone the pretreatment of degreasing, primer coating, and sealer coating are conveyed to the lifter 2 side and stopped at a predetermined position set in advance.
As shown in FIGS. 2 and 3, the lifter 2 is configured such that a fork 22 that holds window glasses W <b> 1 and W <b> 2 moves up and down on a gate-shaped base frame 21. That is, holders 23 a are attached to both ends of the two horizontal sliders 23 of the fork 22, and the holders 23 a are attached to the vertical guides 21 a of the base frame 21. The horizontal slider 23 supports two horizontally extending holding arms 24, and the holding arms 24 are each provided with three suction plates 25 for sucking and holding the wind glasses W 1 and W 2. . Further, two large sprockets 26 are rotatably attached to the center portion of the base frame beam 21 b of the base frame 21, and a chain 27 is engaged with the large sprockets 26. The fixed end 27 a of the chain 27 is fixed to the base frame beam 21 b of the base frame 21, and the movable end 27 b is attached to the upper horizontal slider 23. Further, a small sprocket 28 is engaged with an intermediate portion of the chain 27, and a lot tip of a lift cylinder 29 is connected to a rotation shaft of the small sprocket 28. The small sprocket 28 is moved up and down by the reciprocating movement of the rod of the lift cylinder 29, and the fork 22 is moved up and down by moving the movable end 27b of the chain 27 up and down along with the vertical movement. . The lifter 2 includes a glass sensor (not shown), and detects the window glass W1 and W2 when the window glass W1 and W2 are adsorbed and held by the adsorption plate 25.

  As shown in FIGS. 1 and 4, the mounting robot 3 reciprocates in the longitudinal direction of the base 8 and wind glasses W1 and W2 on the front side and the rear side with respect to the vehicle C once stopped. It can be attached.

  A glass gripping machine 32 (holding mechanism) that sucks and grips the wind glass W1 is attached to the tip of the robot arm 31 of the mounting robot 3. The glass gripping machine 32 can be adjusted in posture according to the driving of the robot arm 31. It has become.

  The glass gripping machine 32 is provided with a pair of CCD cameras 33a and 33b on the upper side, and a pair of CCD cameras 33c and 33d on the left and right side surfaces. The CCD cameras 33a and 33b move the window glass W1 sucked and gripped by the glass gripper 32 to a position just above the mounting surface around the window glass mounting opening C1 of the vehicle C based on a control signal from the robot control unit 41. When this is done, the vicinity of the upper part of the mounting opening C1 on the roof panel C2 side and the upper edge of the window glass W1 are photographed. On the other hand, in the CCD cameras 33c and 33d, when the window glass W1 is moved to just above the mounting surface around the mounting opening C1, the vicinity of the side of the mounting opening C1 on the side of the front pillar C3 and the window glass W1 are displayed. Take a picture of the left and right edges.

  The pair of CCD cameras 33a and 33b are provided at symmetrical positions with respect to a vertical axis (Y axis: see FIG. 5) passing through the center of the window glass W1. On the other hand, the pair of CCD cameras 33c and 33d are provided at the left and right ends of the window glass W1 on a line parallel to the horizontal axis (X axis: see FIG. 5) passing through the center of the window glass W1. Each of the CCD cameras 33a, 33b, 33c, and 33d is installed in a substantially vertical direction (Z-axis direction shown in FIG. 5) with respect to the surface of the window glass W1 sucked and held by the glass holding machine 32, and the surface of the window glass W1. In contrast, photographing is performed from above in a substantially vertical direction.

  Further, in the vicinity of each of the CCD cameras 33a, 33b, 33c, and 33d installed in the glass gripping machine 32, a slit-shaped laser beam from an oblique direction with respect to an area captured by each of the CCD cameras 33a, 33b, 33c, and 33d Slit laser irradiators 34a, 34b, 34c, and 34d for irradiating (slit laser light) are respectively installed.

  As shown in FIG. 6, the slit laser irradiators 34a and 34b installed in the vicinity of the CCD cameras 33a and 33b are pre-teached by the robot controller 41 with the window glass W1 with respect to the mounting opening C1 of the vehicle C. When moving to a position (directly above the mounting surface around the mounting opening C1), laser irradiation is performed so as to cross the vicinity of the upper portion of the mounting opening C1 on the roof panel C2 side and the upper edge of the window glass W1. . 6 shows the CCD camera 33a and the slit laser irradiator 34a side, the same applies to the CCD camera 33b and the slit laser irradiator 34b side.

  The slit laser irradiators 34a and 34b are inclined so as to be slightly inward from each other with respect to the left-right direction (X-axis direction shown in FIG. 5) of the window glass W1.

  On the other hand, as shown in FIG. 7, the slit laser irradiators 34c and 34d respectively installed in the vicinity of the CCD cameras 33c and 33d cross the vicinity of the side on the front pillar C3 side and the left and right edges of the wind glass W1. Laser irradiation is performed as follows. The slit laser irradiators 34c and 34d are inclined so as to face slightly downward with respect to the vertical direction of the surface of the window glass W1 in the vertical direction of the window glass W1 (Y-axis direction shown in FIG. 5). FIG. 7 shows the CCD camera 33c and the slit laser irradiator 34c side, but the same applies to the CCD camera 33d and the slit laser irradiator 34d side.

  Each of the CCD cameras 33a, 33b, 33c, and 33d captures a slit-shaped projected light image emitted from each of the slit laser irradiators 34a, 34b, 34c, and 34d, and the captured image information is stored in the image processing unit 42. Entered. Based on the image information input from the image processing unit 42, the calculation unit 43 calculates a correction amount of displacement with respect to the mounting surface around the mounting opening C1 of the window glass W1 (details will be described later). Based on the correction amount information input from the calculation unit 43, the robot control unit 41 sends a control signal to the robot arm 31 so that the window glass W1 is attached to the attachment surface of the attachment opening C1 at an appropriate position. The robot arm 31 is driven by outputting.

  Next, a specific control method (control means) for the robot arm 31 will be described.

  First, the robot arm 31 of the mounting robot 3 is driven by the control of the robot control unit 41 with respect to the vehicle C, and the window glass W1 sucked and gripped by the glass gripping machine 32 is mounted around the mounting opening C1 of the vehicle C. It is moved toward the mounting position taught in advance with respect to the surface. Then, the window glass W1 is temporarily stopped immediately above the mounting surface around the mounting opening C1 (several millimeters before). Here, as shown in FIGS. 6 and 7, the slit laser beams are irradiated from the slit laser irradiators 34a, 34b, 34c, and 34d obliquely from above in the vertical direction around the mounting opening C1.

  Since the slit laser irradiators 34a and 34b are tilted in the X-axis direction (left and right direction of the window glass W1), the emitted slit laser light is near the upper part of the roof panel C2 side around the mounting opening C1 and the window. Irradiation is performed so as to cross the edge on the upper surface side of the glass W1 in the vertical direction (Y-axis direction in FIG. 5). At this time, the mounting surface around the mounting opening C1 is positioned below the surface of the roof panel C2, and the window glass W1 is positioned above the mounting surface around the mounting opening C1, so that it is irradiated. The slit laser beam is not linear but is projected in the left-right direction (X-axis direction in FIG. 5). That is, as shown in FIG. 8A, the upper end (right side in the figure) of the window glass W1, the mounting surface C1a around the mounting opening C1, and the roof panel C2 are arranged in the vertical direction (Y axis in FIG. 5). The projection line L1 by the slit laser light irradiated so as to cross in the direction) is bent at the mounting surface C1a around the lowest mounting opening C1.

  On the other hand, since the slit laser irradiators 34c and 34d are tilted in the Y-axis direction (the vertical direction of the window glass W1), the emitted slit laser light is on the side of the front pillar C3 around the mounting opening C1. Irradiation is performed so as to cross the vicinity of the portion and the edge on the side surface side of the window glass W1 in the left-right direction (X-axis direction in FIG. 5). At this time, the mounting surface around the mounting opening C1 is positioned below the surface of the front pillar C3, and the window glass W1 is positioned above the mounting surface around the mounting opening C1. The slit laser beam thus formed is not linear but is projected in a vertical direction (Y-axis direction in FIG. 5). That is, as shown in FIG. 8B, irradiation was performed so as to cross the left and right end portions (left end portion in the figure) of the window glass W1, the mounting surface C1b around the mounting opening C1, and the front pillar portion C3. The projection line L2 by the slit laser beam is bent at the mounting surface C1b around the mounting opening C1.

  Then, the respective slit laser beams irradiated from the respective slit laser irradiators 34a, 34b, 34c, 34d are photographed by the respective CCD cameras 33a, 33b, 33c, 33d provided in the vicinity thereof. That is, as shown in FIG. 9, the CCD camera 33a has a region A1, the CCD camera 33b has a region A2, the CCD camera 33c has a region A3, and the CCD camera 33d has a window glass W1 and a mounting surface around the mounting opening C1. Each area A4 is photographed. These projection line images (images shown in FIGS. 8A and 8B) are input to the image processing unit 42.

  For example, the image processing unit 42 sets a distance M1 in the X-axis direction between the bent projection line L1 shown in FIG. 8A and the reference line N1 drawn parallel to the projection line L1. On the other hand, by multiplying the predetermined coefficient a, the position (Z = a × M1) in the Z-axis direction (the vertical direction of the window glass W1 surface) of the surface of the wind glass W1 and the surface of the roof panel C2 can be calculated. Further, the image processing unit 42, for example, the distance in the Y-axis direction between the reference line N2 drawn parallel to the projection line L2 with respect to the entire length of the bent projection line L2 shown in FIG. By multiplying M2 by a predetermined coefficient b, the position (Z = b × M2) in the Z-axis direction (the vertical direction of the window glass W1 surface) of the surface of the wind glass W1 and the surface of the front pillar portion C3 can be calculated. it can.

  Note that the above-described method for calculating the position of the window glass W1 surface and the roof panel C2 surface in the Z-axis direction and the method of calculating the position of the window glass W1 surface and the front pillar C3 surface in the Z-axis direction by the image processing unit 42 are examples. Yes, it can be calculated by other known calculation methods.

  The image processing unit 42 performs image processing on the bent projection lines L1 and L2 shown in FIGS. 8A and 8B based on the above calculation results, so that FIG. 10A and FIG. Processed images as shown in 11 (a) and 11 (b) are generated. FIGS. 10A and 10B are processed images obtained by processing images captured by the CCD cameras 33a and 33b (the processed image in FIG. 10B corresponds to the image in FIG. 8A). 11A and 11B are processes obtained by processing images taken by the CCD cameras 33c and 33d (the processed image in FIG. 11A corresponds to the image in FIG. 8B). It is an image.

  In the processed images shown in FIGS. 10A and 10B, 50 and 50 ′ are lines representing the height position in the pressing direction (Z-axis direction in FIG. 5) of the surface of the window glass W1, and 50a and 50a ′ are windows. Upper end portions 51, 51 'of the glass W1 are lines representing the position of the surface of the roof panel C2, 51a, 51a' are end portions of the roof panel 9, and 52, 52 'are mounting surfaces C1a around the mounting opening C1. It is a line showing.

ΔY ₁ and ΔY ₂ are respectively in the vertical direction (the Y-axis direction in FIG. 2) between the upper end portions 50a and 50a ′ of the window glass W1 and the end portions 51a and 51a ′ of the roof panel C2. It represents a gap.

  On the other hand, in the processed images shown in FIGS. 11A and 11B, reference numerals 53 and 53 ′ denote lines representing height positions in the pressing direction (Z-axis direction in FIG. 5) on the surface of the wind glass W1, 53a and 53a ′. Are the left and right ends of the windshield W1, 54 and 54 'are lines representing the position of the front pillar C3 surface, 54a and 54a' are the ends of the front pillar C3, and 55 and 55 'are the surroundings of the mounting opening C1. It is a line showing the attachment surface C1b.

ΔX ₁ and ΔX ₂ are respectively in the left-right direction (X-axis direction in FIG. 5) between the end portions 53a, 53a ′ on the left and right sides of the window glass W1 and the end portions 54a, 54a ′ of the front pillar portion C3. Gaps ΔZ ₁ and ΔZ ₂ in the pressing direction (Z-axis direction in FIG. 5) between the left and right end portions 53a and 53a ′ of the window glass W1 and the end portions 54a and 54a ′ of the front pillar portion C3. Each gap is represented.

The difference between the gaps ΔY ₁ and ΔY ₂ shown in FIGS. 10A and 10B from the processed image obtained by the image processing unit 42 (ΔY ₁ > in FIGS. 10A and 10B)> ΔY ₂ ) is calculated by the calculation unit 43. The robot control unit 41 sets the robot arm 31 of the mounting robot 3 so that the difference between the gaps ΔY ₁ and ΔY ₂ input from the calculation unit 43 becomes zero (ΔY ₁ −ΔY ₂ = 0). A control signal is output, and the wind glass W1 stopped just above the mounting surface (several millimeters before) around the mounting opening C1 is centered on the Z axis (vertical direction of the surface of the wind glass W1) as the center of rotation. It is rotated around the Z axis (in the θb direction) (rotated clockwise in this embodiment) to finely adjust the shift of the window glass W1 around the Z axis.

Then, a control signal is output from the calculation unit 43 to the robot arm 31 of the mounting robot 3 so that the values of the gaps ΔY ₁ and ΔY ₂ become preset numerical values, and the Y axis of the window glass W1 Finely adjust the direction (vertical direction) deviation.

Further, from the processed image obtained by the image processing unit 42, the difference between the gaps ΔX ₁ and ΔX ₂ shown in FIGS. 11A and 11B (in FIG. 11A and FIG. 11B, ΔX ₁ < ΔX ₂ ) is calculated by the calculation unit 43. The robot control unit 41 sets the robot arm 31 of the mounting robot 3 so that the difference between the gaps ΔX ₁ and ΔX ₂ input from the calculation unit 43 is zero (ΔX ₁ −ΔX ₂ = 0). A control signal is output, and the wind glass W1 stopped just above the mounting surface (several millimeters before) around the mounting opening C1 is centered on the Y axis (the vertical direction of the surface of the window glass W1) as the center of rotation. It is rotated around the Y axis (in the θa direction) (in the present embodiment, it is rotated counterclockwise) to finely adjust the deviation of the window glass W1 around the Y axis.

Then, 11 from the obtained processed image by the image processing section 42 (a), the difference between the clearance △ Z ₁ and △ Z ₂ shown in (b) (FIG. 11 (a), the in (b) △ Z _1> ΔZ ₂ ) is calculated by the calculation unit 43. The robot control unit 41 uses the movement amount such that the difference between the gaps ΔZ ₁ and ΔZ ₂ input from the calculation unit 43 becomes zero (ΔZ ₁ −ΔZ ₂ = 0) as a control signal. the output to the robot arm 31, the window glass W1 that is stopped directly above the mounting surface around the mounting opening C1 (a few millimeters in front), this case is moved by △ Z in _one direction the moving amount, the window glass Fine adjustment is made so that the gaps ΔZ ₁ and ΔZ ₂ in the Z-axis direction (the vertical direction of the surface of the window glass W1) at the left and right ends of W1 are the same.

  As described above, when the correction of the displacement with respect to the mounting surface around the mounting opening C1 of the window glass W1 including the displacement in the Z-axis direction at both the left and right end portions of the window glass W1 is completed, the robot arm 31 is maintained in this state. Is driven to move the window glass W1 by a predetermined amount in the Z-axis direction (the pressing direction of the window glass W1), and is pressed against the mounting surface around the mounting opening C1. Thus, the periphery of the window glass W1 can be attached and attached to the mounting surface with a uniform applied pressure.

  As described above, even when there is an error in the left and right curved surface shapes of the window glass W1, it is possible to detect and correct the displacement in the pressing direction (Z-axis direction) on the left and right ends of the window glass W1, so With respect to the vehicle C to which the window glass W1 is attached in line, the window glass W1 can be mounted on the mounting surface around the mounting opening C1 with good accuracy.

  In the present embodiment, the shift around the X axis with respect to the window glass is not more than a predetermined value, and the shift correction of the shift around the X axis is not performed. However, for example, by changing the shape of the window glass due to a model change, etc. When it is necessary to correct misalignment around the axis, by providing a CCD camera and a slit laser irradiator at a position where the lower end of the window glass can be photographed, the misalignment correction around the Y axis and Z axis described above can be achieved. Similarly, deviation correction around the X axis can be performed.

  Moreover, although the case where the window glass W1 of the front side was attached was demonstrated, when attaching the window glass W2 of the rear side, it can attach similarly.

Next, a procedure (flow) in which the window glasses W1 and W2 are attached to the vehicle C by the vehicle window glass conveyance device 1 having the above configuration will be described.
First, as shown in FIG. 1, the worker H supplies the window glasses W <b> 1 and W <b> 2 that have been degreased and primer-coated alternately to the conveyor 4. The window glass W1 and W2 on the conveyor 4 (firstly, W1 is an object to be attached), the primer dries before reaching the sealing robot 5, and the sealer 5 applies the sealer to the entire outer periphery. The When the application of the sealer is finished, the window glass W1 is conveyed to the lifter 2 side by the conveyor 4 and stopped at a predetermined position. At this time, the fork 22 of the lifter 2 is stopped at the top dead center.
Subsequently, when the lifter 2 detects the wind glass W1 conveyed to a predetermined position, the fork 22 is lowered, and the wind glass W1 is sucked and held by the suction disk 25 of the holding arm 24 (see FIGS. 2 and 3). Then, with the wind glass W1 held, the fork 22 rises to the top dead center and stops. As a result, the exterior surface of the window glass W1 (the surface facing the outside of the vehicle C when attached to the vehicle C) is in an open state (there is no obstacle around).
Next, the mounting robot 3 moves on the base 8 to the vicinity of the lifter 2, and the glass gripping machine 32 attached to the robot arm 31 sucks and grips the exterior surface of the window glass W <b> 1. The attachment robot 3 holding the window glass W1 moves on the base 8 to the front side of the vehicle C, and moves the window glass W1 to a predetermined position around the attachment opening C1 of the vehicle C as described above. The shift correction and fine adjustment are performed, and the window glass W1 is mounted on the mounting surface around the mounting opening C1 to complete the mounting of the window glass W1. Similarly, the window glass W2 is attached to the rear side of the vehicle C.

  As described above, the control of the robot arm 31 corrects the deviation between the window glass W1 and W2 and the mounting surface around the mounting opening C1, finely adjusts the position of the window glass W1 and W2, and accurately controls the window glass W1. , W2 is attached to the attachment surface of the vehicle C. Moreover, since the positioning of the window glasses W1 and W2 on the mounting surface around the mounting opening C1 is finally performed by the control of the robot arm 31, the mounting robot 3 sucks and holds the window glasses W1 and W2. In addition, when the mounting robot 3 conveys the window glass W1, W2 to the vehicle C, it is not necessary to align the positions.

  For this reason, it is not necessary to accurately position the transfer position (top dead center position) of the window glass W1, W2 by the lifter 2 and the stop position of the vehicle C, and the position of the window glass W1, W2 or the position of the vehicle C. Accordingly, it is not necessary to control the mounting robot 3 by matching the position data. As a result, the transfer position by the lifter 2 and the position of the vehicle C may be about the accuracy of normal teaching, the equipment configuration is simplified, and the conventional equipment can be applied as it is.

The schematic block diagram which shows the conveyance apparatus of the window glass for vehicles concerning embodiment of this invention, its peripheral device, etc. FIG. The front view of the lifter concerning embodiment of this invention. AA sectional drawing of FIG. The schematic block diagram which shows the attachment robot and control means concerning embodiment of this invention. The figure which shows the X-axis direction of the wind glass in a mounting attitude | position, a Y-axis direction, and a Z-axis direction. The figure which shows the slit camera irradiator which irradiates a slit laser beam across a wind glass upper end part and a roof panel end part, and the CCD camera which image | photographs this irradiated slit laser beam. The figure which shows the slit camera irradiator which irradiates a slit laser beam across the window glass left end part and a front pillar part, and the CCD camera which image | photographs this irradiated slit laser beam. (A) is a figure which shows the projection line by the slit laser beam irradiated so that the upper part edge part and roof panel edge part of a window glass may be crossed, (b) crosses a window glass left edge part and a front pillar part. The figure which shows the projection line by the slit laser beam irradiated like this. The figure which shows the imaging | photography area | region image | photographed with each CCD camera with respect to the window glass attached to the attachment surface around a window glass attachment opening part. (A), (b) is a figure which shows the processed image which image-processed the projection line by the slit laser beam irradiated so that a wind glass upper part edge part and a roof panel edge part may be crossed. (A), (b) is a figure which shows the process image which image-processed the projection line by the slit laser beam irradiated so that a window glass right-and-left end part and a front pillar part may be crossed.

Explanation of symbols

1 Vehicle Wind Glass Conveying Device 2 Lifter (Transfer means)
3 Mounting robot (conveying means)
32 Glass gripper (holding mechanism)
4 Conveyor 5 Sealing robot W1 Front window glass W2 Rear window glass C Vehicle

Claims (2)

A vehicle windshield conveying device that conveys the window glass that has been pretreated to a vehicle mounting position,
Transfer means for holding the window glass that has been pretreated and transferring the window glass to a predetermined position in which the exterior surface side of the window glass is opened;
A holding mechanism for holding the window glass, holding the window glass transferred by the transfer means on the exterior surface side, and transferring the vehicle to a mounting position of a vehicle;
Comparing the position of the transported window glass with the mounting position of the vehicle, and comprising control means for controlling the movement of the transport means so that the position of the window glass matches the mounting position of the vehicle,
A vehicle window glass conveying device. A vehicle wind glass transport method for transporting a wind glass that has been pretreated to a vehicle mounting position,
A transfer process for holding the window glass that has been pretreated and transferring it to a predetermined position;
Holding the transferred window glass, and transferring the window glass to a predetermined position close to the mounting position of the vehicle;
A positioning step of comparing the position of the window glass conveyed with the mounting position of the vehicle and correcting the position of the window glass so that the position of the window glass matches the mounting position of the vehicle;
A method for conveying a windshield for a vehicle.

Images